أوجوستان-جان فرينل

In a memoir drafted on 30 August 1816 and revised on 6 October, Fresnel reported an experiment in which he placed two matching thin laminae in a double-slit apparatus—one over each slit, with their optic axes perpendicular—and obtained two interference patterns offset in opposite directions, with perpendicular polarizations. This, in combination with the previous findings, meant that each lamina split the incident light into perpendicularly polarized components with different velocities—just like a normal (thick) birefringent crystal, and contrary to Biot's "mobile polarization" hypothesis.^[168]

Accordingly, in the same memoir, Fresnel offered his first attempt at a wave theory of chromatic polarization. When polarized light passed through a crystal lamina, it was split into ordinary and extraordinary waves (with intensities described by Malus's law), and these were perpendicularly polarized and therefore did not interfere, so that no colors were produced (yet). But if they then passed through an analyzer (second polarizer), their polarizations were brought into alignment (with intensities again modified according to Malus's law), and they would interfere.^[169] This explanation, by itself, predicts that if the analyzer is rotated 90°, the ordinary and extraordinary waves simply switch roles, so that if the analyzer takes the form of a calcite crystal, the two images of the lamina should be of the same hue (this issue is revisited below). But in fact, as Arago and Biot had found, they are of complementary colors. To correct the prediction, Fresnel proposed a phase-inversion rule whereby one of the constituent waves of one of the two images suffered an additional 180° phase shift on its way through the lamina. This inversion was a weakness in the theory relative to Biot's, as Fresnel acknowledged,^[170] although the rule specified which of the two images had the inverted wave.^[171] Moreover, Fresnel could deal only with special cases, because he had not yet solved the problem of superposing sinusoidal functions with arbitrary phase differences due to propagation at different velocities through the lamina.^[172]

He solved that problem in a "supplement" signed on 15 January 1818 ^[133] (mentioned above). In the same document, he accommodated Malus's law by proposing an underlying law: that if polarized light is incident on a birefringent crystal with its optic axis at an angle θ to the "plane of polarization", the ordinary and extraordinary vibrations (as functions of time) are scaled by the factors cos θ and sin θ, respectively. Although modern readers easily interpret these factors in terms of perpendicular components of a transverse oscillation, Fresnel did not (yet) explain them that way. Hence he still needed the phase-inversion rule. He applied all these principles to a case of chromatic polarization not covered by Biot's formulae, involving two successive laminae with axes separated by 45°, and obtained predictions that disagreed with Biot's experiments (except in special cases) but agreed with his own.^[173]

Fresnel applied the same principles to the standard case of chromatic polarization, in which one birefringent lamina was sliced parallel to its axis and placed between a polarizer and an analyzer. If the analyzer took the form of a thick calcite crystal with its axis in the plane of polarization, Fresnel predicted that the intensities of the ordinary and extraordinary images of the lamina were respectively proportional to

${\displaystyle{\displaystyle I_{o}=\cos^{2}i\,\cos^{2}(i{-}s)+\sin^{2}i\,\sin^{2}(i{-}s)+{\tfrac{1}{2}}\sin 2i\,\sin 2(i{-}s)\cos\phi\,,}}$

${\displaystyle{\displaystyle I_{e}=\cos^{2}i\,\sin^{2}(i{-}s)+\sin^{2}i\,\cos^{2}(i{-}s)-{\tfrac{1}{2}}\sin 2i\,\sin 2(i{-}s)\cos\phi\,,}}$

where ${\displaystyle{\displaystyle i}}$ is the angle from the initial plane of polarization to the optic axis of the lamina,  ${\displaystyle{\displaystyle s}}$ is the angle from the initial plane of polarization to the plane of polarization of the final ordinary image, and ${\displaystyle{\displaystyle\phi}}$ is the phase lag of the extraordinary wave relative to the ordinary wave due to the difference in propagation times through the lamina. The terms in ${\displaystyle{\displaystyle\phi}}$ are the frequency-dependent terms and explain why the lamina must be thin in order to produce discernible colors: if the lamina is too thick, ${\displaystyle{\displaystyle\cos\phi}}$ will pass through too many cycles as the frequency varies through the visible range, and the eye (which divides the visible spectrum into only three bands) will not be able to resolve the cycles.

From these equations it is easily verified that ${\displaystyle{\displaystyle\,I_{o}+I_{e}=1\,}}$ for all ${\displaystyle{\displaystyle\phi,}}$ so that the colors are complementary. Without the phase-inversion rule, there would be a plus sign in front of the last term in the second equation, so that the ${\displaystyle{\displaystyle\phi}}$-dependent term would be the same in both equations, implying (incorrectly) that the colors were of the same hue.

These equations were included in an undated note that Fresnel gave to Biot,^[174] to which Biot added a few lines of his own. If we substitute

${\displaystyle{\displaystyle U=\cos^{2}{\tfrac{\phi}{2}}}}$  and  ${\displaystyle{\displaystyle A=\sin^{2}{\tfrac{\phi}{2}}\,,}}$

then Fresnel's formulae can be rewritten as

${\displaystyle{\displaystyle\!I_{o}=U\cos^{2}s+A\cos^{2}(2i-s)\,,}}$

${\displaystyle{\displaystyle I_{e}=U\sin^{2}s+A\sin^{2}(2i-s)\,,}}$

which are none other than Biot's empirical formulae of 1812,^[175] except that Biot interpreted ${\displaystyle{\displaystyle U}}$ and ${\displaystyle{\displaystyle A}}$ as the "unaffected" and "affected" selections of the rays incident on the lamina. If Biot's substitutions were accurate, they would imply that his experimental results were more fully explained by Fresnel's theory than by his own.

Arago delayed reporting on Fresnel's works on chromatic polarization until June 1821, when he used them in a broad attack on Biot's theory. In his written response, Biot protested that Arago's attack went beyond the proper scope of a report on the nominated works of Fresnel. But Biot also claimed that the substitutions for ${\displaystyle{\displaystyle U}}$ and ${\displaystyle{\displaystyle A,}}$ and therefore Fresnel's expressions for ${\displaystyle{\displaystyle I_{o}}}$ and ${\displaystyle{\displaystyle I_{e},}}$ were empirically wrong because when Fresnel's intensities of spectral colors were mixed according to Newton's rules, the squared cosine and sine functions varied too smoothly to account for the observed sequence of colors. That claim drew a written reply from Fresnel,^[176] who disputed whether the colors changed as abruptly as Biot claimed,^[177] and whether the human eye could judge color with sufficient objectivity for the purpose. On the latter question, Fresnel pointed out that different observers may give different names to the same color. Furthermore, he said, a single observer can only compare colors side by side; and even if they are judged to be the same, the identity is of sensation, not necessarily of composition.^[178] Fresnel's oldest and strongest point—that thin crystals were subject to the same laws as thick ones and did not need or allow a separate theory—Biot left unanswered.  Arago and Fresnel were seen to have won the debate.^[179]

Moreover, by this time Fresnel had a new, simpler explanation of his equations on chromatic polarization.

 اختراق: الموجات العرضية النقية (1821)

أندريه-ماري أمپير (1775–1836)

In the draft memoir of 30 August 1816, Fresnel mentioned two hypotheses—one of which he attributed to Ampère—by which the non-interference of orthogonally-polarized beams could be explained if polarized light waves were partly transverse. But Fresnel could not develop either of these ideas into a comprehensive theory. As early as September 1816, according to his later account,^[180] he realized that the non-interference of orthogonally-polarized beams, together with the phase-inversion rule in chromatic polarization, would be most easily explained if the waves were purely transverse, and Ampère "had the same thought" on the phase-inversion rule. But that would raise a new difficulty: as natural light seemed to be unpolarized and its waves were therefore presumed to be longitudinal, one would need to explain how the longitudinal component of vibration disappeared on polarization, and why it did not reappear when polarized light was reflected or refracted obliquely by a glass plate.^[181]

Independently, on 12 January 1817, Young wrote to Arago (in English) noting that a transverse vibration would constitute a polarization, and that if two longitudinal waves crossed at a significant angle, they could not cancel without leaving a residual transverse vibration.^[182] Young repeated this idea in an article published in a supplement to the Encyclopædia Britannica in February 1818, in which he added that Malus's law would be explained if polarization consisted in a transverse motion.^[183]

Thus Fresnel, by his own testimony, may not have been the first person to suspect that light waves could have a transverse component, or that polarized waves were exclusively transverse. And it was Young, not Fresnel, who first published the idea that polarization depends on the orientation of a transverse vibration. But these incomplete theories had not reconciled the nature of polarization with the apparent existence of unpolarized light; that achievement was to be Fresnel's alone.

In a note that Buchwald dates in the summer of 1818, Fresnel entertained the idea that unpolarized waves could have vibrations of the same energy and obliquity, with their orientations distributed uniformly about the wave-normal, and that the degree of polarization was the degree of non-uniformity in the distribution. Two pages later he noted, apparently for the first time in writing, that his phase-inversion rule and the non-interference of orthogonally-polarized beams would be easily explained if the vibrations of fully polarized waves were "perpendicular to the normal to the wave"—that is, purely transverse.^[184]

But if he could account for lack of polarization by averaging out the transverse component, he did not also need to assume a longitudinal component. It was enough to suppose that light waves are purely transverse, hence always polarized in the sense of having a particular transverse orientation, and that the "unpolarized" state of natural or "direct" light is due to rapid and random variations in that orientation, in which case two coherent portions of "unpolarized" light will still interfere because their orientations will be synchronized.

It is not known exactly when Fresnel made this last step, because there is no relevant documentation from 1820 or early 1821 ^[185] (perhaps because he was too busy working on lighthouse-lens prototypes; see below). But he first published the idea in a paper on "Calcul des teintes…" ("calculation of the tints…"), serialized in Arago's Annales for May, June, and July 1821.^[186] In the first installment, Fresnel described "direct" (unpolarized) light as "the rapid succession of systems of waves polarized in all directions",^[187] and gave what is essentially the modern explanation of chromatic polarization, albeit in terms of the analogy between polarization and the resolution of forces in a plane, mentioning transverse waves only in a footnote. The introduction of transverse waves into the main argument was delayed to the second installment, in which he revealed the suspicion that he and Ampère had harbored since 1816, and the difficulty it raised.^[188] He continued:

It has only been for a few months that in meditating more attentively on this subject, I have realized that it was very probable that the oscillatory movements of light waves were executed solely along the plane of these waves, for direct light as well as for polarized light.^{[189][Note 6]}

According to this new view, he wrote, "the act of polarization consists not in creating these transverse movements, but in decomposing them into two fixed perpendicular directions and in separating the two components".^[190]

While selectionists could insist on interpreting Fresnel's diffraction integrals in terms of discrete, countable rays, they could not do the same with his theory of polarization. For a selectionist, the state of polarization of a beam concerned the distribution of orientations over the population of rays, and that distribution was presumed to be static. For Fresnel, the state of polarization of a beam concerned the variation of a displacement over time. That displacement might be constrained but was not static, and rays were geometric constructions, not countable objects. The conceptual gap between the wave theory and selectionism had become unbridgeable.^[191]

The other difficulty posed by pure transverse waves, of course, was the apparent implication that the aether was an elastic solid, except that, unlike other elastic solids, it was incapable of transmitting longitudinal waves.^{[Note 7]} The wave theory was cheap on assumptions, but its latest assumption was expensive on credulity.^[192] If that assumption was to be widely entertained, its explanatory power would need to be impressive.

 الانعكاس الجزئي (1821)

In the second installment of "Calcul des teintes" (June 1821), Fresnel supposed, by analogy with sound waves, that the density of the aether in a refractive medium was inversely proportional to the square of the wave velocity, and therefore directly proportional to the square of the refractive index. For reflection and refraction at the surface between two isotropic media of different indices, Fresnel decomposed the transverse vibrations into two perpendicular components, now known as the s and p components, which are parallel to the surface and the plane of incidence, respectively; in other words, the s and p components are respectively square and parallel to the plane of incidence.^{[Note 8]} For the s component, Fresnel supposed that the interaction between the two media was analogous to an elastic collision, and obtained a formula for what we now call the reflectivity: the ratio of the reflected intensity to the incident intensity. The predicted reflectivity was non-zero at all angles.^[193]

The third installment (July 1821) was a short "postscript" in which Fresnel announced that he had found, by a "mechanical solution", a formula for the reflectivity of the p component, which predicted that the reflectivity was zero at the Brewster angle. So polarization by reflection had been accounted for—but with the proviso that the direction of vibration in Fresnel's model was perpendicular to the plane of polarization as defined by Malus. (On the ensuing controversy, see Plane of polarization.) The technology of the time did not allow the s and p reflectivities to be measured accurately enough to test Fresnel's formulae at arbitrary angles of incidence. But the formulae could be rewritten in terms of what we now call the reflection coefficient: the signed ratio of the reflected amplitude to the incident amplitude. Then, if the plane of polarization of the incident ray was at 45° to the plane of incidence, the tangent of the corresponding angle for the reflected ray was obtainable from the ratio of the two reflection coefficients, and this angle could be measured. Fresnel had measured it for a range of angles of incidence, for glass and water, and the agreement between the calculated and measured angles was better than 1.5° in all cases.^[194]

Fresnel gave details of the "mechanical solution" in a memoir read to the Académie des Sciences on 7 January 1823.^[195] Conservation of energy was combined with continuity of the tangential vibration at the interface.^[196] The resulting formulae for the reflection coefficients and reflectivities became known as the Fresnel equations. The reflection coefficients for the s and p polarizations are most succinctly expressed as

${\displaystyle{\displaystyle r_{s}=-{\frac{\sin(i-r)}{\sin(i+r)}}}}$قالب:Quadandقالب:Quad${\displaystyle{\displaystyle r_{p}={\frac{\tan(i-r)}{\tan(i+r)}}\,,}}$

where ${\displaystyle{\displaystyle i}}$ and ${\displaystyle{\displaystyle r}}$ are the angles of incidence and refraction; these equations are known respectively as Fresnel's sine law and Fresnel's tangent law.^[197] By allowing the coefficients to be complex, Fresnel even accounted for the different phase shifts of the s and p components due to total internal reflection.^[198]

(see Physically based rendering).

 الاستقطاب الدائري والبيضاوي، والدوران البصري (1822)

A right-handed/clockwise circularly polarized wave as defined from the point of view of the source. It would be considered left-handed/anti-clockwise circularly polarized if defined from the point of view of the receiver. If the rotating vector is resolved into horizontal and vertical components (not shown), these are a quarter-cycle out of phase with each other.

In a memoir dated 9 December 1822,^[200] Fresnel coined the terms linear polarization (French: polarisation rectiligne) for the simple case in which the perpendicular components of vibration are in phase or 180° out of phase, circular polarization for the case in which they are of equal magnitude and a quarter-cycle (±90°) out of phase, and elliptical polarization for other cases in which the two components have a fixed amplitude ratio and a fixed phase difference. He then explained how optical rotation could be understood as a species of birefringence. Linearly-polarized light could be resolved into two circularly-polarized components rotating in opposite directions. If these components propagated at slightly different speeds, the phase difference between them—and therefore the direction of their linearly-polarized resultant—would vary continuously with distance.^[201]

These concepts called for a redefinition of the distinction between polarized and unpolarized light. Before Fresnel, it was thought that polarization could vary in direction, and in degree (e.g., due to variation in the angle of reflection off a transparent body), and that it could be a function of color (chromatic polarization), but not that it could vary in kind. Hence it was thought that the degree of polarization was the degree to which the light could be suppressed by an analyzer with the appropriate orientation. Light that had been converted from linear to elliptical or circular polarization (e.g., by passage through a crystal lamina, or by total internal reflection) was described as partly or fully "depolarized" because of its behavior in an analyzer. After Fresnel, the defining feature of polarized light was that the perpendicular components of vibration had a fixed ratio of amplitudes and a fixed difference in phase. By that definition, elliptically or circularly polarized light is fully polarized although it cannot be fully suppressed by an analyzer alone.^[202] The conceptual gap between the wave theory and selectionism had widened again.

