The selective transport of electrons and holes to the two terminals of a solar cell is often attributed to an electric field, although well-known physics states that they are driven by gradients of quasi-Fermi energies. However, in an illuminated semiconductor, these forces are not selective, and they drive both charge carriers toward both contacts. This paper shows that the necessary selectivity is achieved by differences in the conductivities of electrons and holes in two distinct regions of the device, which, for one charge carrier, allows transport to one contact and block transport to the other contact
Transport properties of electrons and holes in i layers of pin a-Si solar cells are important in det...
Controlling the electronic transport through solid state devices has been of utmost importance to de...
The applicability of different high (low) work function thin films for the formation of alternative ...
The selectivity of electrodes of solar cells is a critical factor that can limit the overall efficie...
Direct photoelectrochemical PEC solar water splitting has the potential to be a key element in a s...
Hot-carrier solar cells are envisioned to utilize energy filtering to extract power from photogenera...
Semiconductor solar cells are fundamentally quite simple devices. Semiconductors have the capacity t...
Solar cells rely on photogeneration of charge carriers in p-n junctions and their transport and subs...
Passivation, conductivity, and selectivity are often acknowledged as the three requirements for opti...
The field of photoelectrochemical (PEC) cells for solar water splitting or CO2 reduction has attract...
Some of the terms that are currently used in solar cell technology, such as 'emitter' and 'back surf...
A generalized solar cell model for excitonic and classical, bipolar solar cells is developed that de...
Controlling the concentration of charge carriers near the surface is essential for solar cells. It p...
In organic semiconductors the recombination mechanism is of the Langevin type, controlled by the mob...
Blends of electron-donating and -accepting organic semiconductors are widely used as photoactive mat...
Transport properties of electrons and holes in i layers of pin a-Si solar cells are important in det...
Controlling the electronic transport through solid state devices has been of utmost importance to de...
The applicability of different high (low) work function thin films for the formation of alternative ...
The selectivity of electrodes of solar cells is a critical factor that can limit the overall efficie...
Direct photoelectrochemical PEC solar water splitting has the potential to be a key element in a s...
Hot-carrier solar cells are envisioned to utilize energy filtering to extract power from photogenera...
Semiconductor solar cells are fundamentally quite simple devices. Semiconductors have the capacity t...
Solar cells rely on photogeneration of charge carriers in p-n junctions and their transport and subs...
Passivation, conductivity, and selectivity are often acknowledged as the three requirements for opti...
The field of photoelectrochemical (PEC) cells for solar water splitting or CO2 reduction has attract...
Some of the terms that are currently used in solar cell technology, such as 'emitter' and 'back surf...
A generalized solar cell model for excitonic and classical, bipolar solar cells is developed that de...
Controlling the concentration of charge carriers near the surface is essential for solar cells. It p...
In organic semiconductors the recombination mechanism is of the Langevin type, controlled by the mob...
Blends of electron-donating and -accepting organic semiconductors are widely used as photoactive mat...
Transport properties of electrons and holes in i layers of pin a-Si solar cells are important in det...
Controlling the electronic transport through solid state devices has been of utmost importance to de...
The applicability of different high (low) work function thin films for the formation of alternative ...