[0005]When heating, the interior of the sealed container is filled with oxygen ions and helium ions; under the irradiation of the incident light, there exists a radial repulsive force among vibrating oxygen ions and vibrating helium ions, and the radial repulsive force increases the average kinetic energy of the oxygen ions and the helium ions for thermal motion, thus increasing the temperature of the oxygen ion gas and the helium ion gas and implementing heating. The temperature of the oxygen ion gas and the helium ion gas can be controlled by controlling the amplitude, frequency, and electric moment of the incident light.
[0006]When heating, the interior of the sealed container may also be filled with hydrogen gas or other gases, and the gas is ionized into positive ions and electrons by applying an external electric field or light irradiation; under the irradiation of the incident light, the positive ions and the electrons will be forced to vibrate and behave similarly to two vibrating electric dipoles, and emit secondary electromagnetic waves, so that the average distance between the positive ions and the electrons in the sealed container is much smaller than the wavelength of the incident light, causing the vibrating positive ions and the vibrating electrons to be in the near-field of each other, and when the electric field intensity direction of the incident light and the electric moments of two vibrating electrons are in the same radial straight line and are in opposite directions, there exists a radial repulsive force among the vibrating positive ions and the vibrating electrons, and the radial repulsive force increases the average kinetic energy of the positive ions and the electrons for thermal motion, thus increasing the temperature of the positive ion gas and the electron gas and implementing heating. The temperature of the electron gas or the positive ion gas and the electron gas can be controlled by controlling the amplitude, wavelength, and electric moment of the incident light.
[0040]The electrons are irradiated with the incident light, so that the electric field intensity direction of the incident light and the electric moments of the vibrating electrons are in the same radial straight line and in the same direction, and the amplitude and frequency of the electric field intensity of the incident light are adjusted to produce an appropriate radial attractive force. The radial attractive force reduces the average kinetic energy of the electrons for thermal motion and thus reducing the temperature of the electron gas and implementing cooling. After the temperature of the refrigerator decreases, heat can be absorbed from the environment.
[0041]From formulas (2) and (16), it can be known that the attractive force FN between the vibrating electron 1 and vibrating electron 2 increases with the increase of A and ω and increases with the decrease of the distance r, and A increases with the increase of Q and A increases with the decrease of R. Therefore, controlling the charge amount Q and amplitude a of the accelerating charge that produces the incident light and the distance R between the light source and the vibrating electrons can control the radial attractive force among the vibrating electrons, thus controlling the average kinetic energy of the electrons for thermal motion to reach a set cooling temperature.
[0044]When heating, the interior of the sealed container may also be filled with hydrogen gas or other gases, the gas is ionized into positive ions and electrons by applying an external electric field or light irradiation; the average distance between the positive ions and the electrons in the sealed container is caused to be much smaller than the wavelength of the incident light, so that vibrating positive ions and vibrating electrons are in the near-zone field of each other; under the irradiation of the incident light, there exists a radial repulsive force among the vibrating positive ions and the vibrating electrons, and the radial repulsive force increases the average kinetic energy of the positive ions and the electrons for thermal motion, thus increasing the temperature of the positive ion gas and the electron gas and implementing heating. The temperature of the positive ion gas and the electron gas can be controlled by controlling the amplitude, wavelength, and electric moment of the incident light.
[0045]When heating, two sealed containers may be used, wherein the two sealed containers are respectively filled with a positive ion gas and a negative ion gas or an electron gas, there is a valve between the two sealed containers, the sealed container filled with the positive ion gas is connected to a negative electrode of a power supply, and the sealed container filled with the negative ion gas or the electron gas is connected to a positive electrode of the power supply. The average distance between positive ions and negative ions or electrons in the sealed containers is caused to be much smaller the wavelength of the incident light, so that vibrating positive ions and vibrating electrons are in the near-zone field of each other. When heating, the two sealed containers are disconnected from the positive and negative electrodes of the power supply, and the valve between the two sealed containers is opened, and the positive ion gas is mixed with the negative ion gas or the electron gas; under the irradiation of the incident light, there exists a radial repulsive force among the vibrating positive ions and the vibrating negative ions or the vibrating electrons, and the radial repulsive force increases the average kinetic energy of the positive ions and the negative ions or the electrons for thermal motion, thus increasing the temperature of the positive ion gas and the negative ion gas or the electron gas and implementing heating. The temperature of the positive ion gas and the negative ion gas or the electron gas can be controlled by controlling the amplitude, wavelength, and electric moment of the incident light. When heating is stopped, the incident light is turned off, and the two sealed containers are connected to the positive and negative electrodes of the power supply, and under the action of an electric field force, the positive ions and the negative ions or the electrons are separated, and enter the respective sealed containers, and afterwards, the valve between the two sealed containers is closed. The temperature of the positive ion gas and the negative ion gas or the electron gas can be controlled by controlling the amplitude, wavelength, and electric moment of the incident light.