 الانعكاس الداخلي التام (1817–23)

Cross-section of a Fresnel rhomb (blue) with graphs showing the p component of vibration (parallel to the plane of incidence) on the vertical axis, vs. the s component (square to the plane of incidence and parallel to the surface) on the horizontal axis. If the incoming light is linearly polarized, the two components are in phase (top graph). After one reflection at the appropriate angle, the p component is advanced by 1/8 of a cycle relative to the s component (middle graph). After two such reflections, the phase difference is 1/4 of a cycle (bottom graph), so that the polarization is elliptical with axes in the s and p directions. If the s and p components were initially of equal magnitude, the initial polarization (top graph) would be at 45° to the plane of incidence, and the final polarization (bottom graph) would be circular.

By 1817 it had been discovered by Brewster,^[203] but not adequately reported,^[204][183] that plane-polarized light was partly depolarized by total internal reflection if initially polarized at an acute angle to the plane of incidence. Fresnel rediscovered this effect and investigated it by including total internal reflection in a chromatic-polarization experiment. With the aid of his first theory of chromatic polarization, he found that the apparently depolarized light was a mixture of components polarized parallel and perpendicular to the plane of incidence, and that the total reflection introduced a phase difference between them.^[205] Choosing an appropriate angle of incidence (not yet exactly specified) gave a phase difference of 1/8 of a cycle (45°). Two such reflections from the "parallel faces" of "two coupled prisms" gave a phase difference of 1/4 of a cycle (90°). These findings were contained in a memoir submitted to the Académie on 10 November 1817 and read a fortnight later. An undated marginal note indicates that the two coupled prisms were later replaced by a single "parallelepiped in glass"—now known as a Fresnel rhomb.^[206]

This was the memoir whose "supplement",^[133] dated January 1818, contained the method of superposing sinusoidal functions and the restatement of Malus's law in terms of amplitudes. In the same supplement, Fresnel reported his discovery that optical rotation could be emulated by passing the polarized light through a Fresnel rhomb (still in the form of "coupled prisms"), followed by an ordinary birefringent lamina sliced parallel to its axis, with the axis at 45° to the plane of reflection of the Fresnel rhomb, followed by a second Fresnel rhomb at 90° to the first.^[207] In a further memoir read on 30 March,^[208] Fresnel reported that if polarized light was fully "depolarized" by a Fresnel rhomb—now described as a parallelepiped—its properties were not further modified by a subsequent passage through an optically rotating medium or device.

The connection between optical rotation and birefringence was further explained in 1822, in the memoir on elliptical and circular polarization.^[200] This was followed by the memoir on reflection, read in January 1823, in which Fresnel quantified the phase shifts in total internal reflection, and thence calculated the precise angle at which a Fresnel rhomb should be cut in order to convert linear polarization to circular polarization. For a refractive index of 1.51, there were two solutions: about 48.6° and 54.6°.^[195]

 الانكسار المزدوج

 خلفية: البلورات أحادية وثنائية المحور؛ قوانين بيوت

When light passes through a slice of calcite cut perpendicular to its optic axis, the difference between the propagation times of the ordinary and extraordinary waves has a second-order dependence on the angle of incidence. If the slice is observed in a highly convergent cone of light, that dependence becomes significant, so that a chromatic-polarization experiment will show a pattern of concentric rings. But most minerals, when observed in this manner, show a more complicated pattern of rings involving two foci and a lemniscate curve, as if they had two optic axes.^[209][210] The two classes of minerals naturally become known as uniaxal and biaxal—or, in later literature, uniaxial and biaxial.

In 1813, Brewster observed the simple concentric pattern in "beryl, emerald, ruby &c." The same pattern was later observed in calcite by Wollaston, Biot, and Seebeck.  Biot, assuming that the concentric pattern was the general case, tried to calculate the colors with his theory of chromatic polarization, and succeeded better for some minerals than for others. In 1818, Brewster belatedly explained why: seven of the twelve minerals employed by Biot had the lemniscate pattern, which Brewster had observed as early as 1812; and the minerals with the more complicated rings also had a more complicated law of refraction.^[211]

In a uniform crystal, according to Huygens's theory, the secondary wavefront that expands from the origin in unit time is the ray-velocity surface—that is, the surface whose "distance" from the origin in any direction is the ray velocity in that direction. In calcite, this surface is two-sheeted, consisting of a sphere (for the ordinary wave) and an oblate spheroid (for the extraordinary wave) touching each other at opposite points of a common axis—touching at the north and south poles, if we may use a geographic analogy. But according to Malus's corpuscular theory of double refraction, the ray velocity was proportional to the reciprocal of that given by Huygens's theory, in which case the velocity law was of the form

${\displaystyle{\displaystyle v_{o}^{2\!}-v_{e}^{2}=k\sin^{2}\theta\,,}}$

where ${\displaystyle{\displaystyle v_{o}}}$ and ${\displaystyle{\displaystyle v_{e}}}$ were the ordinary and extraordinary ray velocities according to the corpuscular theory, and ${\displaystyle{\displaystyle\theta}}$ was the angle between the ray and the optic axis.^[212] By Malus's definition, the plane of polarization of a ray was the plane of the ray and the optic axis if the ray was ordinary, or the perpendicular plane (containing the ray) if the ray was extraordinary. In Fresnel's model, the direction of vibration was normal to the plane of polarization. Hence, for the sphere (the ordinary wave), the vibration was along the lines of latitude (continuing the geographic analogy); and for the spheroid (the extraordinary wave), the vibration was along the lines of longitude.

On 29 March 1819,^[213] Biot presented a memoir in which he proposed simple generalizations of Malus's rules for a crystal with two axes, and reported that both generalizations seemed to be confirmed by experiment. For the velocity law, the squared sine was replaced by the product of the sines of the angles from the ray to the two axes (Biot's sine law). And for the polarization of the ordinary ray, the plane of the ray and the axis was replaced by the plane bisecting the dihedral angle between the two planes each of which contained the ray and one axis (Biot's dihedral law).^[214][215] Biot's laws meant that a biaxial crystal with axes at a small angle, cleaved in the plane of those axes, behaved nearly like a uniaxial crystal at near-normal incidence; this was fortunate because gypsum, which had been used in chromatic-polarization experiments, is biaxial.^[216]

 المذكرات الأولى وملاحقها (1821–22)

Until Fresnel turned his attention to biaxial birefringence, it was assumed that one of the two refractions was ordinary, even in biaxial crystals.^[217] But, in a memoir submitted ^{[Note 9]} on 19 November 1821,^[218] Fresnel reported two experiments on topaz showing that neither refraction was ordinary in the sense of satisfying Snell's law; that is, neither ray was the product of spherical secondary waves.^[219]

The same memoir contained Fresnel's first attempt at the biaxial velocity law. For calcite, if we interchange the equatorial and polar radii of Huygens's oblate spheroid while preserving the polar direction, we obtain a prolate spheroid touching the sphere at the equator. A plane through the center/origin cuts this prolate spheroid in an ellipse whose major and minor semi-axes give the magnitudes of the extraordinary and ordinary ray velocities in the direction normal to the plane, and (said Fresnel) the directions of their respective vibrations. The direction of the optic axis is the normal to the plane for which the ellipse of intersection reduces to a circle. So, for the biaxial case, Fresnel simply replaced the prolate spheroid with a triaxial ellipsoid,^[220] which was to be sectioned by a plane in the same way. In general there would be two planes passing through the center of the ellipsoid and cutting it in a circle, and the normals to these planes would give two optic axes. From the geometry, Fresnel deduced Biot's sine law (with the ray velocities replaced by their reciprocals).^[221]

The ellipsoid indeed gave the correct ray velocities (although the initial experimental verification was only approximate). But it did not give the correct directions of vibration, for the biaxial case or even for the uniaxial case, because the vibrations in Fresnel's model were tangential to the wavefront—which, for an extraordinary ray, is not generally normal to the ray. This error (which is small if, as in most cases, the birefringence is weak) was corrected in an "extract" that Fresnel read to the Académie a week later, on 26 November. Starting with Huygens's spheroid, Fresnel obtained a 4th-degree surface which, when sectioned by a plane as above, would yield the wave-normal velocities for a wavefront in that plane, together with their vibration directions. For the biaxial case, he generalized the equation to obtain a surface with three unequal principal dimensions; this he subsequently called the "surface of elasticity". But he retained the earlier ellipsoid as an approximation, from which he deduced Biot's dihedral law.^[222]

Fresnel's initial derivation of the surface of elasticity had been purely geometric, and not deductively rigorous. His first attempt at a mechanical derivation, contained in a "supplement" dated 13 January 1822, assumed that (i) there were three mutually perpendicular directions in which a displacement produced a reaction in the same direction, (ii) the reaction was otherwise a linear function of the displacement, and (iii) the radius of the surface in any direction was the square root of the component, in that direction, of the reaction to a unit displacement in that direction. The last assumption recognized the requirement that if a wave was to maintain a fixed direction of propagation and a fixed direction of vibration, the reaction must not be outside the plane of those two directions.^[223]

In the same supplement, Fresnel considered how he might find, for the biaxial case, the secondary wavefront that expands from the origin in unit time—that is, the surface that reduces to Huygens's sphere and spheroid in the uniaxial case. He noted that this "wave surface" (surface de l'onde)^[224] is tangential to all possible plane wavefronts that could have crossed the origin one unit of time ago, and he listed the mathematical conditions that it must satisfy. But he doubted the feasibility of deriving the surface from those conditions.^[225]

In a "second supplement",^[226] Fresnel eventually exploited two related facts: (i) the "wave surface" was also the ray-velocity surface, which could be obtained by sectioning the ellipsoid that he had initially mistaken for the surface of elasticity, and (ii) the "wave surface" intersected each plane of symmetry of the ellipsoid in two curves: a circle and an ellipse. Thus he found that the "wave surface" is described by the 4th-degree equation

${\displaystyle{\displaystyle r^{2}{\big{(}}a^{2}x^{2\!}+b^{2}y^{2\!}+c^{2}z^{2}{\big{)}}-a^{2}{\big{(}}b^{2\!}+c^{2}{\big{)}}x^{2}-b^{2}{\big{(}}c^{2\!}+a^{2}{\big{)}}y^{2}-c^{2}{\big{(}}a^{2\!}+b^{2}{\big{)}}z^{2}+a^{2}b^{2}c^{2}=\,0\,,}}$

where ${\displaystyle{\displaystyle\,r^{2}=x^{2\!}+y^{2\!}+z^{2},\,}}$ and ${\displaystyle{\displaystyle\,a,b,c\,}}$ are the propagation speeds in directions normal to the coordinate axes for vibrations along the axes (the ray and wave-normal speeds being the same in those special cases).^[227] Later commentators^[228] put the equation in the more compact and memorable form

${\displaystyle{\displaystyle{\frac{x^{2}}{r^{2}-a^{2}}}+{\frac{y^{2}}{r^{2}-b^{2}}}+{\frac{z^{2}}{r^{2}-c^{2}}}\,=\,1\,.}}$

Earlier in the "second supplement", Fresnel modeled the medium as an array of point-masses and found that the force-displacement relation was described by a symmetric matrix, confirming the existence of three mutually perpendicular axes on which the displacement produced a parallel force.^[229] Later in the document, he noted that in a biaxial crystal, unlike a uniaxial crystal, the directions in which there is only one wave-normal velocity are not the same as those in which there is only one ray velocity.^[230] Nowadays we refer to the former directions as the optic axes or binormal axes, and the latter as the ray axes or biradial axes

(see Birefringence).^[231] Fresnel's "second supplement" was signed on 31 March 1822 and submitted the next day—less than a year after the publication of his pure-transverse-wave hypothesis, and just less than a year after the demonstration of his prototype eight-panel lighthouse lens

(see below).

 المذكرات الثانية (1822–26)

Having presented the pieces of his theory in roughly the order of discovery, Fresnel needed to rearrange the material so as to emphasize the mechanical foundations;^[232] and he still needed a rigorous treatment of Biot's dihedral law.^[233] He attended to these matters in his "second memoir" on double refraction,^[234] published in the Recueils of the Académie des Sciences for 1824; this was not actually printed until late 1827, a few months after his death.^[235] In this work, having established the three perpendicular axes on which a displacement produces a parallel reaction,^[236] and thence constructed the surface of elasticity,^[237] he showed that Biot's dihedral law is exact provided that the binormals are taken as the optic axes, and the wave-normal direction as the direction of propagation.^[238]

As early as 1822, Fresnel discussed his perpendicular axes with Cauchy. Acknowledging Fresnel's influence, Cauchy went on to develop the first rigorous theory of elasticity of non-isotropic solids (1827), hence the first rigorous theory of transverse waves therein (1830)—which he promptly tried to apply to optics.^[239] The ensuing difficulties drove a long competitive effort to find an accurate mechanical model of the aether.^[240] Fresnel's own model was not dynamically rigorous; for example, it deduced the reaction to a shear strain by considering the displacement of one particle while all others were fixed, and it assumed that the stiffness determined the wave velocity as in a stretched string, whatever the direction of the wave-normal. But it was enough to enable the wave theory to do what selectionist theory could not: generate testable formulae covering a comprehensive range of optical phenomena, from mechanical assumptions.^[241]

 المرونة الضوئية، وتجارب المناشير المتعددة (1822)

Chromatic polarization in a plastic protractor, caused by stress-induced birefringence.

In 1815, Brewster reported that colors appear when a slice of isotropic material, placed between crossed polarizers, is mechanically stressed. Brewster himself immediately and correctly attributed this phenomenon to stress-induced birefringence ^[242][243]—now known as photoelasticity.

