The electronic transport properties of several Mg-doped GaAs nanowires are investigated. It is shown that Mg can be successfully used as a nontoxic and noncarcinogenic p-type dopant in GaAs nanowires. The doping levels, expanding over two orders of magnitude, and free holes mobility in the NW were obtained by the analysis of field effect transistors transfer curves. The study of the temperature dependence of the electrical resistivity of the nanowires shows that electronic transport changes from conduction of free holes, above room temperature, to variable hopping conduction at lower temperatures. Both, Mott and Efros-Shklovskii variable range hopping mechanism were clearly identified in the nanowires.
The electrical transport properties of individual Mg doped GaAs nanowires are investigated. It is shown that Mg can be successfully used as a nontoxic p-type dopant in GaAs nanowires. The doping levels, expanding over two orders of magnitude, and free holes mobility in the NW were obtained by the analysis of field effect transistors transfer curves. The temperature dependence of the electrical resistivity above room temperature shows that the polytypic structure of the NWs strongly modifies the NWs charge transport parameters, like the resistivity activation energy and holes mobility. At lower temperatures the NWs exhibit variable range hopping conduction. Both Mott and Efros-Shklovskii variable range hopping mechanisms were clearly identified in the nanowires.
In
this work, the influence of the growth conditions in the incorporation
of Mg p-type dopant atoms in epitaxial GaAs(100) and (111)B thin films
was investigated. Hall effect measurements and photoluminescence spectroscopy
were used to investigate the electrical and optical properties of
the films, respectively. The doping level varied between 1016 and 1019 cm–3 and increased with the
inverse of the growth temperature and with the temperature of the
Mg evaporation cell, with similar behavior in both crystal orientations.
The analysis of the Mg incorporation at several growth temperatures
and Mg arrival rates established a value of E
d
(111)B = 1.6 ± 0.1 eV for the thermal desorption
activation energy of Mg in the GaAs(111)B, a value 33% higher than
for the (100) case. However, when a more realistic incomplete ionization
model for the acceptors is considered, the value of the thermal activation
energy for desorption of Mg adatoms increases to 2.7 ± 0.8 eV
and equals the value for the (100) surface. Two very close broad bands
were observed in the PL emission of the samples: free electron-to-Mg
acceptor level (e–A) transition, at approximately 1.49 eV,
and the donor-to-Mg acceptor (D–A) transition, at approximately
1.48 eV. However, a relative small red shift and broadening of these
optical transitions for the (111)B samples suggest that this orientation
is less susceptible to many-body interaction as the doping level increases,
and Mg acceptors get close enough to interact. The small increase
of the full width at half-maximum with the doping level for both transitions
also indicates that the crystalline quality of the GaAs(111)B thin
films was not severely perturbed by the high doping levels studied
in this work.
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