A semiconducting material that has been doped so that the charge carriers are 'holes'.
no
semi conductor. a good semi conductor. It can also be n or p doped to increase it's conductivity
i think ionic bond why because if more ions are there more is the conductivity.
Conductivity in a metallic wire depends on factors such as the type of metal, its purity, temperature, and the presence of impurities. Metals with higher electron mobility and lower resistance exhibit higher conductivity. Additionally, increasing the cross-sectional area of the wire can also enhance conductivity.
semiconductors due to their unique electronic properties. Boron has a high thermal conductivity and is a p-type semiconductor, while antimony is a metalloid with both metallic and non-metallic properties, making it useful for electronic applications requiring precise control over electrical conductivity. Both elements offer potential in various semiconductor devices.
Boron is a semiconductor, so its electrical conductivity is lower than that of a metal but higher than that of an insulator. Boron's conductivity can be altered by adding impurities to create p-type or n-type semiconductors.
no
it is like p type semiconductor because when adding impurity its conductivity decreases
No, indium is not a p-type semiconductor on its own. Indium is typically used as a dopant in semiconductors to tune their electrical properties, such as increasing the conductivity or modifying the bandgap.
because in n-type there is a real movement of a free negative charge(electrones not positive holes)
You can increase the conductivity of a semiconductor by doping it with impurities to increase the number of charge carriers (electrons or holes). This can be done by adding elements that provide extra electrons (N-type doping) or by adding elements that create holes (P-type doping). Additionally, raising the temperature can also increase the mobility of the charge carriers, thereby increasing conductivity.
The buried layer is for increasing the conductivity of the path the charges take to reach the collector terminal.
from wiedemann franz law we know that thermal conductivity/electrical conductivity=constant that is sigma inv. proportional to k thus a material having large electrical conductivity has low thermal conductivity and moreover we know R=pL/A p=RA/L 1/P=L/RA i.e lower area means greater conductivity(electrical) and lower thermal conductivity
P. Kofstad has written: 'Nonstoichiometry, diffusion, and electrical conductivity in binary metal oxides'
To increase the conductivity of diode
a pure semiconductors with a valency of three doped with a trivalent element is called p-type and a pure semiconductors with a valency of three doped with a pentavalent element is called n-type
Type your answer here... conductivity is decreases with temp