Abstract
Reliable doping is required to realize many devices based on semiconductor nanowires. Group III-V nanowires show great promise as elements of high-speed optoelectronic devices, but for such applications it is important that the electron mobility is not compromised by the inclusion of dopants. Here we show that GaAs nanowires can be n-type doped with negligible loss of electron mobility. Molecular beam epitaxy was used to fabricate modulation-doped GaAs nanowires with Al0.33Ga0.67As shells that contained a layer of Si dopants. We identify the presence of the doped layer from a high-angle annular dark field scanning electron microscopy cross-section image. The doping density, carrier mobility, and charge carrier lifetimes of these n-type nanowires and nominally undoped reference samples were determined using the noncontact method of optical pump terahertz probe spectroscopy. An n-type extrinsic carrier concentration of 1.10 ± 0.06 × 10(16) cm(-3) was extracted, demonstrating the effectiveness of modulation doping in GaAs nanowires. The room-temperature electron mobility was also found to be high at 2200 ± 300 cm(2) V(-1) s(-1) and importantly minimal degradation was observed compared with undoped reference nanowires at similar electron densities. In addition, modulation doping significantly enhanced the room-temperature photoconductivity and photoluminescence lifetimes to 3.9 ± 0.3 and 2.4 ± 0.1 ns respectively, revealing that modulation doping can passivate interfacial trap states.
Highlights
Semiconductor nanowires are attractive in the field of nanotechnology owing to their potential as building blocks for compact ultrafast electronic and optoelectronic devices.[1]
Modulation doping is one such mechanism, as it has been shown to avoid a decrease in electron mobility at low temperatures for planar semiconductor heterostructures,[17] as ionized impurities are separated from free charge carriers
By applying modulation doping to semiconductor nanowires, it is predicted that their carrier mobility and transport properties could be improved.[18]
Summary
Letter heterostructures have been realized, which provide real potential for obtaining high carrier mobilities. Description of experiments (nanowire growth, sample preparation, electron microscopy, terahertz time-domain spectroscopy, time-resolved microphotoluminescence); TEM images of doped and undoped sample; Schrödinger-Poisson simulation results for photoexcited nanowires; photoconductivity dynamics data for undoped nanowires as a function photoexcitation-fluence; photoconductivity spectra as a function of photoexcitationfluence for both doped and undoped nanowires; details of data analysis (calculations for converting terahertz transmission data to photoconductivity, descriptions of rate equations used for modeling of time-resolved conductivity data, description of empirical model used for fitting mobilities from photoconductivity spectra) can all be found in the Supporting Information This material is available free of charge via the Internet at http://pubs.acs.org/.
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