In a memoir read in September 1822, Fresnel announced that he had verified Brewster's diagnosis more directly, by compressing a combination of glass prisms so severely that one could actually see a double image through it. In his experiment, Fresnel lined up seven 45°–90°–45° prisms, short side to short side, with their 90° angles pointing in alternating directions. Two half-prisms were added at the ends to make the whole assembly rectangular. The prisms were separated by thin films of turpentine (térébenthine) to suppress internal reflections, allowing a clear line of sight along the row. When the four prisms with similar orientations were compressed in a vise across the line of sight, an object viewed through the assembly produced two images with perpendicular polarizations, with an apparent spacing of 1.5 mm at one metre.^[244][245]

At the end of that memoir, Fresnel predicted that if the compressed prisms were replaced by (unstressed) monocrystalline quartz prisms with matching directions of optical rotation, and with their optic axes aligned along the row, an object seen by looking along the common optic axis would give two images, which would seem unpolarized when viewed through an analyzer but, when viewed through a Fresnel rhomb, would be polarized at ±45° to the plane of reflection of the rhomb (indicating that they were initially circularly polarized in opposite directions). This would show directly that optical rotation is a form of birefringence. In the memoir of December 1822, in which he introduced the term circular polarization, he reported that he had confirmed this prediction using only one 14°–152°–14° prism and two glass half-prisms. But he obtained a wider separation of the images by replacing the glass half-prism with quartz half-prisms whose rotation was opposite to that of the 14°–152°–14° prism. He added in passing that one could further increase the separation by increasing the number of prisms.^[246]

 الاستقبال

For the supplement to Riffault's translation of Thomson's System of Chemistry, Fresnel was chosen to contribute the article on light. The resulting 137-page essay, titled De la Lumière (On Light),^[247] was apparently finished in June 1821 and published by February 1822.^[248] With sections covering the nature of light, diffraction, thin-film interference, reflection and refraction, double refraction and polarization, chromatic polarization, and modification of polarization by reflection, it made a comprehensive case for the wave theory to a readership that was not restricted to physicists.^[249]

To examine Fresnel's first memoir and supplements on double refraction, the Académie des Sciences appointed Ampère, Arago, Fourier, and Poisson.^[250] Their report,^[251] of which Arago was clearly the main author,^[252] was delivered at the meeting of 19 August 1822. Then, in the words of Émile Verdet, as translated by Ivor Grattan-Guinness:

Immediately after the reading of the report, Laplace took the floor, and… proclaimed the exceptional importance of the work which had just been reported: he congratulated the author on his steadfastness and his sagacity which had led him to discover a law which had escaped the cleverest, and, anticipating somewhat the judgement of posterity, declared that he placed these researches above everything that had been communicated to the Académie for a long time.^[253]

Whether Laplace was announcing his conversion to the wave theory—at the age of 73—is uncertain. Grattan-Guinness entertained the idea.^[254] Buchwald, noting that Arago failed to explain that the "ellipsoid of elasticity" did not give the correct planes of polarization, suggests that Laplace may have merely regarded Fresnel's theory as a successful generalization of Malus's ray-velocity law, embracing Biot's laws.^[255]

Airy diffraction pattern 65 mm from a 0.09 mm circular aperture illuminated by red laser light. Image size: 17.3 mm × 13 mm

In the following year, Poisson, who did not sign Arago's report, disputed the possibility of transverse waves in the aether. Starting from assumed equations of motion of a fluid medium, he noted that they did not give the correct results for partial reflection and double refraction—as if that were Fresnel's problem rather than his own—and that the predicted waves, even if they were initially transverse, became more longitudinal as they propagated. In reply Fresnel noted, inter alia, that the equations in which Poisson put so much faith did not even predict viscosity. The implication was clear: given that the behavior of light had not been satisfactorily explained except by transverse waves, it was not the responsibility of the wave-theorists to abandon transverse waves in deference to pre-conceived notions about the aether; rather, it was the responsibility of the aether modelers to produce a model that accommodated transverse waves.^[256] According to Robert H. Silliman, Poisson eventually accepted the wave theory shortly before his death in 1840.^[257]

Among the French, Poisson's reluctance was an exception. According to Eugene Frankel, "in Paris no debate on the issue seems to have taken place after 1825. Indeed, almost the entire generation of physicists and mathematicians who came to maturity in the 1820s—Pouillet, Savart, Lamé, Navier, Liouville, Cauchy—seem to have adopted the theory immediately." Fresnel's other prominent French opponent, Biot, appeared to take a neutral position in 1830, and eventually accepted the wave theory—possibly by 1846 and certainly by 1858.^[258]

In 1826, the British astronomer John Herschel, who was working on a book-length article on light for the Encyclopædia Metropolitana, addressed three questions to Fresnel concerning double refraction, partial reflection, and their relation to polarization. The resulting article,^[259] titled simply "Light", was highly sympathetic to the wave theory, although not entirely free of selectionist language. It was circulating privately by 1828 and was published in 1830.^[260] Meanwhile, Young's translation of Fresnel's De la Lumière was published in installments from 1827 to 1829.^[261] George Biddell Airy, the former Lucasian Professor at Cambridge and future Astronomer Royal, unreservedly accepted the wave theory by 1831.^[262] In 1834, he famously calculated the diffraction pattern of a circular aperture from the wave theory,^[263] thereby explaining the limited angular resolution of a perfect telescope

(see Airy disk). By the end of the 1830s, the only prominent British physicist who held out against the wave theory was Brewster, whose objections included the difficulty of explaining photochemical effects and (in his opinion) dispersion.^[264]

A German translation of De la Lumière was published in installments in 1825 and 1828. The wave theory was adopted by Fraunhofer in the early 1820s and by Franz Ernst Neumann in the 1830s, and then began to find favor in German textbooks.^[265]

The economy of assumptions under the wave theory was emphasized by William Whewell in his History of the Inductive Sciences, first published in 1837. In the corpuscular system, "every new class of facts requires a new supposition," whereas in the wave system, a hypothesis devised in order to explain one phenomenon is then found to explain or predict others. In the corpuscular system there is "no unexpected success, no happy coincidence, no convergence of principles from remote quarters"; but in the wave system, "all tends to unity and simplicity." ^[266]

Hence, in 1850, when Foucault and Fizeau found by experiment that light travels more slowly in water than in air, in accordance with the wave explanation of refraction and contrary to the corpuscular explanation, the result came as no surprise.^[267]

 الفنارات وعدسة فرينل

للمزيد من المعلومات: عدسة فرينل § التاريخ

Fresnel was not the first person to focus a lighthouse beam using a lens. That distinction apparently belongs to the London glass-cutter Thomas Rogers, whose first lenses, 53 cm in diameter and 14 cm thick at the center, were installed at the Old Lower Lighthouse at Portland Bill in 1789. Further samples were installed in about half a dozen other locations by 1804. But much of the light was wasted by absorption in the glass.^[268][269]

1: Cross-section of Buffon/Fresnel lens. 2: Cross-section of conventional plano-convex lens of equivalent power. (Buffon's version was biconvex.^[270])

Nor was Fresnel the first to suggest replacing a convex lens with a series of concentric annular prisms, to reduce weight and absorption. In 1748, Count Buffon proposed grinding such prisms as steps in a single piece of glass.^[4] In 1790,^[271] the Marquis de Condorcet suggested that it would be easier to make the annular sections separately and assemble them on a frame; but even that was impractical at the time.^[272][273] These designs were intended not for lighthouses,^[4] but for burning glasses.^[274] Brewster, however, proposed a system similar to Condorcet's in 1811,^{[4][275][132]} and by 1820 was advocating its use in British lighthouses.^[276]

Meanwhile, on 21 June 1819, Fresnel was "temporarily" seconded by the Commission des Phares (Commission of Lighthouses) on the recommendation of Arago (a member of the Commission since 1813), to review possible improvements in lighthouse illumination.^[277][272] The commission had been established by Napoleon in 1811 and placed under the Corps des Ponts—Fresnel's employer.^[278]

By the end of August 1819, unaware of the Buffon-Condorcet-Brewster proposal,^[272][132] Fresnel made his first presentation to the commission,^[279] recommending what he called lentilles à échelons (lenses by steps) to replace the reflectors then in use, which reflected only about half of the incident light.^{[280][Note 10]} One of the assembled commissioners, Jacques Charles, recalled Buffon's suggestion, leaving Fresnel embarrassed for having again "broken through an open door".^[270] But, whereas Buffon's version was biconvex and in one piece, Fresnel's was plano-convex and made of multiple prisms for easier construction. With an official budget of 500 francs, Fresnel approached three manufacturers. The third, François Soleil, produced the prototype. Finished in March 1820, it had a square lens panel 55 cm on a side, containing 97 polygonal (not annular) prisms—and so impressed the Commission that Fresnel was asked for a full eight-panel version. This model, completed a year later in spite of insufficient funding, had panels 76 cm square. In a public spectacle on the evening of 13 April 1821, it was demonstrated by comparison with the most recent reflectors, which it suddenly rendered obsolete.^[281]

Cross-section of a first-generation Fresnel lighthouse lens, with sloping mirrors m, n above and below the refractive panel RC (with central segment A). If the cross-section in every vertical plane through the lamp L is the same, the light is spread evenly around the horizon.

Fresnel's next lens was a rotating apparatus with eight "bull's-eye" panels, made in annular arcs by Saint-Gobain,^[273] giving eight rotating beams—to be seen by mariners as a periodic flash. Above and behind each main panel was a smaller, sloping bull's-eye panel of trapezoidal outline with trapezoidal elements.^[282] This refracted the light to a sloping plane mirror, which then reflected it horizontally, 7 degrees ahead of the main beam, increasing the duration of the flash.^[283] Below the main panels were 128 small mirrors arranged in four rings, stacked like the slats of a louver or Venetian blind. Each ring, shaped as a frustum of a cone, reflected the light to the horizon, giving a fainter steady light between the flashes. The official test, conducted on the unfinished Arc de Triomphe on 20 August 1822, was witnessed by the commission—and by Louis XVIII and his entourage—from 32 km away. The apparatus was stored at Bordeaux for the winter, and then reassembled at Cordouan Lighthouse under Fresnel's supervision. On 25 July 1823, the world's first lighthouse Fresnel lens was lit.^[284] Soon afterwards, Fresnel started coughing up blood.^[285]

In May 1824,^[132] Fresnel was promoted to secretary of the Commission des Phares, becoming the first member of that body to draw a salary,^[286] albeit in the concurrent role of Engineer-in-Chief.^[287] He was also an examiner (not a teacher) at the École Polytechnique since 1821; but poor health, long hours during the examination season, and anxiety about judging others induced him to resign that post in late 1824, to save his energy for his lighthouse work.^[34][288]

In the same year he designed the first fixed lens—for spreading light evenly around the horizon while minimizing waste above or below.^[272] Ideally the curved refracting surfaces would be segments of toroids about a common vertical axis, so that the dioptric panel would look like a cylindrical drum. If this was supplemented by reflecting (catoptric) rings above and below the refracting (dioptric) parts, the entire apparatus would look like a beehive.^[289] The second Fresnel lens to enter service was indeed a fixed lens, of third order, installed at Dunkirk by 1 February 1825.^[290] However, due to the difficulty of fabricating large toroidal prisms, this apparatus had a 16-sided polygonal plan.^[291]

In 1825, Fresnel extended his fixed-lens design by adding a rotating array outside the fixed array. Each panel of the rotating array was to refract part of the fixed light from a horizontal fan into a narrow beam.^[272][292]

Also in 1825, Fresnel unveiled the Carte des Phares (Lighthouse Map), calling for a system of 51 lighthouses plus smaller harbor lights, in a hierarchy of lens sizes (called orders, the first order being the largest), with different characteristics to facilitate recognition: a constant light (from a fixed lens), one flash per minute (from a rotating lens with eight panels), and two per minute (sixteen panels).^[293]

First-order rotating catadioptric Fresnel lens, dated 1870, displayed at the Musée national de la Marine, Paris. In this case the dioptric prisms (inside the bronze rings) and catadioptric prisms (outside) are arranged to give a purely flashing light with four flashes per rotation. The assembly stands 2.54 metres tall and weighs about 1.5 tonnes.

In late 1825,^[294] to reduce the loss of light in the reflecting elements, Fresnel proposed to replace each mirror with a catadioptric prism, through which the light would travel by refraction through the first surface, then total internal reflection off the second surface, then refraction through the third surface.^[295] The result was the lighthouse lens as we now know it. In 1826 he assembled a small model for use on the Canal Saint-Martin,^[296] but he did not live to see a full-sized version.

The first fixed lens with toroidal prisms was a first-order apparatus designed by the Scottish engineer Alan Stevenson under the guidance of Léonor Fresnel, and fabricated by Isaac Cookson & Co. from French glass; it entered service at the Isle of May in 1836.^[297] The first large catadioptric lenses were fixed third-order lenses made in 1842 for the lighthouses at Gravelines and Île Vierge. The first fully catadioptric first-order lens, installed at Ailly in 1852, gave eight rotating beams assisted by eight catadioptric panels at the top (to lengthen the flashes), plus a fixed light from below. The first fully catadioptric lens with purely revolving beams—also of first order—was installed at Saint-Clément-des-Baleines in 1854, and marked the completion of Augustin Fresnel's original Carte des Phares.^[298]

Close-up view of a thin plastic Fresnel lens

Production of one-piece stepped dioptric lenses—roughly as envisaged by Buffon—became practical in 1852, when John L. Gilliland of the Brooklyn Flint-Glass Company patented a method of making such lenses from press-molded glass.^[299] By the 1950s, the substitution of plastic for glass made it economic to use fine-stepped Fresnel lenses as condensers in overhead projectors.^[300] Still finer steps can be found in low-cost plastic "sheet" magnifiers.

 التكريم

Bust of Augustin Fresnel by David d'Angers (1854), formerly at the lighthouse of Hourtin, Gironde, and now exhibited at the Musée national de la Marine

Fresnel was elected to the Société Philomathique de Paris in April 1819,^[301] and in 1822 became one of the editors of the Société's  Bulletin des Sciences.^[302] As early as May 1817, at Arago's suggestion, Fresnel applied for membership of the Académie des Sciences, but received only one vote.^[301] The successful candidate on that occasion was Joseph Fourier. In November 1822, Fourier's elevation to Permanent Secretary of the Académie created a vacancy in the physics section, which was filled in February 1823 by Pierre Louis Dulong, with 36 votes to Fresnel's 20. But in May 1823, after another vacancy was left by the death of Jacques Charles,  Fresnel's election was unanimous.^[303] In 1824,^[304] Fresnel was made a chevalier de la Légion d'honneur (Knight of the Legion of Honour).^[9]

Meanwhile, in Britain, the wave theory was yet to take hold; Fresnel wrote to Thomas Young in November 1824, saying in part:

I am far from denying the value that I attach to the praise of English scholars, or pretending that they would not have flattered me agreeably. But for a long time this sensibility, or vanity, which is called the love of glory, has been much blunted in me: I work far less to capture the public's votes than to obtain an inner approbation which has always been the sweetest reward of my efforts. Doubtless I have often needed the sting of vanity to excite me to pursue my researches in moments of disgust or discouragement; but all the compliments I received from MM. Arago, Laplace, and Biot never gave me as much pleasure as the discovery of a theoretical truth and the confirmation of my calculations by experiment.^[305]

But "the praise of English scholars" soon followed. On 9 June 1825, Fresnel was made a Foreign Member of the Royal Society of London.^[306] In 1827^[25][307] he was awarded the society's Rumford Medal for the year 1824, "For his Development of the Undulatory Theory as applied to the Phenomena of Polarized Light, and for his various important discoveries in Physical Optics." ^[308]

A monument to Fresnel at his birthplace^[7][10]

(see above)  was dedicated on 14 September 1884^[8] with a speech by Jules Jamin, Permanent Secretary of the Académie des Sciences.^[9][309]  "FRESNEL" is among the 72 names embossed on the Eiffel Tower (on the south-east side, fourth from the left). In the 19th century, as every lighthouse in France acquired a Fresnel lens, every one acquired a bust of Fresnel, seemingly watching over the coastline that he had made safer.^[310] The lunar features Promontorium Fresnel and Rimae Fresnel were later named after him.^[311]

 التدهور والوفاة

Fresnel's grave at Père Lachaise Cemetery, Paris, photographed in 2018

Fresnel's health, which had always been poor, deteriorated in the winter of 1822–1823, increasing the urgency of his original research, and (in part) preventing him from contributing an article on polarization and double refraction for the Encyclopædia Britannica.^[312] The memoirs on circular and elliptical polarization and optical rotation,^[200] and on the detailed derivation of the Fresnel equations and their application to total internal reflection,^[195] date from this period. In the spring he recovered enough, in his own view, to supervise the lens installation at Cordouan. Soon afterwards, it became clear that his condition was tuberculosis.^[285]

In 1824, he was advised that if he wanted to live longer, he needed to scale back his activities. Perceiving his lighthouse work to be his most important duty, he resigned as an examiner at the École Polytechnique, and closed his scientific notebooks. His last note to the Académie, read on 13 June 1825, described the first radiometer and attributed the observed repulsive force to a temperature difference.^[313] Although his fundamental research ceased, his advocacy did not; as late as August or September 1826, he found the time to answer Herschel's queries on the wave theory.^[314] It was Herschel who recommended Fresnel for the Royal Society's Rumford Medal.^[315]

Fresnel's cough worsened in the winter of 1826–1827, leaving him too ill to return to Mathieu in the spring. The Académie meeting of 30 April 1827 was the last that he attended. In early June he was carried to Ville-d'Avray, 12 كيلومتر (7.5 mi) west of Paris. There his mother joined him. On 6 July, Arago arrived to deliver the Rumford Medal. Sensing Arago's distress, Fresnel whispered that "the most beautiful crown means little, when it is laid on the grave of a friend." Fresnel did not have the strength to reply to the Royal Society. He died eight days later, on Bastille Day.^[316]

He is buried at Père Lachaise Cemetery, Paris. The inscription on his headstone is partly eroded away; the legible part says, when translated, "To the memory of Augustin Jean Fresnel, member of the Institute of France".

