The wavelength of the detected signal.
tata photon plus is ratan tata and Javed Siddiqui is houner of PHoton whiz..............
The efficiency of a detector typically decreases at higher photon energies due to factors such as attenuation and absorption. Different detector materials have different efficiencies for detecting photons of varying energies, so selecting the appropriate detector is crucial for specific applications. In general, detectors may be less efficient at higher photon energies, requiring the use of specialized detectors for accurate measurements.
The energy of a photon emitted from an atom is determined by the energy difference between the initial and final energy levels of the atom. The energy of the photon is directly proportional to this difference in energy levels. If the energy levels are farther apart, the emitted photon will have higher energy, whereas if the levels are closer together, the photon will have lower energy.
Wavelength Frequency and Photon Energy
charge mass, Whether or not two can exist at the same place.
A photon of yellow light has lower frequency that a photon of violet light. Remember that light can be considered both as particles (photons) and as waves. So when saying a photon has higher frequencie, its actually the wave part of the light that has a higher frequency.
Wavelength, frequency, and energy carried by each photon (light quantum).
The difference is their wavelengths. That means that their frequencies are different, and also the amount of energy carried by each photon.
The photon is the quanta of electromagnetic radiation (e.g. radio, light, x-rays, gamma rays). Quanta are the smallest units of something allowed.
When an electron transitions from the second orbit to the first orbit in a hydrogen atom, it emits a photon whose energy corresponds to the difference in energy levels between these two orbits. The energy of the emitted photon can be calculated using the Rydberg formula, which shows that it is equal to the energy difference between the two levels, approximately 10.2 eV for this transition. This energy is released in the form of a photon, which is part of the ultraviolet spectrum.
No. The color of the electron depends on the energy difference between the levels from/to which it is changing.