corpuscular theory of light

He was justified in sticking to his corpuscular theory of light.

His acceptance of the corpuscular theory of light may have been affected by this.

It was used by Newton, for instance, in his development of the corpuscular theory of light.

After that, the corpuscular theory of light was vanquished, not to be heard of again till the 20th century.

Newton in his Opticks of 1704 proposed instead a corpuscular theory of light.

Newton's corpuscular theory of light was gradually succeeded by the wave theory.

It is true that Newton tried to reduce light to the motion of material points in his corpuscular theory of light.

In 1704 Newton published 'Opticks', in which he expounded his corpuscular theory of light.

He disagreed with Newton's corpuscular theory of light in the Opticks, which was then the prevailing theory.

However, the theory had difficulties in other matters, and was soon overshadowed by Isaac Newton's corpuscular theory of light.

Even when discovering the so-called Newton's rings (a wave interference phenomenon) his explanation remained with his own corpuscular theory of light.

However, many still favored Isaac Newton's corpuscular theory of light, among them the great theoretician Siméon-Denis Poisson.

Bradley conceived of an explanation in terms of a corpuscular theory of light in which light is made of particles unaffected by gravity.

In this modern version of Newton's corpuscular theory of light, the local photon acts as a probe of the molecular or crystal structure (Teertstra 2008b).

Physics had abandoned ideas like the corpuscular theory of light and the transmutability of elements, then had to go back and allow as how, yes, they could be resurrected.

Light bending Soldner is now mostly remembered for having concluded - based on Newton's Corpuscular theory of light - that light would be diverted by heavenly bodies.

Newton, after all, had observed what are now recognized as diffraction phenomena, and wrote on them in his Third Book of Opticks, interpreting them in terms of his corpuscular theory of light.

Newton's corpuscular theory of light was unable to explain supernumerary rainbows, and a satisfactory explanation was not found until Thomas Young realised that light behaves as a wave under certain conditions, and can interfere with itself.

In optics, corpuscular theory of light, originally set forward by Pierre Gassendi, states that light is made up of small discrete particles called "corpuscles" (little particles) which travel in a straight line with a finite velocity and possess kinetic energy.

At around the same time, the atomic theory and the corpuscular theory of light (as updated by Einstein) first came to be widely accepted as scientific fact; these latter theories can be viewed as quantum theories of matter and electromagnetic radiation, respectively.

In Margolis's view non-contradiction applies to "sentential formulas" and not to "meaningful sentences", since discourse in use may always offset any seeming contradiction via re-interpretation, as is routinely done in science (for instance, in the case of the wave theory versus the corpuscular theory of light).

Bradley explained this effect in the context of Newton's corpuscular theory of light, by showing that the aberration angle was given by simple vector addition of the Earth's orbital velocity and the velocity of the corpuscles of light, just as vertically falling raindrops strike a moving object at an angle.