 منشورات بعد وفاته

Émile Verdet (1824–1866)

Fresnel's "second memoir" on double refraction^[234] was not printed until late 1827, a few months after his death.^[317] Until then, the best published source on his work on double refraction was an extract of that memoir, printed in 1822.^[318] His final treatment of partial reflection and total internal reflection,^[195] read to the Académie in January 1823, was thought to be lost until it was rediscovered among the papers of the deceased Joseph Fourier (1768–1830), and was printed in 1831. Until then, it was known chiefly through an extract printed in 1823 and 1825. The memoir introducing the parallelepiped form of the Fresnel rhomb,^[319] read in March 1818, was mislaid until 1846,^[320] and then attracted such interest that it was soon republished in English.^[321] Most of Fresnel's writings on polarized light before 1821—including his first theory of chromatic polarization (submitted 7 October 1816) and the crucial "supplement" of January 1818 ^[133]—were not published in full until his Oeuvres complètes ("complete works") began to appear in 1866.^[322] The "supplement" of July 1816, proposing the "efficacious ray" and reporting the famous double-mirror experiment, met the same fate,^[323] as did the "first memoir" on double refraction.^[324]

Publication of Fresnel's collected works was itself delayed by the deaths of successive editors. The task was initially entrusted to Félix Savary, who died in 1841. It was restarted twenty years later by the Ministry of Public Instruction. Of the three editors eventually named in the Oeuvres, Sénarmont died in 1862, Verdet in 1866, and Léonor Fresnel in 1869, by which time only two of the three volumes had appeared.^[325] At the beginning of vol. 3 (1870), the completion of the project is described in a long footnote by "J. Lissajous."

Not included in the Oeuvres ^[326] are two short notes by Fresnel on magnetism, which were discovered among Ampère's manuscripts.^[327] In response to Ørsted's discovery of electromagnetism in 1820, Ampère initially supposed that the field of a permanent magnet was due to a macroscopic circulating current. Fresnel suggested instead that there was a microscopic current circulating around each particle of the magnet. In his first note, he argued that microscopic currents, unlike macroscopic currents, would explain why a hollow cylindrical magnet does not lose its magnetism when cut longitudinally. In his second note, dated 5 July 1821, he further argued that a macroscopic current had the counterfactual implication that a permanent magnet should be hot, whereas microscopic currents circulating around the molecules might avoid the heating mechanism.^[327] He was not to know that the fundamental units of permanent magnetism are even smaller than molecules

(see Electron magnetic moment). The two notes, together with Ampère's acknowledgment, were eventually published in 1885.^[328]

 أعمال مفقودة

Fresnel's essay Rêveries of 1814 has not survived.^[329] The article "Sur les Différents Systèmes relatifs à la Théorie de la Lumière" ("On the Different Systems relating to the Theory of Light"), which Fresnel wrote for the newly launched English journal European Review,^[330] was received by the publisher's agent in Paris in September 1824. The journal failed before Fresnel's contribution could be published. Fresnel tried unsuccessfully to recover the manuscript. The editors of his collected works were unable to find it, and concluded that it was probably lost.^[331]

 أعمال غير مكتملة

 Aether drag and aether density

In 1810, Arago found experimentally that the degree of refraction of starlight does not depend on the direction of the earth's motion relative to the line of sight. In 1818, Fresnel showed that this result could be explained by the wave theory,^[332] on the hypothesis that if an object with refractive index ${\displaystyle{\displaystyle n}}$ moved at velocity ${\displaystyle{\displaystyle v}}$ relative to the external aether (taken as stationary), then the velocity of light inside the object gained the additional component ${\displaystyle{\displaystyle\,v(1-1/n^{2})}}$. He supported that hypothesis by supposing that if the density of the external aether was taken as unity, the density of the internal aether was ${\displaystyle{\displaystyle n^{2}}}$, of which the excess, namely ${\displaystyle{\displaystyle\,n^{2}{-}1\,}}$, was dragged along at velocity ${\displaystyle{\displaystyle v}}$, whence the average velocity of the internal aether was ${\displaystyle{\displaystyle\,v(1-1/n^{2})}}$. The factor in parentheses, which Fresnel originally expressed in terms of wavelengths,^[333] became known as the Fresnel drag coefficient.

(See Aether drag hypothesis.)

In his analysis of double refraction, Fresnel supposed that the different refractive indices in different directions within the same medium were due to a directional variation in elasticity, not density (because the concept of mass per unit volume is not directional). But in his treatment of partial reflection, he supposed that the different refractive indices of different media were due to different aether densities, not different elasticities.^[334]

 Dispersion

The analogy between light waves and transverse waves in elastic solids does not predict dispersion—that is, the frequency-dependence of the speed of propagation, which enables prisms to produce spectra and causes lenses to suffer from chromatic aberration. Fresnel, in De la Lumière and in the second supplement to his first memoir on double refraction, suggested that dispersion could be accounted for if the particles of the medium exerted forces on each other over distances that were significant fractions of a wavelength.^[335] Later, more than once, Fresnel referred to the demonstration of this result as being contained in a note appended to his "second memoir" on double refraction.^[336] No such note appeared in print, and the relevant manuscripts found after his death showed only that, around 1824, he was comparing refractive indices (measured by Fraunhofer) with a theoretical formula, the meaning of which was not fully explained.^[337]

In the 1830s, Fresnel's suggestion was taken up by Cauchy, Baden Powell, and Philip Kelland, and it was found to be tolerably consistent with the variation of refractive indices with wavelength over the visible spectrum for a variety of transparent media

(see Cauchy's equation).^[338] These investigations were enough to show that the wave theory was at least compatible with dispersion; if the model of dispersion was to be accurate over a wider range of frequencies, it needed to be modified so as to take account of resonances within the medium

(see Sellmeier equation).^[339]

 Conical refraction

The analytical complexity of Fresnel's derivation of the ray-velocity surface was an implicit challenge to find a shorter path to the result. This was answered by MacCullagh in 1830, and by William Rowan Hamilton in 1832.^{[340][341][342]}

 Legacy

The lantern room of the Cordouan Lighthouse, in which the first Fresnel lens entered service in 1823. The current fixed catadioptric "beehive" lens replaced Fresnel's original rotating lens in 1854.^[343]

Within a century of Fresnel's initial stepped-lens proposal, more than 10,000 lights with Fresnel lenses were protecting lives and property around the world.^[344] Concerning the other benefits, the science historian Theresa H. Levitt has remarked:

Everywhere I looked, the story repeated itself. The moment a Fresnel lens appeared at a location was the moment that region became linked into the world economy.^[345]

In the history of physical optics, Fresnel's successful revival of the wave theory nominates him as the pivotal figure between Newton, who held that light consisted of corpuscles, and James Clerk Maxwell, who established that light waves are electromagnetic. Whereas Albert Einstein described Maxwell's work as "the most profound and the most fruitful that physics has experienced since the time of Newton," ^[346] commentators of the era between Fresnel and Maxwell made similarly strong statements about Fresnel:

• MacCullagh, as early as 1830, wrote that Fresnel's mechanical theory of double refraction "would do honour to the sagacity of Newton".^[341]
• Lloyd, in his Report on the progress and present state of physical optics (1834) for the British Association for the Advancement of Science, surveyed previous knowledge of double refraction and declared:

  The theory of Fresnel to which I now proceed,—and which not only embraces all the known phenomena, but has even outstripped observation, and predicted consequences which were afterwards fully verified,—will, I am persuaded, be regarded as the finest generalization in physical science which has been made since the discovery of universal gravitation.^[347]

  In 1841, Lloyd published his Lectures on the Wave-theory of Light, in which he described Fresnel's transverse-wave theory as "the noblest fabric which has ever adorned the domain of physical science, Newton's system of the universe alone excepted." ^[6]
• William Whewell, in all three editions of his History of the Inductive Sciences (1837, 1847, and 1857), at the end of Book IX, compared the histories of physical astronomy and physical optics and concluded:

  It would, perhaps, be too fanciful to attempt to establish a parallelism between the prominent persons who figure in these two histories. If we were to do this, we must consider Huyghens and Hooke as standing in the place of Copernicus, since, like him, they announced the true theory, but left it to a future age to give it development and mechanical confirmation; Malus and Brewster, grouping them together, correspond to Tycho Brahe and Kepler, laborious in accumulating observations, inventive and happy in discovering laws of phenomena; and Young and Fresnel combined, make up the Newton of optical science.^[348]

What Whewell called the "true theory" has since undergone two major revisions. The first, by Maxwell, specified the physical fields whose variations constitute the waves of light. Without the benefit of this knowledge, Fresnel managed to construct the world's first coherent theory of light, showing in retrospect that his methods are applicable to multiple types of waves. The second revision, initiated by Einstein's explanation of the photoelectric effect, supposed that the energy of light waves was divided into quanta, which were eventually identified with particles called photons. But photons did not exactly correspond to Newton's corpuscles; for example, Newton's explanation of ordinary refraction required the corpuscles to travel faster in media of higher refractive index, which photons do not. Neither did photons displace waves; rather, they led to the paradox of wave–particle duality. Moreover, the phenomena studied by Fresnel, which included nearly all the optical phenomena known at his time, are still most easily explained in terms of the wave nature of light. So it was that, as late as 1927, the astronomer Eugène Michel Antoniadi declared Fresnel to be "the dominant figure in optics." ^[349]

 انظر أيضاً

• Birefringence
• Catadioptric system
• Circular polarization
• Fresnel diffraction
• Elliptical polarization
• Fresnel (unit of frequency)
• Fresnel–Arago laws
• Fresnel equations
• Fresnel imager
• Fresnel integral
• Fresnel lantern
• Fresnel lens
• Fresnel number
• Fresnel rhomb
• Fresnel zone
• Fresnel zone antenna
• Fresnel's wave surface
• Fresnel zone plate
• Huygens–Fresnel principle
• Linear polarization
• Optical rotation
• Phasor
• Physical crystallography before X-rays
• Physical optics
• Poisson's /Arago's spot
• Polarization
• Ridged mirror

 Explanatory notes

1. ^ English pronunciation varies: []ˈfreɪnɛl,_ʔnəl[] FRAY-nel, --nəl, or []ˈfrɛnɛl,_ʔəl[] FREN-el, --əl, or []freɪˈnɛl[] fray-NEL.^[1] الفرنسية: [oɡystɛ̃ ʒɑ̃ fʁɛnɛl];^[2]
2. ^ Newton (1730) observed feathers acting as reflection gratings and as a transmission gratings, but classified the former case under thin plates (p. 252), and the latter, more vaguely, under inflection (p. 322). In retrospect, the latter experiment (p. 322, end of Obs. 2) is dangerous to eyesight and should not be repeated as written.
3. ^ The story that Ampère lost the essay (propagated from Boutry, 1948, p. 593?) is implicitly contradicted by Darrigol (2012, p. 198), Buchwald (1989, p. 117), Mérimée's letter to Fresnel dated 20 December 1814 (in Fresnel, 1866–70, vol. 2, pp. 830–831), and two footnotes in Fresnel's collected works (Fresnel, 1866–70, vol. 1, pp. xxix–xxx, note 4, and p. 6n).
4. ^ "Young's book", which Fresnel distinguished from the Philosophical Transactions, is presumably A Course of Lectures on Natural Philosophy and the Mechanical Arts (2 volumes, 1807). In vol. 1, the relevant illustrations are Plate XX (facing p. 777), including the famous two-source interference pattern (Fig. 267), and Plate XXX (facing p. 787), including the hyperbolic paths of the fringes in that pattern (Fig. 442) followed by sketches of other diffraction patterns and thin-plate patterns, with no visual hints on their physical causes. In vol. 2, which includes the Bakerian lectures from the Philosophical Transactions, Fig. 108 (p. 632) shows just one case of an undeviated direct ray intersecting a reflected ray.
5. ^ Silliman (1967, p. 163) and Frankel (1976, p. 156) give the date of Arago's note on scintillation as 1814; but the sequence of events implies 1816, in agreement with Darrigol (2012, pp. 201,‍290).  Kipnis (1991, pp. 202–203, 206) proves the later date and explains the origin and propagation of the incorrect earlier date.
6. ^ In the same installment, Fresnel acknowledged a letter from Young to Arago, dated 29 April 1818 (and lost before 1866), in which Young suggested that light waves could be analogous to waves on stretched strings. But Fresnel was dissatisfied with the analogy because it suggested both transverse and longitudinal modes of propagation and was hard to reconcile with a fluid medium (Silliman, 1967, pp. 214–215; Fresnel, 1821a, §13).
7. ^ Fresnel, in an effort to show that transverse waves were not absurd, suggested that the aether was a fluid comprising a lattice of molecules, adjacent layers of which would resist a sliding displacement up to a certain point, beyond which they would gravitate towards a new equilibrium. Such a medium, he thought, would behave as a solid for sufficiently small deformations, but as a perfect liquid for larger deformations. Concerning the lack of longitudinal waves, he further suggested that the layers offered incomparably greater resistance to a change of spacing than to a sliding motion (Silliman, 1967, pp. 216–218; Fresnel, 1821a, §§ 11–12; cf. Fresnel, 1827, tr. Hobson, pp. 258–262).
8. ^ The s originally comes from the German senkrecht, meaning perpendicular (to the plane of incidence).
9. ^ In Fresnel's collected works (1866–70), a paper is said to have been "presented" ("présenté") if it was merely delivered to the Permanent Secretary of the Académie for witnessing or processing (cf. vol. 1, p. 487; vol. 2, pp. 261,‍308). In such cases this article prefers the generic word "submitted", to avoid the impression that the paper had a formal reading.
10. ^ Another report by Fresnel, dated 29 August 1819 (Fresnel, 1866–70, vol. 3, pp. 15–21), concerns tests on reflectors, and does not mention stepped lenses except in an unrelated sketch on the last page of the manuscript. The minutes of the meetings of the Commission go back only to 1824, when Fresnel himself took over as Secretary (Fresnel, 1866–70, vol. 3, p. 6n). Thus, unfortunately, it is not possible to ascertain the exact date on which Fresnel formally recommended lentilles à échelons.

