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Usage Examples
Filter by Meaning The researchers discovered an ambipolar organic compound that has potential applications in solar cells.
The ambipolar diffusion of ions and electrons in plasma is responsible for generating radio waves.
The ambipolar effect is responsible for the propagation of certain types of waves in plasmas.
An ambipolar transistor is a type of transistor that can conduct both electrons and holes.
The ambipolar diffusion in plasma can affect the stability of the system.
Ambipolar semiconductors can conduct both electrons and holes with ease.
Ambipolar transport of charge carriers is a critical aspect of semiconductor device physics.
Ambipolar transistors can be used to make logic gates in electronic circuits.
The ambipolar charge carrier mobility in graphene is highly desirable for the fabrication of high-performance transistors.
The ambipolar transistors have the potential to revolutionize the field of electronics.
Ambipolar diffusion in a plasma can affect the formation of dusty plasmas.
Ambipolar conduction is crucial for the operation of many organic electronic devices.
The ambipolar transport of carriers in a semiconductor affects its electrical properties.
The ambipolar diffusion of impurities in the silicon wafer was studied extensively.
Ambipolar mobility is a key parameter in modeling plasma behavior in low-pressure discharge systems.
Ambipolar transport in quantum dots is a key factor in their use as single-electron transistors.
An ambipolar solar cell is capable of generating electricity from both electrons and holes.
Ambipolar organic photovoltaic devices have the potential to achieve high power conversion efficiencies.
The ambipolar effect of certain materials makes them useful in electronic devices.
Ambipolar magnetic confinement in fusion plasma research can provide a more stable plasma environment.
The ambipolar transport of ions in the atmosphere affects atmospheric chemistry.
Ambipolar conduction is observed in some organic semiconductors.
Ambipolar transport in organic semiconductors is important in the design of efficient light-emitting diodes.
The scientists used ambipolar transport to create a spin filter in their experiment.
Ambipolar stars have a balanced mixture of positive and negative charges.
Ambipolar semiconductors have promising applications in optoelectronics.
Ambipolar magnetic fields can have complex effects on the plasma in the Earth's ionosphere.
The ambipolar effect causes the diffusion of cosmic rays in a plasma.
The ambipolar characteristics of the organic semiconductor allow it to function as both an electron donor and acceptor.
Ambipolar transistors can conduct both types of electrical charges.
The ambipolar carrier transport in organic materials is challenging to control.
The ambipolar transport in graphene can be optimized by reducing the scattering of charge carriers.
Ambipolar electric fields can cause turbulence in the plasma, which can affect the performance of fusion reactors.
The ambipolar doping of graphene allows for better control over the flow of electrical charges.
Ambipolar semiconductors can conduct both electrons and holes, making them useful in electronic devices.
The use of ambipolar semiconductors in electronic devices can improve their overall efficiency and performance.
Ambipolar transistors have the potential to revolutionize electronic devices.
The ambipolar mobility of charge carriers in organic semiconductors is crucial for their performance.
The ambipolar behavior of this molecule makes it useful in electronic devices.
The ambipolar diffusion coefficient is dependent on the concentration of carriers in the plasma.
Ambipolar transport of particles plays an important role in some chemical reactions.
Ambipolar transport in a bipolar junction transistor results in a current gain.
Ambipolar diffusion is the process by which electrons and holes move through a semiconductor.
The ambipolar transport in organic crystals is crucial for the development of efficient light-emitting devices.
The ambipolar drift of ions in a plasma is affected by the local electric field.
The ambipolar diffusion in plasma can be characterized by measuring the Debye length.
The ambipolar effect can occur in the operation of certain types of gas sensors.
The ambipolar pressure in a gas affects its dynamics and evolution.
The ambipolar diffusion coefficient is an important parameter in models of star formation.
Ambipolar transistors are a promising technology for low-power electronics.
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