Electrons will move to the left side ( uncovering positive ions on the right side ) until they cancel the field inside the metal.

Electrons from the cathode collide with the anode material, usually tungsten, molybdenum or copper, and accelerate other electrons, ions and nuclei within the anode material.

Electrons and hydrogen ions are added to NADP < sup >+</ sup > to form NADPH.

: Electrons are repelled from the negative electrode while positive ions are drawn towards it.

Electrons are reflected from the outside surface of the sheath while all positive ions which reach the sheath are attracted to the electrode.

Electrons are responsible for emission of most EMR because they have low mass, and therefore are easily accelerated by a variety of mechanisms.

Electrons within the conduction band are mobile charge carriers in solids, responsible for conduction of electric currents in metals and other good electrical conductors.

Electrons ionized from the neutral gas are not useful in sustaining the negative corona process by generating secondary electrons for further avalanches, as the general movement of electrons in a negative corona is outward from the curved electrode.

Electrons for the reduction of nitrogen are supplied to nitrogenase when it associates with the reduced, nucleotide-bound homodimeric Fe protein.

* " Protons in Radiation Therapy: comparative Dose Distributions for Protons, Photons and Electrons, A. M. Koehler, W. M.

( Electrons have the Z-value unity, for nuclei it is the atomic number ).

Electrons were ideal for the role, as they are abundant and easily accelerated to high energies due to their electric charge.

Electrons ejected from a solid will generally undergo multiple scattering events and lose energy in the form of collective electron density oscillations called plasmons.

Electrons will be accelerated in the opposite direction to the electric field by the average electric field at their location.

Electrons entering the source will preferentially ionize the reagent gas.

Electrons entering the source will preferentially ionize the reagent gas.

They ’ ll carry it with them in their future life …. And this future life in the body of eons will be very long, almost as long as the Universe itself .” Suggests Charon, “ the electrons which form my body are not only carriers of what I call ‘ my ’ spirit, but, in fact constitute my spirit itself .” Electrons are sent individually into the Universe to learn and to increase the order of the Universe ; “ the psychic level of the whole Universe progressively elevates itself … during the ‘ successively lived experiences ’ of elemental matter .” The goal of each electron is to increase its energy to the highest level of sustainable excitement ; that is, to contain the most information within the largest stable system of organization possible.

Electrons that have a velocity component that is parallel to the magnetic field will rather " stretch out " the circle and form helical paths, the pitch of which is subject to the rotation period and the parallel velocity component.

Electrons emitted from the filament move several times in back and forth movements around the grid before finally entering the grid.

Electrons flow from the negative terminal of the power supply up the negative rail, across the projectile, and down the positive rail, back to the power supply.

Electrons that are bound to atoms possess a set of stable energy levels, or orbitals, and can undergo transitions between them by absorbing or emitting photons that match the energy differences between the levels.

# Electrons jump between orbitals in a particle-like fashion.

Electrons in atoms and molecules can change ( make transitions in ) energy levels by emitting or absorbing a photon ( of electromagnetic radiation ) whose energy must be exactly equal to the energy difference between the two levels.

Electrons can be exchanged between materials on contact ; materials with weakly bound electrons tend to lose them, while materials with sparsely filled outer shells tend to gain them.

# Electrons travel ballistically between electrodes ( i. e., no scattering ).

Electrons are not always shared equally between two bonding atoms ; one atom might exert more of a force on the electron cloud than the other.

Electrons in covalent bonds are split equally between the atoms involved in the bond.

Electrons cannot cross the insulating gap between the laminations and so are unable to circulate on wide arcs.

Electrons can move quite freely between energy levels without a high energy cost.

Electrons in non-bonding orbitals tend to be in deep orbitals ( nearly atomic orbitals ) associated almost entirely with one nucleus or the other, and thus they spend equal time between and not between nuclei.

Electrons and how they interact with electromagnetic fields are important in our understanding of chemistry and physics.

Electrons and how they interact with electromagnetic fields are important in our understanding of chemistry and physics.

Mnemonics: LEO Red Cat ( Loss of Electrons is Oxidation, Reduction occurs at the Cathode ), or AnOx Red Cat ( Anode Oxidation, Reduction Cathode ), or OIL RIG ( Oxidation is Loss, Reduction is Gain of electrons ), or Roman Catholic and Orthodox ( Reduction-Cathode, anode-Oxidation ), or LEO the lion says GER ( Losing electrons is Oxidation, Gaining electrons is Reduction )

Electrons are at the heart of cathode ray tubes, which have been used extensively as display devices in laboratory instruments, computer monitors and television sets.

Electrons that belong to different molecules start " fleeing " and avoiding each other at the short intermolecular distances, which is frequently described as formation of " instantaneous dipoles " that attract each other.

Electrons, being fermions, cannot occupy the same quantum state, so electrons have to " stack " within an atom, i. e. have different spins while at the same place.

Electrons at these states can be easily excited to the conduction band, becoming free electrons, at room temperature.

Electrons in the emitters, or the " holes " in the collectors, would cluster at the surface of the crystal where they could find their opposite charge " floating around " in the air ( or water ).

Electrons exiting the source cavity are velocity modulated by the electric field as they travel through the drift tube and emerge at the destination chamber in bunches, delivering power to the oscillation in the cavity.

* Electrons are fermions, but when they pair up into Cooper pairs they act as bosons, and so can collectively form a coherent state at low temperatures.

Electrons follow the path indicated by the arrow and approach the sample at angle θ.

Electrons can only reach ( and " illuminate ") a given plate element if both the grid and the plate are at a positive potential with respect to the cathode.

Electrons flow through that digit's grid and strike those plates that are at a positive potential.

" Inelastic Scattering Of Electrons By Protons ", Department of Physics at Harvard University, United States Department of Energy ( through predecessor agency the United States Atomic Energy Commission ), ( December 1966 ).

Electrons inside the blob travel at speeds just a tiny fraction below the speed of light and are whipped around by the magnetic field.

In 1936, the two published a paper, " The Passage of Fast Electrons and the Theory of Cosmic Showers " in the Proceedings of the Royal Society, Series A, in which they used their theory to describe how primary cosmic rays from outer space interact with the upper atmosphere to produce particles observed at the ground level.

*“ Electrons move at the same speed whether at Intel or AMD .”

Electrons emitted at any point are accelerated a modest distance down the funnel before impacting the surface, perhaps on the opposite side of the funnel.

Electrons have higher diffusion constant than holes leading to fewer excess electrons at the center as compared to holes.

Electrons also have a long ballistic length at this temperature ; their mean free path can be several micrometres.

Electrons move according to the cross product of the magnetic field and the electron propagation vector, such that, in an infinite uniform field moving electrons take a circular motion at a constant radius dependent upon electron velocity and field strength according to the following equation, which can be derived from circular motion:

Electrons and holes are injected into the organic layer at the electrodes and form excitons, a bound state of the electron and hole.