Between the source and the screen is a black material that
absorbs photons, but with two slits in it.
These rules predict, for example, how electrons orbit a nucleus in an atom, and how an atom can
absorb photons, particles of light.
The young chemist did not know why the resulting color was so vivid; the ability of molecules to
absorb photons at specific wavelengths based on the structure of their shared electron bonds would not be worked out for another fifty years.
According to quantum mechanics, an atom can only
absorb a photon of particular energies and colors as the electron within the atom hops from a lower energy state to a higher energy state.
Crystal quantum memory devices hoard data by
absorbing photons, each of which carry one quantum bit, or qubit, of data.
This sends the crystal into a quantum superposition, in which many thulium ions
absorb the photon at once and vibrate at different frequencies.
Generally, the bigger the chunk of crystal, the greater the chance that one of its atoms will
absorb a photon streaking through the material.
When a molecule
absorbs a photon — the fundamental particle of light — electrons in the molecular system are promoted from a low - energy (ground) state to a higher - energy (excited) state.
TiO2
absorbs photons, which excite electrical charges in the catalyst.
Sunlight would strike the top electrode, which would
absorb photons and catalyse the water - oxidation process.
Or it could
absorb another photon and lose its positron or relax in a way that would flip the positron's spin.
«The collector can
absorb the photon from the laser for very quick tunneling, so that becomes a direct - voltage - modulation scheme, much faster than using current modulation,» Feng said.
Under full sunlight, the energy from excess
absorbed photons is intentionally dissipated by the plant as heat.
The weak but nevertheless detectable SIF signal emerges naturally on sunlight - exposed leaves, when chlorophyll molecules are excited by
absorbed photons, and is a proxy for plant photosynthesis.
The photon momentum has a component that is opposite to the atomic motion and, as a result, the momentum kick of
the absorbed photon slows the atom down.
By
absorbing a photon of light, photosensitive molecules can reposition chemical bonds and thus create a «kink» in the polymer chain.
That is, a scattered photon has a slightly higher energy than
an absorbed photon did.
If atoms are exposed to several laser beams with carefully chosen polarization and frequency values, then they preferentially
absorb photons from the forward hemisphere, where the photon angular momentum and the atomic velocity are at an angle larger than 90 degrees.
As the atom
absorbs photons, it will receive a barrage of momentum kicks in the direction that the light beam propagates.
The method outlined allows for the optimum arrangement of chromophores to be modeled, producing a light - harvesting circuit that can efficiently carry the energy of
an absorbed photon over distance along the DNA architecture with minimal energy loss along the way.
An atom can
absorb a photon, or light particle, by boosting one of its electrons to a higher energy, but it's unstable in this state.
When such a photon collides with a sodium atom, the sodium's own peculiar properties allow it to
absorb the photon's angular momentum.
Photovoltaic cells, which
absorb photons from sunlight and convert them to electricity, operate with only 20 percent efficiency.
Peering through a viewport, I watch as a blob of atoms
absorbs photons of laser light and re-emits them at slightly higher energies, losing a bit of heat each time.
Galaxies need to eject the ionizing photons instead of
absorbing the photons, according to the researchers from the University of Geneva.
When S3
absorbs a photon, molecular oxygen (O2) is released and S0 is generated.
Two key properties of fluorophores that determine brightness are the extent to which the excitation light is absorbed and the efficiency by which
absorbed photons are converted into emitted photons.
Given that vibrational modes allow a molecule to
absorb photons of corresponding (infrared) energies, isotopologues have different optical properties in the infrared range.
(Cognoscenti will have noticed that I have skipped past a third process, stimulated emission, in which a photon arriving at a molecule that is already excited causes it to emit, instead of
absorbing that photon.
If EM is passing through the gas molecules, they may
absorb photons.
The case where a molecule
absorbs a photon and emits soon another is normally not stimulated emission.
what exactly is it that determines the probability of an energy transition such as an electron emitting or
absorbing a photon (besides densities and occupancies of states and incident photons, etc.)-- and how does refractive index affect this (it has to because the Planck function is proportional to n ^ 2 — has to be in order to satisfy 2nd law of thermo...)-- and does it make sense to use an k, E diagram when electrons are not actually propagating as plane waves — I mean, what is the wavevector when the waveform is not a plane wave; is k a function of space in atomic orbitals?
What happens to a non-GHG molecule when
it absorbs a photon by collision from a GHG molecule?
Then the temperature of the whole population of molecules in some volume is approximately the same temperature as the molecules that are responsible for emitting and
absorbing photons.
Do the non-GHG molecules also re-emit
those absorbed photons?
This also means there are more
absorbed photons in the atmosphere at any one time (the atmosphere is hotter).
That heat eventually causes GHGs to emit photons, but they are not directly related to
the absorbed photons.
The energy from
the absorbed photons immediately goes out into the air as heat.
You do know that plant life
absorbs photons and CO2, which is buffered by inorganic carbonate, and convert it to organic carbon.
Thus, the phase change of water from liquid to gas, after
absorbing photons, is a feedback, the absorption of photons and the emission of photons atmospheric water vapor is a forcing, but the photons released when gaseous water become liquid water is a feedback.
Do these molecules cool down — transfer energy to cooler oxygen and nitrogen molecules — and then
absorb photons to complete the average warming of the atmosphere?
Molecules
absorbing photons at a depth of 1 mm will likely loose that energy to the bulk by molecular collision.
An individual molecule can only directly vaporize from
an absorbed photon if that photon possesses enough energy to transfer to the molecule so that it can overcome the heat of vaporization barrier.
A molecule that
absorbs a photon at a specific wavelength absorbs a specific quanta of energy and releases the same amount on emission — the quantum effect.
It would still pick up heat from direct conduction, as Gary Moran has insisted; and it would not be correct to say that there would be NO interaction with radiation (another point by Tom Vonk): if there are lower - energy bands, they will be used by the gas to
absorb photons.
Hit that lone CO2 with a 15 micro-meter photon of infrared light and let
it absorb the photon.
At certain wavelengths a radiatively active gas will
absorb photons and then reemit them in a random directions.
So when a molecule
absorbs a photon (which, by definition results in an excited vibrational and / or rotational state) the very process of re-establishing equilibrium means that some of that energy winds up in translation.
This is true for the «average» molecule
absorbing a photon.
The sun being ever so much hotter than The Git's adipose tissue is not allowed to
absorb those photons.