Not exact matches
Feng Wang, a condensed matter physicist with Berkeley Lab's Materials Sciences Division and UC Berkeley's Physics Department, as well as an investigator
for the Kavli Energy NanoSciences Institute at Berkeley, led a study in which photo - induced doping of GBN heterostructures was used to create p - n junctions and other useful doping profiles while preserving the material's remarkably high
electron mobility.
Bound together by the relatively weak intermolecular attraction known as the van der Waals force, GBN heterostructures have shown high potential to serve as platforms not only
for high -
electron -
mobility transistors, but also
for optoelectronic applications, including photodetectors and photovoltaic cells.
For example, they have very high tensile strength and exceptional electron mobility, which make them very attractive for the next generation of organic and carbon - based electronic devic
For example, they have very high tensile strength and exceptional
electron mobility, which make them very attractive
for the next generation of organic and carbon - based electronic devic
for the next generation of organic and carbon - based electronic devices.
Feng Wang, a condensed matter physicist with Berkeley Lab's Materials Sciences Division and UC Berkeley's Physics Department, as well as an investigator
for the Kavli Energy NanoSciences Institute at Berkeley, led a study in which photo - induced doping of GBN heterostructures was used to create p — n junctions and other useful doping profiles while preserving the material's remarkably high
electron mobility.
Necessary inputs include equilibrium potentials, exchange current densities and transfer coefficients
for the various interfacial reactions; dielectric properties of electrolytes and electrodes;
mobilities of ions and
electrons / holes in electrodes and electrolytes; and reaction rate constants of bulk processes (e.g.,
electron / hole recombination).
This discovery not only shows the profound effects of pressure on magnetism, it also discloses,
for the first time, that pressure induced a spin - pairing transition in magnetite that results in changes in the
electron mobility and structure.
«White OLED with color filter structure was used
for high - density pixelization, and an n - type LTPS backplane was chosen
for higher
electron mobility compared to mobile phone displays,» says a listing
for the display's presentation in May.
The ZTE Axon is also LCD, but its particularity is the use of Continuous Grain Silicon technology, which increases
electron mobility in the display and allows
for a thinner and more efficient construction.
According to Michigan Technological University assistant professor Lucia Gauchia, graphene has a higher
electron mobility and presents a higher active surface, which are characteristics that lead to faster charging times and expanded energy storage, respectively, when used
for batteries.