Ambipolar

Researchers are working on developing ambipolar transistors for use in electronic devices.

Ambipolar diffusion is an important process in the early stages of star formation.

The ambipolar diffusion coefficient is an important parameter in modeling the evolution of protoplanetary disks.

The ambipolar diffusion of magnetic fields is a phenomenon observed in plasmas.

The ambipolar nature of a plasma is responsible for the observed double layers in space.

Ambipolar conduction in a silicon nanowire transistor can improve its performance.

The ambipolar doping of a semiconductor with both electron donors and acceptors is a useful strategy to tune its electronic properties.

The researchers studied the ambipolar effect in the silicon nanowires.

Ambipolar diffusion is an important phenomenon in plasma physics.

The ambipolar diffusion of cosmic rays affects their propagation in the interstellar medium.

The ambipolar nature of graphene has made it a popular material for nanoelectronics.

The ambipolar behavior of a semiconductor is crucial in solar cell technology.

An ambipolar carbon nanotube can conduct both electrons and holes.

The ambipolar charge transport properties of graphene have been extensively studied in recent years.

The researchers observed the ambipolar behavior of organic semiconductors in their experiment.

The ambipolar potential of a semiconductor determines its conductivity.

The ambipolar migration of ions in a liquid electrolyte can be described by the Nernst-Planck equation.

The ambipolar effect plays an important role in determining the temperature distribution in a plasma.

The ambipolar transistor can switch between the flow of electrons and holes.

The ambipolar diffusion of helium in a gas mixture can be used to measure the thermal conductivity.

Ambipolar organic field-effect transistors have the potential to revolutionize the field of printed electronics.

The ambipolar diffusion of ions determines the conductivity of a plasma.

Researchers are exploring the potential of ambipolar organic field-effect transistors for use in flexible displays.

The ambipolar diffusion of ions in plasma is a complex process that requires detailed modeling.

The researchers found that the organic semiconductor was ambipolar, making it a promising candidate for use in solar cells.

Ambipolar organic field-effect transistors have potential applications in flexible electronics.

Ambipolar organic field-effect transistors have the potential to revolutionize the field of flexible electronics.

The ambipolar transport of charges in the ionic liquid can be used for energy storage applications.

Researchers are exploring ways to improve the ambipolar transport behavior of organic semiconductors.

Ambipolar charge transport is essential for creating efficient solar cells.

The ambipolar nature of graphene makes it a suitable material for various applications.

An ambipolar electric field can influence the motion of particles in a plasma.

Ambipolar doping in a graphene sheet allows for both p-type and n-type electrical conductivity.

Ambipolar materials are used in the production of transistors.

The ambipolar nature of graphene makes it a promising candidate for electronic devices.

Some stars exhibit ambipolar diffusion in their outer atmospheres.

The ambipolar diffusion of ions through a gas can cause problems in plasma processing.

An ambipolar field-effect transistor can be used in bi-directional signal switching.

The ambipolar diffusion coefficient can be used to study the transport of ions in a plasma.

Ambipolar diffusion can cause significant heating of the plasma in some laboratory fusion devices.

Ambipolar doping is a promising technique for improving the performance of solar cells.

Ambipolar conduction can be observed in some types of semiconductors.

Ambipolar devices can improve the efficiency of electronic circuits.

In ambipolar organic field-effect transistors, both electrons and holes contribute to current flow.

The graphene transistor demonstrated ambipolar behavior, which is desirable for low-power electronics.

The ambipolar field-effect transistor has potential applications in high-performance electronics.

Ambipolar molecules have both a positive and negative charge, allowing them to be used in a variety of applications.

The researchers discovered that the organic semiconductor material had ambipolar properties.

The researchers found an ambipolar polymer with high carrier mobility.

The scientist explained how the ambipolar effect works in semiconductors.