 References

 Citations

1. ^ J. Wells (2008), Longman Pronunciation Dictionary (3rd ed.), Pearson Longman, ISBN 978-1-4058-8118-0.
2. ^ "Fresnel", Collins English Dictionary / Webster's New World College Dictionary.
3. ^ Darrigol, 2012, pp. 220–223.
4. ^ ^{أ ب ت ث}  Chisholm, Hugh, ed. (1911). "Lighthouse" . دائرة المعارف البريطانية. Vol. 16 (eleventh ed.). Cambridge University Press. pp. 627–651. {{cite encyclopedia}}: Cite has empty unknown parameter: |coauthors= (help).
5. ^ Darrigol, 2012, p. 205.
6. ^ ^{أ ب} H. Lloyd, Lectures on the Wave-theory of Light, Dublin: Milliken, 1841, Part II, Lecture III, p. 26. The same description was retained in the "second edition", published under the title Elementary Treatise on the Wave-theory of Light (London: Longman, Brown, Green, Longmans, & Roberts, 1857; p. 136), and in the "third edition" (London: Longmans, Green, & Co., 1873; p. 167), which appeared in the same year as Maxwell's Treatise on Electricity and Magnetism.
7. ^ ^{أ ب ت ث}  'martan' (author), "Eure (27)", Guide National des Maisons Natales, 30 May 2014.
8. ^ ^{أ ب} Bibliothèques et Médiathèque, "Inauguration à Broglie, le 14 Septembre 1884 du buste d'Augustin Fresnel", archived 28 July 2018.
9. ^ ^{أ ب ت} Académie des Sciences, "Augustin Fresnel", accessed 21 August 2017; archived 15 February 2017.
10. ^ ^{أ ب} D. Perchet, "Monument à Augustin Fresnel – Broglie", e-monumen.net, 5 July 2011.
11. ^ ^{أ ب} J.H. Favre, "Augustin Fresnel", geneanet.org, accessed 30 August 2017.
12. ^ ^{أ ب ت}  'jeanelie' (author), "Augustine Charlotte Marie Louise Merimee" and "Louis Jacques Fresnel", geneanet.org, accessed 30 August 2017.
13. ^ Levitt (2013, p. 23) says "in 1790". Silliman (1967, p. 7) says "by 1790". Boutry (1948, p. 590) says the family left Broglie in 1789.
14. ^ ^{أ ب} Silliman, 2008, p. 166.
15. ^ Boutry, 1948, p. 590.
16. ^ Levitt, 2013, p. 99.
17. ^ Fresnel, 1866–70.
18. ^ Levitt, 2013, p. 72.
19. ^ ^{أ ب} Pillet, Maurice (1881–1964) (1922). L'expédition scientifique et artistique de Mésopotamie et de Médie, 1851–1855 (in الفرنسية). Accessed from Gallica – Bibliothèque nationale de France: Libraire Ancienne Honoré Champion.{{cite book}}: CS1 maint: numeric names: authors list (link)
20. ^ Levitt, 2009, p. 49.
21. ^ Levitt, 2013, pp. 24–25; Buchwald, 1989, p. 111.
22. ^ That age was given by Arago in his elegy (Arago, 1857, p. 402) and widely propagated (Encyclopædia Britannica, 1911; Buchwald, 1989, p. 111; Levitt, 2013, p. 24; etc.). But the reprint of the elegy at the end of Fresnel's collected works bears a footnote, presumably by Léonor Fresnel, saying that "eight" should be "five or six", and regretting "the haste with which we had to collect the notes that were belatedly requested for the biographical part of this speech" (Fresnel, 1866–70, vol. 3, p. 477n). Silliman (1967, p. 9n) accepts the correction.
23. ^ Levitt, 2013, p. 25; Arago, 1857, p. 402; Boutry, 1948, pp. 590–591.
24. ^ Levitt, 2013, pp. 25–26; Silliman, 1967, pp. 9–11.
25. ^ ^{أ ب}  Chisholm, Hugh, ed. (1911). "Fresnel, Augustin Jean" . دائرة المعارف البريطانية. Vol. 11 (eleventh ed.). Cambridge University Press. p. 209. {{cite encyclopedia}}: Cite has empty unknown parameter: |coauthors= (help).
26. ^ Boutry, 1948, p. 592.
27. ^ Silliman, 1967, p. 14; Arago, 1857, p. 403. Fresnel's solution was printed in the Correspondance sur l'École polytechnique, No. 4 (June–July 1805), pp. 78–80, and reprinted in Fresnel, 1866–70, vol. 2, pp. 681–684. Boutry (1948, p. 591) takes this story as referring to the entrance examination.
28. ^ Levitt, 2013, pp. 26–27; Silliman, 2008, p. 166; Boutry, 1948, pp. 592, 601.
29. ^ Kneller, tr. Kettle, 1911, p. 147.  Kneller interprets the quote as referring to Augustin; but Verdet (in Fresnel, 1866–70, vol. 1, pp. xcviii–xcix), cited by Silliman (1967, p. 8), gives it a different context, referring to Louis's academic success.
30. ^ Levitt, 2013, p. 24.
31. ^ Kneller, 1911, p. 148.
32. ^ Kneller, 1911, pp. 148–149n; cf. Arago, 1857, p. 470.
33. ^ Grattan-Guinness, 1990, pp. 914–915.
34. ^ ^{أ ب ت} H.M. Brock, "Fresnel, Augustin-Jean", Catholic Encyclopedia, 1907–12, vol. 6 (1909).
35. ^ Fresnel, 1866–70, vol. 1, p. xcvii.
36. ^ Reilly, D. (December 1951). "Salts, acids & alkalis in the 19th century; a comparison between advances in France, England & Germany". Isis; an International Review Devoted to the History of Science and Its Cultural Influences. 42 (130): 287–296. doi:10.1086/349348. ISSN 0021-1753. PMID 14888349.
37. ^ Cf.  Silliman, 1967, pp. 28–33; Levitt, 2013, p. 29; Buchwald, 1989, pp. 113–114.  The surviving correspondence on soda ash extends from August 1811 to April 1812; see Fresnel, 1866–70, vol. 2, pp. 810–817.
38. ^ Boutry, 1948, pp. 593–594.
39. ^ Fresnel, 1866–70, vol. 2, p. 819; emphasis in original.
40. ^ Boutry, 1948, p. 593; Arago, 1857, pp. 407–408; Fresnel, 1815a.
41. ^ Académie des Sciences, "History of the French Académie des sciences", accessed 8 December 2017; archived 13 August 2017.
42. ^ Arago, 1857, p. 405; Silliman, 2008, p. 166.  Arago does not use quotation marks.
43. ^ Levitt, 2013, pp. 38–39; Boutry, 1948, p. 594; Arago, 1857, pp. 405–406; Kipnis, 1991, p. 167.
44. ^ Huygens, 1690, tr. Thompson, pp. 20–21.
45. ^ Newton, 1730, p. 362.
46. ^ Huygens, 1690, tr. Thompson, pp. 22–38.
47. ^ Darrigol, 2012, pp. 93–94, 103.
48. ^ Darrigol, 2012, pp. 129–130, 258.
49. ^ Huygens, 1690, tr. Thompson, pp. 52–105.
50. ^ de Witte, A. J. (1 May 1959). "Equivalence of Huygens' Principle and Fermat's Principle in Ray Geometry". American Journal of Physics. 27 (5): 293–301. Bibcode:1959AmJPh..27..293D. doi:10.1119/1.1934839. ISSN 0002-9505.Erratum: In Fig. 7(b), each instance of "ray" should be "normal" (noted in vol. 27, no. 6, p. 387).
51. ^ Young, 1855, pp. 225–226, 229.
52. ^ Darrigol, 2012, pp. 62–64.
53. ^ Darrigol, 2012, p. 87.
54. ^ Newton, Isaac (18 November 1672). "Mr. Isaac Newtons answer to some considerations upon his doctrine of light and colors; which doctrine was printed in Numb. 80 of these tracts". Philosophical Transactions of the Royal Society of London (in الإنجليزية). 7 (88): 5084–5103. doi:10.1098/rstl.1672.0051. ISSN 0261-0523. JSTOR 100964.
55. ^ Darrigol, 2012, pp. 53–56.
56. ^ Huygens, 1690, tr. Thompson, p. 17.
57. ^ Darrigol, 2012, pp. 98–100; Newton, 1730, p. 281.
58. ^ Newton, 1730, p. 284.
59. ^ Newton, 1730, pp. 283,‍287.
60. ^ ^{أ ب} N. Kipnis, "Physical optics", in I. Grattan-Guinness (ed.), Companion Encyclopedia of the History and Philosophy of the Mathematical Sciences,  JHU Press, 2003, vol. 2, pp. 1143–1152.
61. ^ Newton, 1730, pp. 279, 281–282.
62. ^ ^{أ ب ت ث ج} T. Young, "On the Theory of Light and Colours" (Bakerian Lecture), Philosophical Transactions of the Royal Society, vol. 92 (1802), pp. 12–48, read 12 November 1801.
63. ^ Darrigol, 2012, pp. 101–102; Newton, 1730, Book III, Part I.
64. ^ Darrigol, 2012, pp. 177–179.
65. ^ Young, 1855, p. 188.
66. ^ Young, 1855, pp. 179–181.
67. ^ Darrigol, 2012, p. 187.
68. ^ Huygens, 1690, tr. Thompson, pp. 92–94. For simplicity, the above text describes a special case; Huygens's description has greater generality.
69. ^ Newton, 1730, pp. 358–361.
70. ^ Newton, 1730, pp. 373–374.
71. ^ Newton, 1730, p. 363.
72. ^ Newton, 1730, p. 356.
73. ^ ^{أ ب} Buchwald, Jed Z. (1 December 1980). "Experimental investigations of double refraction from Huygens to Malus". Archive for History of Exact Sciences (in الإنجليزية). 21 (4): 311–373. doi:10.1007/BF00595375. ISSN 1432-0657. As the author notes, alternative rules for the extraordinary refraction were offered by La Hire in 1710 and by Haüy in 1788 (see pp. 332–334, 335–337, respectively).
74. ^ Frankel (1974) and Young (1855, pp. 225–228) debunk Laplace's claim to have established the existence of such a force. Fresnel (1827, tr. Hobson, pp. 239–241) more comprehensively addresses the mechanical difficulties of this claim. Admittedly, the particular statement that he attributes to Laplace is not found in the relevant passage from Laplace's writings (appended to Fresnel's memoir by the translator), which is similar to the passage previously demolished by Young; however, an equivalent statement is found in the works of Malus (Mémoires de Physique et de Chimie, de la Société d'Arcueil, vol. 2, 1809, p. 266, quoted in translation by Silliman, 1967, p. 131).
75. ^ Young, 1855, pp. 228–232; cf. Whewell, 1857, p. 329.
76. ^ Darrigol, 2012, pp. 191–192; Silliman, 1967, pp. 125–127.
77. ^ Brewster, David (31 December 1815). "IX. On the laws which regulate the polarisation of light by reflexion from transparent bodies". Philosophical Transactions of the Royal Society of London (in الإنجليزية). 105: 125–159. doi:10.1098/rstl.1815.0010. ISSN 0261-0523. JSTOR 107362.
78. ^ Darrigol, 2012, p. 192; Silliman, 1967, p. 128.
79. ^ Young, 1855, pp. 249–250.
80. ^ Young, 1855, p. 233.
81. ^ Levitt, 2009, p. 37; Darrigol, 2012, pp. 193–194, 290.
82. ^ Darrigol, 2012, pp. 194–195 (ordinary intensity); Frankel, 1976, p. 148 (both intensities).
83. ^ Buchwald, 1989, pp. 79–88; Levitt, 2009, pp. 33–54.
84. ^ ^{أ ب} Buchwald, J Z (May 1989). "The battle between Arago and Biot over Fresnel". Journal of Optics. 20 (3): 109–117. Bibcode:1989JOpt...20..109B. doi:10.1088/0150-536X/20/3/002. ISSN 0150-536X.
85. ^ Frankel, 1976, pp. 149–150; Buchwald, 1989, pp. 99–103; Darrigol, 2012, pp. 195–196.
86. ^ Frankel, 1976, pp. 151–152; Darrigol, 2012, p. 196.
87. ^ Young, 1855, pp. 269–272.
88. ^ ^{أ ب} Frankel, 1976, p. 176; cf. Silliman, 1967, pp. 142–143.
89. ^ Frankel, 1976, p. 155.
90. ^ Buchwald, 1989, pp. 116–117; Silliman, 1967, pp. 40–45; Fresnel, 1866–70, vol. 2, p. 831; Levitt, 2009, p. 49.
91. ^ Boutry, 1948, pp. 594–595.
92. ^ Presumably  G.W. Jordan, The Observations of Newton Concerning the Inflections of Light; Accompanied by Other Observations Differing from His; and Appearing to Lead to a Change of His Theory of Light and Colours (also cited as New Observations concerning the Inflections of Light), London: T. Cadell Jr. & W. Davies, 1799;  reviewed in T.G. Smollett (ed.), The Critical Review, Or, Annals of Literature (London), vol. 34, pp. 436–443 (April 1802).
93. ^ Fresnel, 1866–70, vol. 1, p. 6n; Kipnis, 1991, p. 167; emphasis added.
94. ^ ^{أ ب} Fresnel, 1866–70, vol. 1, pp. 6–7.
95. ^ Fresnel, 1866–70, vol. 1, pp. xxxi (micrometer, locksmith [serrurier], supports), 6n (locksmith); Buchwald, 1989, pp. 122 (honey drop), 125–126 (micrometer, with diagram); Boutry 1948, p. 595 and Levitt, 2013, p. 40 (locksmith, honey drop, micrometer); Darrigol 2012, pp. 198–199 (locksmith, honey drop).
96. ^ Buchwald, 1989, pp. 122, 126; Silliman, 1967, pp. 147–149.
97. ^ Levitt, 2013, pp. 39,‍239.
98. ^ Kipnis, 1991, p. 167; Fresnel, 1866–70, vol. 1, pp. 5–6.
99. ^ Darrigol, 2012, p. 198. Silliman (1967, p. 146) identifies the brother as Fulgence, then in Paris; cf. Fresnel, 1866–70, vol. 1, p. 7n.
100. ^ Darrigol, 2012, p. 199.
101. ^ Buchwald, 1989, pp. 119, 131–132; Darrigol, 2012, pp. 199–201; Kipnis, 1991, pp. 175–176.
102. ^ Darrigol, 2012, p. 201.
103. ^ Fresnel, 1866–70, vol. 1, pp. 48–49; Kipnis, 1991, pp. 176–178.
104. ^ Frankel, 1976, p. 158; Fresnel, 1866–70, vol. 1, p. 9n.
105. ^ Fresnel, 1866–70, vol. 1, p. 38; italics added.
106. ^ Buchwald, 1989, pp. 137–139.
107. ^ Young, 1807, vol. 1, p. 787 & Figs. 442,‍445; Young, 1855, pp. 180–181, 184.
108. ^ Young to Arago (in English), 12 January 1817, in Young, 1855, pp. 380–384, at p. 381; quoted in Silliman, 1967, p. 171.
109. ^ Newton, 1730, p. 321, Fig. 1, where the straight rays DG, EH, FI contribute to the curved path of a fringe, so that the same fringe is made by different rays at different distances from the obstacle  (cf. Darrigol, 2012, p. 101, Fig. 3.11 – where, in the caption, "1904" should be "1704" and "CFG" should be "CFI").
110. ^ Kipnis, 1991, pp. 204–205.
111. ^ Silliman, 1967, pp. 163–164; Frankel, 1976, p. 158; Boutry, 1948, p. 597; Levitt, 2013, pp. 41–43, 239.
112. ^ Silliman, 1967, pp. 165–166; Buchwald, 1989, p. 137; Kipnis, 1991, pp. 178, 207, 213.
