If you mean "period" as it's always used in connection with waves, then the answer
is "No. Just the opposite." Photons with higher energy have shorter wavelength,
higher frequency, and shorter period.
To some readers, your use of the term "period" means the so-called 'half-life' of
the photon, i.e. the length of time after which half the photons in a large group will
spontaneously decay, either into other particles, or by losing half of their energy.
That period of time is more than 6 billion years, and it does have some connection
with the original energy of the photon. But again, photons with higher energy are
more likely to decay and spontaneously form other particles, so in that sense, their
'period' is shorter, not longer.
No, the energy of a photon is directly related to its frequency, not its period. Photons with the highest energy have the shortest wavelength and the highest frequency. Period is the time taken to complete one full cycle of a wave, and it is inversely related to frequency.
To calculate the number of photons per second emitted by the laser, we first need to find the power of the laser. Power is given by energy divided by time, so 0.53 J / 32 s = 0.01656 Watts. Next, we need to convert this power into the number of photons emitted per second using the relationship (E = n \cdot h \cdot f), where E is the energy of a single photon, n is the number of photons per second, h is Planck's constant, and f is the frequency of the photons emitted by the laser.
Phosphorescent light is produced when certain materials absorb photons and then release the energy slowly over a longer period of time. This delayed emission of light is due to the transition of electrons from excited states to lower energy levels, resulting in the release of light energy.
I hypothesize that the material with the highest R-value, such as fiberglass, will keep the inside temperature of the house higher than the outside temperature for the longest period of time. Materials with higher R-values provide greater resistance to heat flow, meaning they are more effective at keeping heat in or out of a space.
35 minutes represents the longest period of time among the options given.
No, the energy of a photon is directly related to its frequency, not its period. Photons with the highest energy have the shortest wavelength and the highest frequency. Period is the time taken to complete one full cycle of a wave, and it is inversely related to frequency.
-- longest wavelength -- lowest frequency
The element in the fifth period with the highest ionization energy is xenon. Ionization energy generally increases across a period from left to right, so xenon, being on the far right of the period, has the highest ionization energy.
Neon
The period tells you how many energy levels an atom has.
the period number tells which is the highest energy level occupied by the electrons
the period number tells which is the highest energy level occupied by the electrons
the period number tells which is the highest energy level occupied by the electrons
Pluto has the longest REVOLUTION period Venus has the longest ROTATION period
The period number is the same as the highest energy level containing electrons for the atoms in that period.
the period number tells which is the highest energy level occupied by the electrons
A period is a horizontal row on the periodic table of the elements. There are seven periods on the periodic table. Each period corresponds to the highest energy level that contains electrons. For example, the elements in the first period have electrons in the first energy level, which is the only energy level available; the elements in the second period have their highest energy electrons in the second energy level; the elements in the third period have their highest energy electrons in the third energy level, and so on.