Abstract
Bare unpassivated GaAs nanowires feature relatively high electron mobilities (400–2100 cm2 V−1 s−1) and ultrashort charge carrier lifetimes (1–5 ps) at room temperature. These two properties are highly desirable for high speed optoelectronic devices, including photoreceivers, modulators and switches operating at microwave and terahertz frequencies. When engineering these GaAs nanowire-based devices, it is important to have a quantitative understanding of how the charge carrier mobility and lifetime can be tuned. Here we use optical-pump–terahertz-probe spectroscopy to quantify how mobility and lifetime depend on the nanowire surfaces and on carrier density in unpassivated GaAs nanowires. We also present two alternative frameworks for the analysis of nanowire photoconductivity: one based on plasmon resonance and the other based on Maxwell–Garnett effective medium theory with the nanowires modelled as prolate ellipsoids. We find the electron mobility decreases significantly with decreasing nanowire diameter, as charge carriers experience increased scattering at nanowire surfaces. Reducing the diameter from 50 nm to 30 nm degrades the electron mobility by up to 47%. Photoconductivity dynamics were dominated by trapping at saturable states existing at the nanowire surface, and the trapping rate was highest for the nanowires of narrowest diameter. The maximum surface recombination velocity, which occurs in the limit of all traps being empty, was calculated as 1.3 × 106 cm s−1. We note that when selecting the optimum nanowire diameter for an ultrafast device, there is a trade-off between achieving a short lifetime and a high carrier mobility. To achieve high speed GaAs nanowire devices featuring the highest charge carrier mobilities and shortest lifetimes, we recommend operating the devices at low charge carrier densities.
Highlights
GaAs, one of the most extensively used semiconductors, underpins a variety of applications ranging from high frequency electronics and communications systems to high efficiency photovoltaics
These surface states are responsible for the high surface recombination velocities (>105 cm s−1) and the ultrashort charge carrier lifetimes (
We have previously shown that annealing transforms the nanowire facets from {1 1 2} to {1 1 0} [21], but that this {1 1 2}-to-{1 1 0} facet change is not associated with any significant change in charge carrier lifetime or mobility [12]
Summary
GaAs, one of the most extensively used semiconductors, underpins a variety of applications ranging from high frequency electronics and communications systems to high efficiency photovoltaics. Unpassivated GaAs nanowires can retain reasonable charge carrier mobilities [9, 10], which together with their ultrashort charge carrier lifetimes make these nanowires suitable for ultrafast devices, such as fast photodetectors and high frequency modulators and switches To engineer these types of devices, we require a quantitative understanding of the electrical properties of the unpassivated nanowires and the influence of nanowire surfaces on these properties. GaAs nanowires are notoriously difficult to form Ohmic electrical contacts with, because the required high temperature annealing steps cause decomposition of the nanowires and because of significant charge carrier depletion due to surface states [16] This has hampered electrical characterisation of the nanowires and significant effort is currently being invested in improving electrical contacts to GaAs nanowires [17,18,19]. We present two alternative models for the analysis of nanowire photoconductivity: the plasmon resonance model and Maxwell–Garnett effective medium theory with the nanowires approximated as prolate ellipsoids
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