In 1907 Einstein realized that, in all circumstances, the speed of
photons varies exactly as the speed of cannonballs does. However
recognizing that explicitly would have put an end to the system of
miracles (length contraction, time dilation etc.) that was to replace
tedious Newtonian science and convert Albert the Plagiarist into
Divine Albert. So fraud and camouflage invaded the world of science
and yet, from time to time, guilty conscience makes Einsteinians hint
at the truth:

http://www.pitt.edu/~jdnorton/papers...UP_TimesNR.pdf
John Norton: "Already in 1907, a mere two years after the completion
of the special theory, he [Einstein] had concluded that the speed of
light is variable in the presence of a gravitational field."

http://www.logosjournal.com/issue_4.3/smolin.htm
Lee Smolin: "Special relativity was the result of 10 years of
intellectual struggle, yet Einstein had convinced himself it was wrong
within two years of publishing it."

http://en.wikisource.org/wiki/The_De...e_of_Radiation
The Development of Our Views on the Composition and Essence of
Radiation by Albert Einstein, 1909
EINSTEIN'S 1909 CONFESSION: "A large body of facts shows undeniably
that light has certain fundamental properties that are better
explained by Newton's emission theory of light than by the oscillation
theory. For this reason, I believe that the next phase in the
development of theoretical physics will bring us a theory of light
that can be considered a fusion of the oscillation and emission
theories. The purpose of the following remarks is to justify this
belief and to show that a profound change in our views on the
composition and essence of light is imperative.....Then the
electromagnetic fields that make up light no longer appear as a state
of a hypothetical medium, but rather as independent entities that the
light source gives off, just as in Newton's emission theory of
light......Relativity theory has changed our views on light. Light is
conceived not as a manifestation of the state of some hypothetical
medium, but rather as an independent entity like matter. Moreover,
this theory shares with the corpuscular theory of light the unusual
property that light carries inertial mass from the emitting to the
absorbing object."

http://www.perimeterinstitute.ca/ind...ecture_id=3576
John Stachel: "Einstein discussed the other side of the particle-field
dualism - get rid of fields and just have particles."
EINSTEIN'S 1954 CONFESSION: "I consider it entirely possible that
physics cannot be based upon the field concept, that is on continuous
structures. Then nothing will remain of my whole castle in the air,
including the theory of gravitation, but also nothing of the rest of
contemporary physics."
John Stachel's comment: "If I go down, everything goes down, ha ha,
hm, ha ha ha."

http://www.pbs.org/wgbh/nova/einstein/genius/
"Genius Among Geniuses" by Thomas Levenson
A clue to EINSTEIN'S 1954 CONFESSION: "And then, in June, Einstein
completes special relativity, which adds a twist to the story:
Einstein's March paper treated light as particles, but special
relativity sees light as a continuous field of waves. Alice's Red
Queen can accept many impossible things before breakfast, but it takes
a supremely confident mind to do so. Einstein, age 26, sees light as
wave and particle, picking the attribute he needs to confront each
problem in turn. Now that's tough."

http://books.google.com/books?id=JokgnS1JtmMC
"Relativity and Its Roots" By Banesh Hoffmann
p.92: "Moreover, if light consists of particles, as Einstein had
suggested in his paper submitted just thirteen weeks before this one,
the second principle seems absurd: A stone thrown from a speeding
train can do far more damage than one thrown from a train at rest; the
speed of the particle is not independent of the motion of the object
emitting it. And if we take light to consist of particles and assume
that these particles obey Newton's laws, they will conform to
Newtonian relativity and thus automatically account for the null
result of the Michelson-Morley experiment without recourse to
contracting lengths, local time, or Lorentz transformations. Yet, as
we have seen, Einstein resisted the temptation to account for the null
result in terms of particles of light and simple, familiar Newtonian
ideas, and introduced as his second postulate something that was more
or less obvious when thought of in terms of waves in an ether."

http://press.princeton.edu/chapters/i6272.html
John Stachel: "Not only is the theory [of relativity] compatible with
an emission theory of radiation, since it implies that the velocity of
light is always the same relative to its source; the theory also
requires that radiation transfer mass between an emitter and an
absorber, reinforcing Einstein's light quantum hypothesis that
radiation manifests a particulate structure under certain
circumstances."

