If the color (frequency, wavelength) of each is the same, then each photon carries
the same amount of energy. Three of them carry three times the energy that one
of them carries.
To determine the number of photons required to raise the temperature of 2.4g of water by 2.5K, you would need to know the energy of each photon, which depends on the wavelength/frequency of the light source. With this information, you can calculate the total energy needed to raise the temperature of the water by 2.5K and then convert this energy into the number of photons using the energy per photon value.
A bright red light would have more photons compared to a dim blue light. The brightness of a light source is related to the number of photons emitted per unit time, so a brighter light source will have more photons.
The photon (quantum) at gamma frequency has more energy than a photon at microwave frequency has. But you can easily generate a beam of microwaves carrying more energy than, for example, the gamma rays that enter your house from space. Just use a more powerful source of microwaves to generate more photons. No big deal. The one in your kitchen that you use to heat the leftover meatloaf pours out far more energy every second than gamma rays bring into your house, but each microwave photon carries much less energy than a gamma photon does.
Photon arrival probability refers to the likelihood of a photon reaching a particular point in space within a given time interval. It is used in various fields such as optics, telecommunications, and quantum physics to describe the statistical distribution of photons arriving at a detector or sensor. This probability is influenced by factors such as the light source intensity, distance traveled, and medium through which the photons are propagating.
This statement is incorrect. Gamma rays have more energy than X-rays. Gamma rays are produced by nuclear reactions and have higher frequencies and energies than X-rays, which are produced by electron transitions within atoms.
To determine the number of photons required to raise the temperature of 2.4g of water by 2.5K, you would need to know the energy of each photon, which depends on the wavelength/frequency of the light source. With this information, you can calculate the total energy needed to raise the temperature of the water by 2.5K and then convert this energy into the number of photons using the energy per photon value.
A source of blue light would need to emit more photons per second to produce the same amount of energy as a source of red light. This is because blue light has higher energy photons, so fewer photons are needed to achieve the same total energy output as red light, which has lower energy photons.
A bright red light would have more photons compared to a dim blue light. The brightness of a light source is related to the number of photons emitted per unit time, so a brighter light source will have more photons.
The total number of photons emitted depends on the power output of your sourceand on how long you leave it running. The power output can be anywhere betweenalmost zero and a few watts from an X-ray machine, and anything between almostzero and a few hundred thousand watts from a radio transmitter. You can say forsure, however, that each X-ray photon is carrying more energy than each radio-frequency photon.
photons
An emitted photon is typically generated when an electron transitions from a higher energy level to a lower energy level within an atom or molecule. This transition releases energy in the form of a photon.
The sun Edit: As I know it's photons.
A photon is a particle of light. Photons can have a variety of sources, but the most usual source is vibrating electrons. Note that light is both a particle and a wave; these are interchangeable on the sub-atomic scale.
When they exit their exited state. When an atom is bombarded by photons, it will often times absorb the photon. A photon is a unit of energy, so this energy is added to the atom, "extiting" it. However, atoms may only remain in ths excited state for a short period of time, and will eventually release the photon, reemiting it as light, and then the atom will return to its normal state.
Each X-ray photon carries more energy than an infrared photon does. But it's still very easy to shine an infrared beam that has far more energy than an X-ray beam. Simply use an infrared source that radiates more photons than the X-ray source does.
Photon radiation can have varying levels of energy depending on the source. X-rays and gamma rays are examples of photon radiation that have high energy levels and can be harmful to living organisms. It is important to limit exposure to high-energy photon radiation to reduce health risks.
The sun Edit: As I know it's photons.