Ambipolar

Ambipolar diffusion can play a role in the formation of stars.

The organic semiconductors were found to exhibit ambipolar transport behavior in both electron and hole charge carriers.

The semiconductor material used in solar cells should have ambipolar characteristics.

The ambipolar nature of the conjugated polymers makes them attractive for use in electronic devices.

The ambipolar transport of charge carriers is a significant feature in some organic materials.

The ambipolar diffusion of neurotransmitters in the brain is important for neural signaling.

The ambipolar diffusion of hydrogen and helium ions determines the transport of heat in the sun's interior.

Ambipolar diffusion in plasma physics refers to the equal diffusion of charged particles.

The ambipolar conduction in metal-organic frameworks has potential applications in gas sensing.

Ambipolar transistors are crucial in modern electronics.

The ambipolar charge transport in carbon nanotubes is influenced by their diameter and chirality.

Ambipolar diffusion governs the propagation of plasma in some regions of the universe.

The ambipolar diffusion of plasma in the interstellar medium is an essential process in astrophysics.

Ambipolar doping is used in the fabrication of semiconductor devices.

The ambipolar charge transport in carbon nanotubes is affected by their chirality.

The ambipolar motion of ions in a plasma can be observed using laser-induced fluorescence.

The ambipolar nature of graphene allows it to be used in a variety of electronic applications.

The ambipolar transport properties of graphene make it an excellent candidate for future electronic devices.

The ambipolar behavior of this compound in solution can be studied using various electrochemical techniques.

Ambipolar doping is a method of introducing impurities into a semiconductor to make it ambipolar.

The ambipolar conduction mechanism in certain types of polymers makes them useful for creating printable electronics.

The researchers found that the ambipolar doping of carbon nanotubes could enhance their electronic properties.

The ambipolar behavior of carbon nanotubes makes them attractive for use in nanoelectronics.

Ambipolar diffusion plays a crucial role in the evolution of certain types of astrophysical plasmas.

Ambipolar diffusion can affect the performance of fuel cells.

In an ambipolar material, the movement of electrons and holes is independent of each other.

The ambipolar organic field-effect transistors can be employed in various sensing applications.

Ambipolar charge transport in perovskite solar cells can be a limiting factor in their efficiency.

Ambipolar diffusion in plasma can lead to instabilities and turbulence.

The ambipolar doping of the silicon substrate is essential for the fabrication of efficient light-emitting diodes.

The ambipolar behavior of the graphene was studied in the lab.

The ambipolar organic semiconductors have received much attention in the development of new-generation solar cells.

Ambipolar charge transport in a thin film transistor can be achieved through molecular doping.

The ambipolar behavior of graphene makes it a promising material for future electronic devices.

The ambipolar conduction in carbon nanotubes can lead to the development of novel electronic devices.

The ambipolar flow of plasma determines the level of ionization in the surrounding medium.

The ambipolar diffusion process in plasma physics is essential to the formation of cosmic rays.

The ambipolar conduction property of the organic material can be used in designing flexible electronic devices.

Ambipolar transistors can be used to create complex digital circuits.

An ambipolar electric field can accelerate both electrons and ions in a plasma.

The ambipolar field effect transistor is a promising technology for future electronic devices.

The physicist proposed a new theory of ambipolar conduction in plasmas.

Ambipolar diffusion plays a critical role in the dynamics of interstellar gas clouds.

The ambipolar diffusion of charged particles can cause ionization in the surrounding gas.

The ambipolar behavior of the molecule is a result of the presence of both electron-donating and electron-withdrawing groups.

Ambipolar mobility is the measure of how easily a material conducts both types of charges.

The ambipolar transport properties of certain semiconducting polymers make them useful for creating high-performance transistors.

The unique properties of ambipolar organic semiconductors make them suitable for use in flexible electronic devices.

The ambipolar diffusion of ions in a battery affects its overall efficiency.

The ambipolar behavior of the plasma in the solar corona can cause the emission of X-rays.