113. ^ Fresnel, 1816.
114. ^ Darrigol, 2012, p. 201; Frankel, 1976, p. 159.
115. ^ Kipnis, 1991, pp. 166n,‍214n.
116. ^ Kipnis, 1991, pp. 212–214; Frankel, 1976, pp. 159–160, 173.
117. ^ Cf. Young, 1807, vol. 1, p. 777 & Fig. 267.
118. ^ Darrigol, 2012, p. 201; the letter is printed in Young, 1855, pp. 376–378, and its conclusion is translated by Silliman (1967, p. 170).
119. ^ Fresnel, 1866–70, vol. 1, pp. 129–170.
120. ^ Silliman, 1967, pp. 177–179; Darrigol, 2012, pp. 201–203.
121. ^ Buchwald, 1989, pp. 134–135, 144–145; Silliman, 1967, pp. 176–177.
122. ^ Silliman, 1967, pp. 173–175; Buchwald, 1989, pp. 137–138; Darrigol, 2012, pp. 201–2; Boutry, 1948, p. 597; Fresnel, 1866–70, vol. 1, pp. 123–128 (Arago's announcement).
123. ^ Levitt, 2013, p. 43; Boutry, 1948, p. 599.
124. ^ Arago, 1857, pp. 404–405.
125. ^ Levitt, 2013, pp. 28, 237.
126. ^ Kipnis, 1991, p. 218; Buchwald, 2013, p. 453; Levitt, 2013, p. 44.  Frankel (1976, pp. 160–161) and Grattan-Guinness (1990, p. 867) note that the topic was first proposed on 10 February 1817. Darrigol alone (2012, p. 203) says that the competition was "opened" on 17 March 1818. Prizes were offered in odd-numbered years for physics and in even-numbered years for mathematics (Frankel, 1974, p. 224n).
127. ^ Buchwald, 1989, pp. 169–171; Frankel, 1976, p. 161; Silliman, 1967, pp. 183–184; Fresnel, 1866–70, vol. 1, pp. xxxvi–xxxvii.
128. ^ Fresnel, 1866–70, vol. 1, p. xxxv; Levitt, 2013, p. 44.
129. ^ Silliman, 2008, p. 166; Frankel, 1976, p. 159.
130. ^ Fresnel, 1866–70, vol. 1, pp. xxxv, xcvi; Boutry, 1948, pp. 599,‍601.  Silliman (1967, p. 180) gives the starting date as 1 May 1818.
131. ^ Fresnel, 1866–70, vol. 1, p. xcvi; Arago, 1857, p. 466.
132. ^ ^{أ ب ت ث} G. Ripley and C.A. Dana (eds.), "Fresnel, Augustin Jean", American Cyclopædia, 1879, vol. 7, pp. 486–489. Contrary to this entry (p. 486), calcite and quartz were not the only doubly refractive crystals known before Fresnel; see (e.g.) Young, 1855, p. 250 (written 1810) and pp. 262,‍266,‍277 (written 1814), and Lloyd, 1834, pp. 376–377.
133. ^ ^{أ ب ت ث} A. Fresnel, "Supplément au Mémoire sur les modifications que la réflexion imprime à la lumière polarisée" ("Supplement to the Memoir on the modifications that reflection impresses on polarized light"), signed 15 January 1818, submitted for witnessing 19 January 1818; printed in Fresnel, 1866–70, vol. 1, pp. 487–508.
134. ^ Printed in Fresnel, 1866–70, vol. 1, pp. 171–181.
135. ^ Cf. Fresnel, 1866–70, vol. 1, pp. 174–175; Buchwald, 1989, pp. 157–158.
136. ^ Buchwald, 1989, p. 167; 2013, p. 454.
137. ^ Fresnel, 1818b.
138. ^ See Fresnel, 1818b, in Mémoires de l'Académie Royale des Sciences…, vol. V, p. 339n, and in Fresnel, 1866–70, vol. 1, p. 247, note 1.
139. ^ Fresnel, 1866–70, vol. 1, p. 247; Crew, 1900, p. 79; Levitt, 2013, p. 46.
140. ^ Crew, 1900, pp. 101–108 (vector-like representation), 109 (no retrograde radiation), 110–111 (directionality and distance), 118–122 (derivation of integrals), 124–125 (maxima & minima), 129–131 (geometric shadow).
141. ^ Darrigol, 2012, pp. 204–205.
142. ^ Crew, 1900, pp. 127–128 (wavelength), 129–131 (half-plane), 132–135 (extrema, slit); Fresnel, 1866–70, vol. 1, pp. 350–355 (narrow strip).
143. ^ Buchwald, 1989, pp. 179–182.
144. ^ Crew, 1900, p. 144.
145. ^ Fresnel, 1866–70, vol. 1, p. xlii; Worrall, 1989, p. 136; Buchwald, 1989, pp. 171, 183; Levitt, 2013, pp. 45–46.
146. ^ Levitt, 2013, p. 46.
147. ^ Frankel, 1976, p. 162. However, Kipnis (1991, pp. 222–224) offers evidence that the unsuccessful entrant was Honoré Flaugergues (1755–1830?) and that the essence of his entry is contained in a "supplement" published in Journal de Physique, vol. 89 (September 1819), pp. 161–186.
148. ^ Fresnel, 1866–70, vol. 1, pp. 236–237.
149. ^ Worrall, 1989, pp. 139–140.
150. ^ Cf. Worrall, 1989, p. 141.
151. ^ B. Watson, Light: A Radiant History from Creation to the Quantum Age, New York: Bloomsbury, 2016.
152. ^ Darrigol, 2012, p. 205; Fresnel, 1866–70, vol. 1, p. xlii.
153. ^ Fresnel, 1866–70, vol. 1, p. xlii; Worrall, 1989, p. 141.
154. ^ Fresnel, 1866–70, vol. 1, pp. 229–246.
155. ^ Fresnel, 1866–70, vol. 1, p. 229, note 1; Grattan-Guinness, 1990, p. 867; Levitt, 2013, p. 47.
156. ^ Fresnel, 1866–70, vol. 1, p. 237; Worrall, 1989, p. 140.
157. ^ ^{أ ب} Académie des Sciences, Proces-verbaux des séances de l'Académie tenues depuis la fondation de l'Institut jusqu'au mois d'août 1835, vol. VI (for 1816–19), Hendaye, Basses Pyrénées: Imprimerie de l'Observatoire d'Abbadia, 1915.
158. ^ Fresnel, 1866–70, vol. 1, p. 230n.
159. ^ Worrall, 1989, pp. 135–138; Kipnis, 1991, p. 220.
160. ^ Worrall, 1989, pp. 143–145. The printed version of the report also refers to a note (E), but this note concerns further investigations that took place after the prize was decided (Worrall, 1989, pp. 145–146; Fresnel, 1866–70, vol. 1, pp. 236, 245–246). According to Kipnis (1991, pp. 221–222), the real significance of Poisson's spot and its complement (at the center of the disk of light cast by a circular aperture) was that they concerned the intensities of fringes, whereas Fresnel's measurements had concerned only the positions of fringes; but, as Kipnis also notes, this issue was pursued only after the prize was decided.
161. ^ Concerning their later  views, see  §‍Reception.
162. ^ Buchwald, 1989, pp. 183–184; Darrigol, 2012, p. 205.
163. ^ Kipnis, 1991, pp. 219–220, 224, 232–233; Grattan-Guinness, 1990, p. 870.
164. ^ Buchwald, 1989, pp. 186–198; Darrigol, 2012, pp. 205–206; Kipnis, 1991, p. 220.
165. ^ Buchwald, 1989, pp. 50–51, 63–5, 103–104; 2013, pp. 448–449.
166. ^ Buchwald, 1989, pp. 203,‍205; Darrigol, 2012, p. 206; Silliman, 1967, pp. 203–205.
167. ^ Arago & Fresnel, 1819.
168. ^ Darrigol, 2012, p. 207; Frankel, 1976, pp. 163–164, 182.
169. ^ Darrigol, 2012, p. 206.
170. ^ Frankel, 1976, p. 164.
171. ^ Buchwald, 1989, p. 386.
172. ^ Buchwald, 1989, pp. 216,‍384.
173. ^ Buchwald, 1989, pp. 333–336; Darrigol, 2012, pp. 207–208. (Darrigol gives the date as 1817, but the page numbers in his footnote 95 fit his reference "1818b", not "1817".)
174. ^ Fresnel, 1866–70, vol. 1, pp. 533–537. On the provenance of the note, see p. 523. In the above text, φ is an abbreviation for Fresnel's 2π(e − o), where e and o are the numbers of cycles taken by the extraordinary and ordinary waves to travel through the lamina.
175. ^ Buchwald, 1989, p. 97; Frankel, 1976, p.  148.
176. ^ Fresnel, 1821b.
177. ^ Fresnel, 1821b, §3.
178. ^ Fresnel, 1821b, §1 & footnotes.
179. ^ Buchwald, 1989, pp. 237–251; Frankel, 1976, pp. 165–168; Darrigol, 2012, pp. 208–209.
180. ^ Fresnel, 1821a, §10.
181. ^ Fresnel, 1866–70, vol. 1, p. 394n; Fresnel, 1821a, §10; Silliman, 1967, pp. 209–210; Buchwald, 1989, pp. 205–206, 208, 212, 218–219.
182. ^ Young, 1855, p. 383.
183. ^ ^{أ ب} T. Young, "Chromatics" (written Sep.– Oct. 1817), Supplement to the Fourth, Fifth, and Sixth Editions of the Encyclopædia Britannica, vol. 3 (issued February 1818), reprinted in Young, 1855, pp. 279–342.
184. ^ Buchwald, 1989, pp. 225–226; Fresnel, 1866–70, vol. 1, pp. 526–527, 529.
185. ^ Buchwald, 1989, p. 226.
186. ^ Fresnel, 1821a.
187. ^ Buchwald, 1989, p. 227; Fresnel, 1821a, §1.
188. ^ Buchwald, 1989, p. 212; Fresnel, 1821a, §10.
189. ^ Fresnel, 1821a, §10; emphasis added.
190. ^ Fresnel, 1821a, §13;  cf. Buchwald, 1989, p. 228.
191. ^ Cf. Buchwald, 1989, p. 230.
192. ^ "This hypothesis of Mr. Fresnel is at least very ingenious, and may lead us to some satisfactory computations: but it is attended by one circumstance which is perfectly appalling in its consequences. The substances on which Mr. Savart made his experiments were solids only; and it is only to solids that such a lateral resistance has ever been attributed: so that if we adopted the distinctions laid down by the reviver of the undulatory system himself, in his Lectures, it might be inferred that the luminiferous ether, pervading all space, and penetrating almost all substances, is not only highly elastic, but absolutely solid!!!" — Thomas Young (written January 1823), Sect. XIII in "Refraction, double, and polarisation of light", Supplement to the Fourth, Fifth, and Sixth Editions of the Encyclopædia Britannica, vol. 6 (1824), at p. 862, reprinted in Young, 1855, at p. 415 (italics and exclamation marks in the original). The "Lectures" that Young quotes next are his own (Young, 1807, vol. 1, p. 627).
193. ^ Buchwald, 1989, pp. 388–390; Fresnel, 1821a, §18.
194. ^ Buchwald, 1989, pp. 390–391; Fresnel, 1821a, §§ 20–22.
195. ^ ^{أ ب ت ث} A. Fresnel, "Mémoire sur la loi des modifications que la réflexion imprime à la lumière polarisée" ("Memoir on the law of the modifications that reflection impresses on polarized light"), read 7 January 1823; reprinted in Fresnel, 1866–70, vol. 1, pp. 767–799 (full text, published 1831), pp. 753–762 (extract, published 1823). See especially pp. 773 (sine law), 757 (tangent law), 760–761 and 792–796 (angles of total internal reflection for given phase differences).
196. ^ Buchwald, 1989, pp. 391–393; Whittaker, 1910, pp. 133–135.
197. ^ Whittaker, 1910, p. 134; Darrigol, 2012, p. 213; Fresnel, 1866–70, vol. 1, pp. 773,‍757.
198. ^ Buchwald, 1989, pp. 393–394; Whittaker, 1910, pp. 135–136; Fresnel, 1866–70, vol. 1, pp. 760–761, 792–796.
199. ^ Whittaker, 1910, pp. 177–179; Buchwald, 2013, p. 467.
200. ^ ^{أ ب ت} A. Fresnel, "Mémoire sur la double réfraction que les rayons lumineux éprouvent en traversant les aiguilles de cristal de roche suivant les directions parallèles à l'axe" ("Memoir on the double refraction that light rays undergo in traversing the needles of rock crystal [quartz] in directions parallel to the axis"), read 9 December 1822; printed in Fresnel, 1866–70, vol. 1, pp. 731–751 (full text), pp. 719–29 (extract, first published in Bulletin de la Société philomathique for 1822, pp. 191–198).
201. ^ Buchwald, 1989, pp. 230–232, 442.
202. ^ Cf. Buchwald, 1989, p. 232.
203. ^ Item re  Brewster, "On a new species of moveable polarization", [Quarterly] Journal of Science and the Arts, vol. 2, no. 3, 1817, p. 213.
204. ^ Lloyd, 1834, p. 368.
205. ^ Darrigol, 2012, p. 207.
206. ^ A. Fresnel, "Mémoire sur les modifications que la réflexion imprime à la lumière polarisée" ("Memoir on the modifications that reflection impresses on polarized light"), signed & submitted 10 November 1817, read 24 November 1817; printed in Fresnel, 1866–70, vol. 1, pp. 441–485, including pp. 452 (rediscovery of depolarization by total internal reflection), 455 (two reflections, "coupled prisms", "parallelepiped in glass"), 467–8 (phase difference per reflection); see also p. 487, note 1 (date of reading). Kipnis (1991, p. 217n) confirms the reading and adds that the paper was published in 1821.
207. ^ Buchwald, 1989, pp. 223,‍336; on the latter page, a "prism" means a Fresnel rhomb or equivalent. A footnote in the 1817 memoir (Fresnel, 1866–70, vol. 1, p. 460, note 2) described the emulator more briefly, and not in a self-contained manner.
208. ^ Fresnel, 1818a, especially pp. 47–49.
209. ^ Jenkins & White, 1976, pp. 576–579 (§ 27.9, esp. Fig. 27M).
210. ^ For illustrations see J.M. Derochette, "Conoscopy of biaxial minerals (1)", www.jm-derochette.be, 2004; archived 1 May 2017.
211. ^ Buchwald, 1989, pp. 254–255, 402.
212. ^ Cf. Buchwald, 1989, p. 269.
213. ^ Grattan-Guinness, 1990, p. 885.
214. ^ Buchwald, 1989, pp. 269,‍418.
215. ^ J.-B. Biot, "Mémoire sur les lois générales de la double réfraction et de la polarisation, dans les corps régulièrement cristallisés" (read 29 March 1819), Mémoires de l'Académie Royale des Sciences…, vol. III (for 1818 [ك‍], printed 1820), pp. 177–384; "Extrait d'un Mémoire sur les lois de la double réfraction et de la polarisation dans les corps régulièrement cristallisés", Bulletin des Sciences par la Société Philomathique de Paris, 1820, pp. 12–16, including pp. 13–14 (sine law), 15–16 (dihedral law).
216. ^ Cf.  Fresnel, 1822a, tr. Young, in Quarterly Journal of Science, Literature, and Art,  Jul.– Dec. 1828, at pp. 178–179.