http://www.larecherche.fr/content/re...ticle?id=10745
Jean-Marc Lévy-Leblond: "Un siècle après son émergence, la théorie de
la relativité est encore bien mal comprise - et pas seulement par les
profanes ! Le vocable même qui la désigne (« relativité ») est fort
inadéquat. Ses énoncés courants abondent en maladresses sémantiques,
et donc en confusions épistémologiques. Paradoxe majeur, cette
théorie, présentée comme un sommet de la modernité scientifique, garde
de nombreux traits primitifs. Or, de récentes recherches montrent
éloquemment qu'un sérieux approfondissement de ses concepts et de ses
formulations peut résulter du retour à ses origines, avant même
Einstein. Déjà le principe de relativité se comprend mieux si on le
détache de la forme nouvelle qu'il prit après Lorentz, Poincaré et
Einstein, pour le ressourcer chez Galilée et Descartes. Mais surtout,
l'examen de nombreux travaux des XVIIe et XVIIIe siècles, injustement
oubliés, met en évidence une théorie particulaire de la lumière, en
germe dans la physique newtonienne, qui ouvre des voies d'approche
négligées vers la théorie moderne. Ces considérations contrebalancent
utilement le point de vue ondulatoire traditionnel, et allègent ses
difficultés."

http://ustl1.univ-lille1.fr/culture/...40/pgs/4_5.pdf
Jean Eisenstaedt: "Même s'il était conscient de l'intérêt de la
théorie de l'émission, Einstein n'a pas pris le chemin, totalement
oublié, de Michell, de Blair, des Principia en somme. Le contexte de
découverte de la relativité ignorera le XVIIIème siècle et ses racines
historiques plongent au coeur du XIXème siècle. Arago, Fresnel,
Fizeau, Maxwell, Mascart, Michelson, Poincaré, Lorentz en furent les
principaux acteurs et l'optique ondulatoire le cadre dans lequel ces
questions sont posées. Pourtant, au plan des structures physiques,
l'optique relativiste des corps en mouvement de cette fin du XVIIIème
est infiniment plus intéressante - et plus utile pédagogiquement - que
le long cheminement qu'a imposé l'éther."

http://www.mfo.de/programme/schedule...WR_2006_10.pdf
Jean Eisenstaedt: "At the end of the 18th century, a natural extension
of Newton's dynamics to light was developed but immediately forgotten.
A body of works completed the Principia with a relativistic optics of
moving bodies, the discovery of the Doppler-Fizeau effect some sixty
years before Doppler, and many other effects and ideas which represent
a fascinating preamble to Einstein relativities. It was simply
supposed that 'a body-light', as Newton named it, was subject to the
whole dynamics of the Principia in much the same way as were material
particles; thus it was subject to the Galilean relativity and its
velocity was supposed to be variable. Of course it was subject to the
short range 'refringent' force of the corpuscular theory of light --
which is part of the Principia-- but also to the long range force of
gravitation which induces Newton's theory of gravitation. The fact
that the 'mass' of a corpuscle of light was not known did not
constitute a problem since it does not appear in the Newtonian (or
Einsteinian) equations of motion. It was precisely what John Michell
(1724-1793), Robert Blair (1748-1828), Johann G. von Soldner
(1776-1833) and François Arago (1786-1853) were to do at the end of
the 18th century and the beginning the 19th century in the context of
Newton's dynamics. Actually this 'completed' Newtonian theory of light
and material corpuscle seems to have been implicitly accepted at the
time. In such a Newtonian context, not only Soldner's calculation of
the deviation of light in a gravitational field was understood, but
also dark bodies (cousins of black holes). A natural (Galilean and
thus relativistic) optics of moving bodies was also developed which
easily explained aberration and implied as well the essence of what we
call today the Doppler effect. Moreover, at the same time the
structure of -- but also the questions raised by-- the Michelson
experiment was understood. Most of this corpus has long been
forgotten. The Michell-Blair-Arago effect, prior to Doppler's effect,
is entirely unknown to physicists and historians. As to the influence
of gravitation on light, the story was very superficially known but
had never been studied in any detail. Moreover, the existence of a
theory dealing with light, relativity and gravitation, embedded in
Newton's Principia was completely ignored by physicists and by
historians as well. But it was a simple and natural way to deal with
the question of light, relativity (and gravitation) in a Newtonian
context."

Pentcho Valev