牛顿的微粒说和爱因斯坦的光子说的区别

Newton's corpuscular theory was an elaboration of his view of reality as interactions of material points through forces. Note Albert Einstein description of Newton's conception of physical reality:

Newton's physical reality is characterised by concepts of space， time， the material point and force (interaction between material points). Physical events are to be thought of as movements according to law of material points in space. The material point is the only representative of reality in so far as it is subject to change. The concept of the material point is obviously due to observable bodies; one conceived of the material point on the analogy of movable bodies by omitting characteristics of extension， form， spatial locality， and all their 'inner' qualities， retaining only inertia， translation， and the additional concept of force.

In physics， the photon is the elementary particle responsible for electromagnetic phenomena. It is the carrier of electromagnetic radiation of all wavelengths， including gamma rays， X-rays， ultraviolet light， visible light， infrared light， microwaves， and radio waves. The photon differs from many other elementary particles， such as the electron and the quark， in that it has zero rest mass;[3] therefore， it travels (in a vacuum) at the speed of light， c. Like all quanta， the photon has both wave and particle properties (“wave–particle duality”). Photons show wave-like phenomena， such as refraction by a lens and destructive interference when reflected waves cancel each other out; however， as a particle， it can only interact with matter by transferring the amount of energy

where h is Planck's constant， c is the speed of light， and λ is its wavelength. This is different from a classical wave， which may gain or lose arbitrary amounts of energy. For visible light the energy carried by a single photon is around 4×10–19 joules; this energy is just sufficient to excite a single molecule in a photoreceptor cell of an eye， thus contributing to vision.[4]

Apart from having energy， a photon also carries momentum and has a polarization. It follows the laws of quantum mechanics， which means that often these properties do not have a well-defined value for a given photon. Rather， they are defined as a probability to measure a certain polarization， position， or momentum. For example， although a photon can excite a single molecule， it is often impossible to predict beforehand which molecule will be excited.

The above description of a photon as a carrier of electromagnetic radiation is commonly used by physicists. However， in theoretical physics， a photon can be considered as a mediator for any type of electromagnetic interactions， including magnetic fields and electrostatic repulsion between like charges.

The modern concept of the photon was developed gradually (1905–17) by Albert Einstein[5][6][7][8] to explain experimental observations that did not fit the classical wave model of light. In particular， the photon model accounted for the frequency dependence of light's energy， and explained the ability of matter and radiation to be in thermal equilibrium. Other physicists sought to explain these anomalous observations by semiclassical models， in which light is still described by Maxwell's equations， but the material objects that emit and absorb light are quantized. Although these semiclassical models contributed to the development of quantum mechanics， further experiments proved Einstein's hypothesis that light itself is quantized; the quanta of light are photons.

The photon concept has led to momentous advances in experimental and theoretical physics， such as lasers， Bose–Einstein condensation， quantum field theory， and the probabilistic interpretation of quantum mechanics. According to the Standard Model of particle physics， photons are responsible for producing all electric and magnetic fields， and are themselves the product of requiring that physical laws have a certain symmetry at every point in spacetime. The intrinsic properties of photons—such as charge， mass and spin—are determined by the properties of this gauge symmetry.

The concept of photons is applied to many areas such as photochemistry， high-resolution microscopy， and measurements of molecular distances. Recently， photons have been studied as elements of quantum computers and for sophisticated applications in optical communication such as quantum cryptography.
牛顿的微粒说和爱因斯坦的光子说都是为了解释光的现象，牛顿把光看作一个个微粒小球，遇到平面就会反弹，但这却解释不了传播能量的问题，而光子说就弥补了这点，爱因斯坦把光看成光是一份一份的能量，具有动能和势能

自己看一下
Newton's corpuscular theory was an elaboration of his view of reality as interactions of material points through forces. Note Albert Einstein description of Newton's conception of physical reality:

Newton's physical reality is characterised by concepts of space， time， the material point and force (interaction between material points). Physical events are to be thought of as movements according to law of material points in space. The material point is the only representative of reality in so far as it is subject to change. The concept of the material point is obviously due to observable bodies; one conceived of the material point on the analogy of movable bodies by omitting characteristics of extension， form， spatial locality， and all their 'inner' qualities， retaining only inertia， translation， and the additional concept of force.

In physics， the photon is the elementary particle responsible for electromagnetic phenomena. It is the carrier of electromagnetic radiation of all wavelengths， including gamma rays， X-rays， ultraviolet light， visible light， infrared light， microwaves， and radio waves. The photon differs from many other elementary particles， such as the electron and the quark， in that it has zero rest mass;[3] therefore， it travels (in a vacuum) at the speed of light， c. Like all quanta， the photon has both wave and particle properties (“wave–particle duality”). Photons show wave-like phenomena， such as refraction by a lens and destructive interference when reflected waves cancel each other out; however， as a particle， it can only interact with matter by transferring the amount of energy

where h is Planck's constant， c is the speed of light， and λ is its wavelength. This is different from a classical wave， which may gain or lose arbitrary amounts of energy. For visible light the energy carried by a single photon is around 4×10–19 joules; this energy is just sufficient to excite a single molecule in a photoreceptor cell of an eye， thus contributing to vision.[4]

Apart from having energy， a photon also carries momentum and has a polarization. It follows the laws of quantum mechanics， which means that often these properties do not have a well-defined value for a given photon. Rather， they are defined as a probability to measure a certain polarization， position， or momentum. For example， although a photon can excite a single molecule， it is often impossible to predict beforehand which molecule will be excited.

The above description of a photon as a carrier of electromagnetic radiation is commonly used by physicists. However， in theoretical physics， a photon can be considered as a mediator for any type of electromagnetic interactions， including magnetic fields and electrostatic repulsion between like charges.

The modern concept of the photon was developed gradually (1905–17) by Albert Einstein[5][6][7][8] to explain experimental observations that did not fit the classical wave model of light. In particular， the photon model accounted for the frequency dependence of light's energy， and explained the ability of matter and radiation to be in thermal equilibrium. Other physicists sought to explain these anomalous observations by semiclassical models， in which light is still described by Maxwell's equations， but the material objects that emit and absorb light are quantized. Although these semiclassical models contributed to the development of quantum mechanics， further experiments proved Einstein's hypothesis that light itself is quantized; the quanta of light are photons.

The photon concept has led to momentous advances in experimental and theoretical physics， such as lasers， Bose–Einstein condensation， quantum field theory， and the probabilistic interpretation of quantum mechanics. According to the Standard Model of particle physics， photons are responsible for producing all electric and magnetic fields， and are themselves the product of requiring that physical laws have a certain symmetry at every point in spacetime. The intrinsic properties of photons—such as charge， mass and spin—are determined by the properties of this gauge symmetry.

The concept of photons is applied to many areas such as photochemistry， high-resolution microscopy， and measurements of molecular distances. Recently， photons have been studied as elements of quantum computers and for sophisticated applications in optical communication such as quantum cryptography.