217. ^ Buchwald, 1989, p. 260.
218. ^ Printed in Fresnel, 1866–70, vol. 2, pp. 261–308.
219. ^ Silliman, 1967, pp. 243–246 (first experiment); Buchwald, 1989, pp. 261–267 (both experiments). The first experiment was briefly reported earlier in Fresnel, 1821c.
220. ^ Buchwald (1989, pp. 267–272) and Grattan-Guinness (1990, pp. 893–894 call it the "ellipsoid of elasticity".
221. ^ Buchwald, 1989, pp. 267–272; Grattan-Guinness, 1990, pp. 885–887.
222. ^ Buchwald, 1989, pp. 274–279.
223. ^ Buchwald, 1989, pp. 279–280.
224. ^ Literally "surface of the wave"—as in Hobson's translation of Fresnel 1827.
225. ^ Fresnel, 1866–70, vol. 2, pp. 340, 361–363; Buchwald, 1989, pp. 281–283. The derivation of the "wave surface" from its tangent planes was eventually accomplished by Ampère in 1828 (Lloyd, 1834, pp. 386–387; Darrigol, 2012, p. 218; Buchwald, 1989, pp. 281,‍457).
226. ^ Fresnel, 1866–70, vol. 2, pp. 369–442.
227. ^ Buchwald, 1989, pp. 283–285; Darrigol, 2012, pp. 217–218; Fresnel, 1866–70, vol. 2, pp. 386–388.
228. ^ W.N. Griffin, The Theory of Double Refraction, Cambridge: T. Stevenson, 1842.
229. ^ Grattan-Guinness, 1990, pp. 891–892; Fresnel, 1866–70, vol. 2, pp. 371–379.
230. ^ Buchwald, 1989, pp. 285–286; Fresnel, 1866–70, vol. 2, p. 396.
231. ^ Lunney, James G.; Weaire, Denis (1 May 2006). "The ins and outs of conical refraction". Europhysics News (in الإنجليزية). 37 (3): 26–29. Bibcode:2006ENews..37c..26L. doi:10.1051/epn:2006305. ISSN 0531-7479.
232. ^ Grattan-Guinness, 1990, pp. 896–897.  Silliman, 1967, pp. 262–263; 2008, p. 170
233. ^ Buchwald, 1989, pp. 286–287, 447.
234. ^ ^{أ ب} Fresnel, 1827.
235. ^ Fresnel, 1866–70, vol. 2, p. 800n. Although the original publication (Fresnel, 1827) shows the year "1824" in selected page footers, it is known that Fresnel, slowed down by illness, did not finish the memoir until 1826 (Buchwald, 1989, pp. 289,‍447, citing Fresnel, 1866–70, vol. 2, p. 776n).
236. ^ Fresnel, 1827, tr. Hobson, pp. 266–273.
237. ^ Fresnel, 1827, tr. Hobson, pp. 281–285.
238. ^ Fresnel, 1827, tr. Hobson, pp. 320–322; Buchwald, 1989, p. 447.
239. ^ Grattan-Guinness, 1990, pp. 1003–1009, 1034–1040, 1043; Whittaker, 1910, pp. 143–145; Darrigol, 2012, p. 228.  Grattan-Guinness offers evidence against any earlier dating of Cauchy's theories.
240. ^ Whittaker, 1910, chapter V; Darrigol, 2012, chapter 6; Buchwald, 2013, pp. 460–464.
241. ^ Fresnel, 1827, tr. Hobson, pp. 273–281; Silliman, 1967, p. 268n; Buchwald, 1989, p. 288.
242. ^ Brewster, David (31 December 1815). "V. On the effects of simple pressure in producing that species of crystallization which forms two oppositely polarised images, and exhibits the complementary colours by polarised light". Philosophical Transactions of the Royal Society of London (in الإنجليزية). 105: 60–64. doi:10.1098/rstl.1815.0006. ISSN 0261-0523. JSTOR 107358.
243. ^ Brewster, David (31 December 1816). "X. On the communication of the structure of doubly refracting crystals to glass, muriate of soda, fluor spar, and other substances, by mechanical compression and dilatation". Philosophical Transactions of the Royal Society of London (in الإنجليزية). 106: 156–178. doi:10.1098/rstl.1816.0011. ISSN 0261-0523. JSTOR 107522.
244. ^ A. Fresnel, "Note sur la double réfraction du verre comprimé" ("Note on the double refraction of compressed glass"), read 16 September 1822, published 1822; reprinted in Fresnel, 1866–70, vol. 1, pp. 713–718, at pp. 715–717.
245. ^ Whewell, 1857, pp. 355–356.
246. ^ Fresnel, 1866–70, vol. 1, pp. 737–739 (§4).  Cf. Whewell, 1857, p. 356–358; Jenkins & White, 1976, pp. 589–590.
247. ^ Fresnel, 1822a.
248. ^ Grattan-Guinness, 1990, p. 884.
249. ^ Cf. Frankel, 1976, p. 169.
250. ^ Fresnel, 1866–70, vol. 2, pp. 261n,‍369n.
251. ^ Printed in Fresnel, 1866–70, vol. 2, pp. 459–464.
252. ^ Buchwald, 1989, p. 288.
253. ^ Fresnel, 1866–70, vol. 1, pp. lxxxvi–lxxxvii; Grattan-Guinness, 1990, p. 896.
254. ^ Grattan-Guinness, 1990, p. 898.
255. ^ Buchwald, 1989, pp. 289–390.
256. ^ Frankel, 1976, pp. 170–171; cf. Fresnel, 1827, tr. Hobson, pp. 243–244, 262.
257. ^ Silliman, 1967, pp. 284–285, citing Fresnel, 1866–70, vol. 1, p. lxxxix, note 2.  Frankel (1976, p. 173) agrees. Worrall (1989, p. 140) is skeptical.
258. ^ Frankel, 1976, pp. 173–174.
259. ^ J.F.W. Herschel, "Light", Encyclopædia Metropolitana, vol. 4 (London, 1845; re-issued 1849), pp. 341–586;  reprinted (with original page numbers and appended plates) in J.F.W. Herschel, Treatises on Physical Astronomy, Light and Sound, contributed to the Encyclopædia Metropolitana,  London and Glasgow: R. Griffin & Co. (undated).
260. ^ Buchwald, 1989, pp. 291–296; Darrigol, 2012, pp. 220–221, 303.
261. ^ Fresnel, 1822a; Kipnis, 1991, pp. 227–228.
262. ^ Buchwald, 1989, p. 296.
263. ^ G.B. Airy, "On the diffraction of an object-glass with circular aperture", Transactions of the Cambridge Philosophical Society, vol. V, part III (1835), pp. 283–291 (read 24 November 1834).
264. ^ Darrigol, 2012, pp. 222–223, 248.
265. ^ Kipnis, 1991, pp. 225,‍227; Darrigol, 2012, pp. 223,‍245.
266. ^ Whewell, 1857, pp. 340–341; the quoted paragraphs date from the 1st Ed. (1837).
267. ^ Whewell, 1857, pp. 482–483; Whittaker, 1910, p. 136; Darrigol, 2012, p. 223.
268. ^ T. Tag, "Lens use prior to Fresnel", U.S. Lighthouse Society, accessed 12 August 2017; archived 20 May 2017.
269. ^ Levitt, 2013, p. 57.
270. ^ ^{أ ب} Levitt, 2013, p. 59.
271. ^ N. de Condorcet, Éloge de M. le Comte de Buffon, Paris: Chez Buisson, 1790, pp. 11–12.
272. ^ ^{أ ب ت ث ج} T. Tag, "The Fresnel lens", U.S. Lighthouse Society, accessed 12 August 2017; archived 22 July 2017.
273. ^ ^{أ ب} Levitt, 2013, p. 71.
274. ^ D. Appleton & Co., "Sea-lights", Dictionary of Machines, Mechanics, Engine-work, and Engineering, 1861, vol. 2, pp. 606–618.
275. ^ T. Tag, "Chronology of Lighthouse Events", U.S. Lighthouse Society, accessed 22 August 2017; archived 8 April 2017.
276. ^  Chisholm, Hugh, ed. (1911). "Brewster, Sir David" . دائرة المعارف البريطانية. Vol. 4 (eleventh ed.). Cambridge University Press. pp. 513–514. {{cite encyclopedia}}: Cite has empty unknown parameter: |coauthors= (help).
277. ^ Levitt, 2013, pp. 51,‍53; Fresnel, 1866–70, vol. 1, p. xcvii, and vol. 3, p. xxiv.
278. ^ Levitt, 2013, pp. 49–50.
279. ^ Fresnel, 1866–70, vol. 3, pp. 5–14; on the date, see p. 6n.
280. ^ Levitt, 2013, pp. 56,‍58.
281. ^ Levitt, 2013, pp. 59–66. On the dimensions see Elton, 2009, pp. 193–194; Fresnel, 1866–70, vol. 3, p. xxxiv; Fresnel, 1822b, tr. Tag, p. 7.
282. ^ D. Gombert, photograph of the Optique de Cordouan in the collection of the Musée des Phares et Balises, Ouessant, France, 23 March 2017.
283. ^ Fresnel, 1822b, tr. Tag, pp. 13,‍25.
284. ^ Elton, 2009, p. 195;  Levitt, 2013, pp. 72–76.
285. ^ ^{أ ب} Levitt, 2013, p. 97.
286. ^ Levitt, 2013, p. 82.
287. ^ Elton, 2009, p. 190.
288. ^ Grattan-Guinness, 1990, pp. 914–915, citing Young, 1855, p. 399;  Arago, 1857, pp. 467, 470; Boutry, 1948, pp. 601–602.
289. ^ Cf. Elton, 2009, p. 198, Figure 12.
290. ^ Levitt, 2013, p. 84.
291. ^ Elton, 2009, pp. 197–198.
292. ^ Elton, 2009, pp. 198–199.
293. ^ Levitt, 2013, pp. 82–84.
294. ^ Elton, 2009, p. 200.
295. ^ Levitt, 2013, pp. 79–80.
296. ^ Musée national de la Marine, "Appareil catadioptrique, Appareil du canal Saint-Martin", accessed 26 August 2017; archived 26 August 2017.
297. ^ Elton, 2009, pp. 199,‍200,‍202; Levitt, 2013, pp. 104–105.
298. ^ Levitt, 2013, pp. 108–110, 113–116, 122–123.
299. ^ T. Tag, "American-Made Fresnel Lenses", U.S. Lighthouse Society, accessed 1 March 2021; archived 21 February 2021.
300. ^ A. Finstad, "New developments in audio-visual materials", Higher Education, vol. 8, no. 15 (1 April 1952), pp. 176–178, at p. 176.
301. ^ ^{أ ب} Kipnis, 1991, p. 217.
302. ^ Frankel, 1976, p. 172.
303. ^ Grattan-Guinness, 1990, pp. 861, 913–914; Arago, 1857, p. 408. Silliman (1967, p. 262n) gives the dates of the respective elections as 27 January and 12 May 1823.
304. ^ Levitt, 2013, p. 77.
305. ^ Young, 1855, pp. 402–403.
306. ^ Royal Society, List of Fellows of the Royal Society 1660–2007, A–J, July 2007, p. 130.
307. ^ G.E. Rines (ed.), "Fresnel, Augustin Jean", Encyclopedia Americana, 1918–20, vol. 12 (1919), p.93. (This entry inaccurately describes Fresnel as the "discoverer" of polarization of light and as a "Fellow" of the Royal Society, whereas in fact he explained polarization and was a "Foreign Member" of the Society; see text.)
308. ^ Royal Society, "Rumford Medal" (with link to full list of past winners), accessed 2 September 2017.
309. ^ J. Jamin, Discours prononcé au nom de l'Académie des Sciences à l'inauguration du monument de Fresnel, Broglie, 14 September 1884; accessed 6 September 2017.
310. ^ Levitt, 2013, p. 233.
311. ^ IAU WGPSN, "Promontorium Fresnel" and "Rimae Fresnel", Gazetteer of Planetary Nomenclature, accessed 19 December 2017.
312. ^ Levitt, 2013, pp. 75–76; Silliman, 1967, pp. 276–277.
313. ^ Boutry, 1948, pp. 601–602; Silliman, 1967, p. 278; Fresnel, 1866–70, vol. 2, pp. 667–672.
314. ^ Fresnel, 1866–70, vol. 2, pp. 647–660.
315. ^ Boutry, 1948, p. 603.
316. ^ Levitt, 2013, p. 98; Silliman, 1967, p. 279; Arago, 1857, p. 470; Boutry, 1948, pp. 602–603.
317. ^ Fresnel, 1866–70, vol. 2, p. 800n.
318. ^ Buchwald, 1989, p. 289.
319. ^ Fresnel, 1818a.
320. ^ Kipnis, 1991, pp. 207n,‍217n; Buchwald, 1989, p. 461, ref. 1818d; Fresnel, 1866–70, vol. 1, p. 655n.
321. ^ In  Taylor, 1852, pp. 44–65.
322. ^ Buchwald, 1989, pp. 222, 238, 461–462.
323. ^ Grattan-Guinness, 1990, p. 861.
324. ^ Whittaker, 1910, p. 125n.
325. ^ Boutry, 1948, pp. 603–604; Fresnel, 1866–70, vol. 1, pp. i–vii.
326. ^ Silliman, 2008, p. 171.
327. ^ ^{أ ب} A.K.T. Assis and J.P.M.C. Chaib, Ampère's Electrodynamics ("Analysis of the meaning and evolution of Ampère’s force between current elements, together with a complete translation of his masterpiece: Theory of Electrodynamic Phenomena, Uniquely Deduced from Experience"), Montreal: Apeiron, 2015.
328. ^ J. Joubert (ed.), Collection de Mémoires relatifs à la Physique, vol. 2 (being Part 1 of Mémoires sur l'électrodynamique), Paris: Gauthier-Villars, 1885, pp. 140 (Ampère's acknowledgment), 141–147 (Fresnel's notes).
329. ^ Buchwald, 1989, p. 116.
330. ^ Fresnel, 1866–70, vol. 2, pp. 768n, 802.
331. ^ Fresnel, 1866–70, vol. 2, p. 803n.  Grattan-Guinness (1990, p. 884n) gives the year of composition as 1825, but this does not match the primary sources.
332. ^ Cf. Darrigol, 2012, pp. 258–260.
333. ^ Fresnel, 1818c.
334. ^ Darrigol, 2012, p. 212; Fresnel, 1821a, §§ 14, 18.
335. ^ Darrigol, 2012, p. 246; Buchwald, 1989, pp. 307–308;  Fresnel, 1822a, tr. Young, in Quarterly Journal of Science, Literature, and Art,  Jan.– Jun. 1828, at pp. 213–215.  Whittaker, 1910, p. 132; Fresnel, 1866–70, vol. 2, p. 438.
336. ^ Fresnel, 1827, tr. Hobson, pp. 277n,‍331n; Lloyd, 1834, p. 316.
337. ^ Fresnel, 1866–70, vol. 1, p. xcvi.
338. ^ Whittaker, 1910, pp. 182–183; Whewell, 1857, pp. 365–367; Darrigol, 2012, pp. 246–249.
339. ^ Darrigol, 2012, p. 252.
340. ^ Lloyd, 1834, pp. 387–388.
341. ^ ^{أ ب} MacCullagh, James (1830). "On the Double Refraction of Light in a Crystallized Medium, according to the Principles of Fresnel". The Transactions of the Royal Irish Academy. 16: 65–78. ISSN 0790-8113. JSTOR 30079025.
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343. ^ Phare de Cordouan, "The lighting systems of the Cordouan Lighthouse", accessed 26 August 2017; archived 22 September 2016.
344. ^ Levitt, 2013, p. 19.
345. ^ Levitt, 2013, p. 8.
346. ^ James Clerk Maxwell Foundation, "Who was James Clerk Maxwell?", accessed 6 August 2017; archived 30 June 2017.
347. ^ Lloyd, 1834, p. 382.
348. ^ Whewell, 1857, pp. 370–371.
349. ^ Opening sentence in  E.M. Antoniadi, "Le centenaire d'Augustin Fresnel", L'Astronomie (Paris), vol. 41, pp. 241–246 (June 1927), translated as "The centenary of Augustin Fresnel" in Annual Report of the Board of Regents of the Smithsonian Institution, Washington, 1927, pp. 217–220.

 General and cited references

• D.F.J. Arago (tr.  B. Powell), 1857, "Fresnel" (elegy read at the Public Meeting of the Academy of Sciences, 26 July 1830), in D.F.J. Arago (tr.  W.H. Smyth, B. Powell, and R. Grant), Biographies of Distinguished Scientific Men (single-volume edition), London: Longman, Brown, Green, Longmans, & Roberts, 1857, pp. 399–471. (On the translator's identity, see pp. 425n,‍452n.)  Erratum: In the translator's note on p. 413, a plane tangent to the outer sphere at point t should intersect the refractive surface (assumed flat); then, through that intersection, tangent planes should be drawn to the inner sphere and spheroid (cf. Mach, 1926, p. 263).
• D.F.J. Arago and A. Fresnel, 1819, "Mémoire sur l'action que les rayons de lumière polarisée exercent les uns sur les autres", Annales de Chimie et de Physique, Ser. 2, vol. 10, pp. 288–305, March 1819; reprinted in Fresnel, 1866–70, vol. 1, pp. 509–522; translated as "On the action of rays of polarized light upon each other", in Crew, 1900, pp. 145–155.
• G.-A. Boutry, 1948, "Augustin Fresnel: His time, life and work, 1788–1827", Science Progress, vol. 36, no. 144 (October 1948), pp. 587–604; jstor.org/stable/43413515.
• J.Z. Buchwald, 1989, The Rise of the Wave Theory of Light: Optical Theory and Experiment in the Early Nineteenth Century, University of Chicago Press, ISBN 0-226-07886-8.
• J.Z. Buchwald, 2013, "Optics in the Nineteenth Century", in J.Z. Buchwald and R. Fox (eds.), The Oxford Handbook of the History of Physics, Oxford, ISBN 978-0-19-969625-3, pp. 445–472.
• H. Crew (ed.), 1900, The Wave Theory of Light: Memoirs by Huygens, Young and Fresnel, American Book Company.
• O. Darrigol, 2012, A History of Optics: From Greek Antiquity to the Nineteenth Century, Oxford, ISBN 978-0-19-964437-7.
• J. Elton, 2009, "A Light to Lighten our Darkness: Lighthouse Optics and the Later Development of Fresnel's Revolutionary Refracting Lens 1780–1900", International Journal for the History of Engineering & Technology, vol. 79, no. 2 (July 2009), pp. 183–244; DOI:10.1179/175812109X449612.
• E. Frankel, 1974, "The search for a corpuscular theory of double refraction: Malus, Laplace and the price [ك‍] competition of 1808", Centaurus, vol. 18, no. 3 (September 1974), pp. 223–245.
• E. Frankel, 1976, "Corpuscular optics and the wave theory of light: The science and politics of a revolution in physics", Social Studies of Science, vol. 6, no. 2 (May 1976), pp. 141–184; jstor.org/stable/284930.
• A. Fresnel, 1815a, Letter to Jean François "Léonor" Mérimée, 10 February 1815 (Smithsonian Dibner Library, MSS 546A), printed in G. Magalhães, "Remarks on a new autograph letter from Augustin Fresnel: Light aberration and wave theory", Science in Context, vol. 19, no. 2 (June 2006), pp. 295–307, DOI:10.1017/S0269889706000895, at p. 306 (original French) and p. 307 (English translation).
• A. Fresnel, 1816, "Mémoire sur la diffraction de la lumière" ("Memoir on the diffraction of light"), Annales de Chimie et de Physique, Ser. 2, vol. 1, pp. 239–281 (March 1816); reprinted as "Deuxième Mémoire…" ("Second Memoir…") in Fresnel, 1866–70, vol. 1, pp. 89–122.  Not  to be confused with the later "prize memoir" (Fresnel, 1818b).
• A. Fresnel, 1818a, "Mémoire sur les couleurs développées dans les fluides homogènes par la lumière polarisée", read 30 March 1818 (according to Kipnis, 1991, p. 217), published 1846; reprinted in Fresnel, 1866–70, vol. 1, pp. 655–683; translated by E. Ronalds & H. Lloyd as "Memoir upon the colours produced in homogeneous fluids by polarized light", in Taylor, 1852, pp. 44–65. (Cited page numbers refer to the translation.)
• A. Fresnel, 1818b, "Mémoire sur la diffraction de la lumière" ("Memoir on the diffraction of light"), deposited 29 July 1818, "crowned" 15 March 1819, published (with appended notes) in Mémoires de l'Académie Royale des Sciences de l'Institut de France, vol. V (for 1821 & 1822, printed 1826), pp. 339–475; reprinted (with notes) in Fresnel, 1866–70, vol. 1, pp. 247–383; partly translated as "Fresnel's prize memoir on the diffraction of light", in Crew, 1900, pp. 81–144.  Not  to be confused with the earlier memoir with the same French title (Fresnel, 1816).
• A. Fresnel, 1818c, "Lettre de M. Fresnel à M. Arago sur l'influence du mouvement terrestre dans quelques phénomènes d'optique", Annales de Chimie et de Physique, Ser. 2, vol. 9, pp. 57–66 & plate after p. 111 (Sep. 1818), & pp. 286–287 (Nov. 1818); reprinted in Fresnel, 1866–70, vol. 2, pp. 627–636; translated as "Letter from Augustin Fresnel to François Arago, on the influence of the movement of the earth on some phenomena of optics" in K.F. Schaffner, Nineteenth-Century Aether Theories, Pergamon, 1972 (DOI:10.1016/C2013-0-02335-3), pp. 125–135; also translated (with several errors) by R.R. Traill as "Letter from Augustin Fresnel to François Arago concerning the influence of terrestrial movement on several optical phenomena", General Science Journal, 23 January 2006 (PDF, 8 pp.).
• A. Fresnel, 1821a, "Note sur le calcul des teintes que la polarisation développe dans les lames cristallisées" et seq., Annales de Chimie et de Physique, Ser. 2, vol. 17, pp. 102–111 (May 1821), 167–196 (June 1821), 312–315 ("Postscript", July 1821); reprinted (with added section nos.) in Fresnel, 1866–70, vol. 1, pp. 609–648; translated as "On the calculation of the tints that polarization develops in crystalline plates, & postscript", قالب:Zenodo / DOI:10.5281/zenodo.4058004, 2021.
• A. Fresnel, 1821b, "Note sur les remarques de M. Biot...", Annales de Chimie et de Physique, Ser. 2, vol. 17, pp. 393–403 (August 1821); reprinted (with added section nos.) in Fresnel, 1866–70, vol. 1, pp. 601–608; translated as "Note on the remarks of Mr. Biot relating to colors of thin plates", قالب:Zenodo / DOI:10.5281/zenodo.4541332, 2021.
• A. Fresnel, 1821c, Letter to D.F.J. Arago, 21 September 1821, in Fresnel, 1866–70, vol. 2, pp. 257–259; translated as "Letter to Arago on biaxial birefringence", Wikisource, April 2021.
• A. Fresnel, 1822a, De la Lumière (On Light), in J. Riffault (ed.), Supplément à la traduction française de la cinquième édition du "Système de Chimie" par Th. Thomson, Paris: Chez Méquignon-Marvis, 1822, pp. 1–137, 535–539; reprinted in Fresnel, 1866–70, vol. 2, pp. 3–146; translated by T. Young as "Elementary view of the undulatory theory of light", Quarterly Journal of Science, Literature, and Art, vol. 22 (Jan.– Jun. 1827), pp. 127–141, 441–454; vol. 23 (Jul.– Dec. 1827), pp. 113–35, 431–448; vol. 24 (Jan.– Jun. 1828), pp. 198–215; vol. 25 (Jul.– Dec. 1828), pp. 168–191, 389–407; vol. 26 (Jan.– Jun. 1829), pp. 159–165.
• A. Fresnel, 1822b, "Mémoire sur un nouveau système d'éclairage des phares", read 29 July 1822; reprinted in Fresnel, 1866–70, vol. 3, pp. 97–126; translated by T. Tag as "Memoir upon a new system of lighthouse illumination", U.S. Lighthouse Society, accessed 26 August 2017; 19 August 2016. (Cited page numbers refer to the translation.)
• A. Fresnel, 1827, "Mémoire sur la double réfraction", Mémoires de l'Académie Royale des Sciences de l'Institut de France, vol. VII (for 1824, printed 1827), pp. 45–176; reprinted as "Second mémoire…" in Fresnel, 1866–70, vol. 2, pp. 479–596; translated by A.W. Hobson as "Memoir on double refraction", in Taylor, 1852, pp. 238–333. (Cited page numbers refer to the translation. For notable errata in the original edition, and consequently in the translation, see Fresnel, 1866–70, vol. 2, p. 596n.)
• A. Fresnel (ed.  H. de Sénarmont, E. Verdet, and L. Fresnel), 1866–70, Oeuvres complètes d'Augustin Fresnel (3 volumes), Paris: Imprimerie Impériale; vol. 1 (1866), vol. 2 (1868), vol. 3 (1870).
• I. Grattan-Guinness, 1990, Convolutions in French Mathematics, 1800–1840, Basel: Birkhäuser, vol. 2, ISBN 3-7643-2238-1, chapter 13 (pp. 852–915, "The entry of Fresnel: Physical optics, 1815–1824") and chapter 15 (pp. 968–1045, "The entry of Navier and the triumph of Cauchy: Elasticity theory, 1819–1830").
• C. Huygens, 1690, Traité de la Lumière (Leiden: Van der Aa), translated by S.P. Thompson as Treatise on Light, University of Chicago Press, 1912; Project Gutenberg, 2005. (Cited page numbers match the 1912 edition and the Gutenberg HTML edition.)
• F.A. Jenkins and H.E. White, 1976, Fundamentals of Optics, 4th Ed., New York: McGraw-Hill, ISBN 0-07-032330-5.
• N. Kipnis, 1991, History of the Principle of Interference of Light, Basel: Birkhäuser, ISBN 978-3-0348-9717-4, chapters VII, VIII.
• K.A. Kneller (tr.  T.M. Kettle), 1911, Christianity and the Leaders of Modern Science: A contribution to the history of culture in the nineteenth century, Freiburg im Breisgau: B. Herder, pp. 146–149.
• T.H. Levitt, 2009, The Shadow of Enlightenment: Optical and Political Transparency in France, 1789–1848, Oxford, ISBN 978-0-19-954470-7.
• T.H. Levitt, 2013, A Short Bright Flash: Augustin Fresnel and the Birth of the Modern Lighthouse, New York: W.W. Norton, ISBN 978-0-393-35089-0.
• H. Lloyd, 1834, "Report on the progress and present state of physical optics", Report of the Fourth Meeting of the British Association for the Advancement of Science (held at Edinburgh in 1834), London: J. Murray, 1835, pp. 295–413.
• E. Mach (tr.  J.S. Anderson & A.F.A. Young), The Principles of Physical Optics: An Historical and Philosophical Treatment, London: Methuen & Co., 1926.
• I. Newton, 1730, Opticks: or, a Treatise of the Reflections, Refractions, Inflections, and Colours of Light, 4th Ed. (London: William Innys, 1730; Project Gutenberg, 2010); republished with foreword by A. Einstein and Introduction by E.T. Whittaker (London: George Bell & Sons, 1931); reprinted with additional Preface by I.B. Cohen and Analytical Table of Contents by D.H.D. Roller,  Mineola, NY: Dover, 1952, 1979 (with revised preface), 2012. (Cited page numbers match the Gutenberg HTML edition and the Dover editions.)
• R.H. Silliman, 1967, Augustin Fresnel (1788–1827) and the Establishment of the Wave Theory of Light (PhD dissertation, 6 + 352 pp.), Princeton University, submitted 1967, accepted 1968; available from ProQuest  (missing the first page of the preface).
• R.H. Silliman, 2008, "Fresnel, Augustin Jean", Complete Dictionary of Scientific Biography, Detroit: Charles Scribner's Sons, vol. 5, pp. 165–171. (The version at encyclopedia.com lacks the diagram and equations.)
• R. Taylor (ed.), 1852, Scientific Memoirs, selected from the Transactions of Foreign Academies of Science and Learned Societies, and from Foreign Journals (in English), vol. V, London: Taylor & Francis.
• W. Whewell, 1857, History of the Inductive Sciences: From the Earliest to the Present Time, 3rd Ed., London: J.W. Parker & Son, vol. 2, book IX, chapters V–XIII.
• E. T. Whittaker, 1910, A History of the Theories of Aether and Electricity: From the age of Descartes to the close of the nineteenth century, London: Longmans, Green, & Co., chapters IV, V.
• J. Worrall, 1989, "Fresnel, Poisson and the white spot: The role of successful predictions in the acceptance of scientific theories" Archived 2 يونيو 2023 at the Wayback Machine, in D. Gooding, T. Pinch, and S. Schaffer (eds.), The Uses of Experiment: Studies in the Natural Sciences, Cambridge University Press, ISBN 0-521-33185-4, pp. 135–157.
• T. Young, 1807, A Course of Lectures on Natural Philosophy and the Mechanical Arts (2 volumes), London: J. Johnson; vol. 1, vol. 2.
• T. Young (ed. G. Peacock), 1855, Miscellaneous Works of the late Thomas Young, London: J. Murray, vol. 1.

 External links

• Media related to أوجوستان-جان فرينل at Wikimedia Commons

اقرأ اقتباسات ذات علاقة بأوجوستان-جان فرينل، في معرفة الاقتباس.

• List of English translations of works by Augustin Fresnel at Zenodo.
• United States Lighthouse Society, especially "Fresnel Lenses Archived 2 مارس 2021 at the Wayback Machine".
• Works by أوجوستان-جان فرينل on Open Library at the Internet Archive.
• "Episode 3 – Augustin Fresnel", École polytechnique, 23 January 2019, archived from the original on 22 November 2021 – via YouTube.