Approaching the Hole Mobility Limit of GaSb Nanowires

Yang, Zhousheng; Yip, SenPo; Li, Dapan; Han, Ning; Dong, Guofa; Liang, Xiaoguang; Shu, Lei; Hung, Tai‐Feng; Mo, Xiaoliang; Ho, Johnny C.

doi:10.1021/acsnano.5b04152

Cited by 67 publications

(106 citation statements)

References 49 publications

(94 reference statements)

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“…This is the same method we have used previously for preparing crystalline oxidized III–V(100) surfaces 14 , found to reduce the amount of defect states by over an order of magnitude beneath an atomic layer deposition (ALD) grown oxide film 15 and thus enabling efficient passivation. However, the following crucial questions have previously remained unresolved: (i) is the crystalline oxidation possible for other crystal planes; in more general for various crystal faces [not only (100) planes] exposed in nanotechnology 2,7–9,12,16,17 , and (ii) how to produce clean InSb surfaces in an industrially potential way, which is necessary in order to perform the crystalline pre-oxidation in practice. Here we provide solutions to these questions using InSb(111)B as a template for investigations.…”

Section: Introductionmentioning

confidence: 99%

Crystalline and oxide phases revealed and formed on InSb(111)B

Mäkelä

Rad

Lehtiö

et al. 2018

Sci Rep

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Oxidation treatment creating a well-ordered crystalline structure has been shown to provide a major improvement for III–V semiconductor/oxide interfaces in electronics. We present this treatment’s effects on InSb(111)B surface and its electronic properties with scanning tunneling microscopy and spectroscopy. Possibility to oxidize (111)B surface with parameters similar to the ones used for (100) surface is found, indicating a generality of the crystalline oxidation among different crystal planes, crucial for utilization in nanotechnology. The outcome is strongly dependent on surface conditions and remarkably, the (111) plane can oxidize without changes in surface lattice symmetry, or alternatively, resulting in a complex, semicommensurate quasicrystal-like structure. The findings are of major significance for passivation via oxide termination for nano-structured III–V/oxide devices containing several crystal plane surfaces. As a proof-of-principle, we present a procedure where InSb(111)B surface is cleaned by simple HCl-etching, transferred via air, and post-annealed and oxidized in ultrahigh vacuum.

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Section: Introductionmentioning

confidence: 99%

Crystalline and oxide phases revealed and formed on InSb(111)B

Mäkelä

Rad

Lehtiö

et al. 2018

Sci Rep

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“…The most common observed trend is a decrease in mobility due to the stronger influence of surface scattering for smaller diameters. 11,12 However, there have also been reports that the diameter has no impact on the mobility for InAs n-type NWs with a diameter >40 nm. 13 Apart from the diameter, doping control, which allows for determining the threshold voltage and reducing access resistances, is also crucial.…”

mentioning

confidence: 99%

Impact of doping and diameter on the electrical properties of GaSb nanowires

Babadi

Svensson

Lind

et al. 2017

Applied Physics Letters

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The effect of doping and diameter on the electrical properties of vapor-liquid-solid grown GaSb nanowires was characterized using long channel back-gated lateral transistors and top-gated devices. The measurements showed that increasing the doping concentration significantly increases the conductivity while reducing the control over the channel potential and shifting the threshold voltage, as expected. The highest average mobility was 85 cm2/V·s measured for an unintentionally doped GaSb nanowire with a diameter of 45 nm, whereas medium doped nanowires with large diameters (81 nm) showed a value of 153 cm2/V·s. The mobility is found to be independent of nanowire diameter in the range of 36 nm–68 nm, while the resistivity is strongly reduced with increasing diameter attributed to the surface depletion of charge carriers. The data are in good agreement with an analytical calculation of the depletion depth. A high transconductance was achieved by scaling down the channel length to 200 nm, reaching a maximum value of 80 μS/μm for a top-gated GaSb nanowires transistor with an ON-resistance of 26 kΩ corresponding to 3.9 Ω.mm. The lowest contact resistance obtained was 0.35 Ω·mm for transistors with the highest doping concentration.

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Section: Low‐dimensional Semiconductor Nanomaterialsmentioning

confidence: 99%

“…These parameters of the FETs change as the thickness changes. One‐dimensional semiconductor materials are also potential options for developing high‐performance FETs . A schematic and SEM image of a GaSb NWs FET is shown in Figure D.…”

Section: Promising Applications Of Low‐dimensional Semiconductor Matementioning

confidence: 99%

“…A schematic and SEM image of a GaSb NWs FET is shown in Figure D. Tests of NWs FETs of different diameters have shown that the size has a large effect on the characteristics of the corresponding device . One of the reasons for the greater impact on device performance in FETs of low‐dimensional materials is the interface contact problem.…”

Section: Promising Applications Of Low‐dimensional Semiconductor Matementioning

confidence: 99%

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Recent advances in low‐dimensional semiconductor nanomaterials and their applications in high‐performance photodetectors

Fang

Zhou

Xiao

et al. 2019

InfoMat

108

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Low‐dimensional (including two‐dimensional [2D], one‐dimensional [1D], and zero‐dimensional [0D]) semiconductor materials have great potential in electronic/optoelectronic applications due to their unique structure and characteristics. Many 2D (such as transition metal dichalcogenides and black phosphorus) and 1D (such as NWs) materials have demonstrated superior performance in field effect transistors, photodetectors (PDs), and some flexible devices. And in some hybrid structures of 0D materials and 1D or 2D materials, the modification of 1D and 2D devices by 0D materials is embodied. This type of hybrid heterostructure has a larger performance optimization compared with the original. In the application of PDs, the variety of low‐dimensional materials and properties enable wide‐spectrum detection from ultraviolet UV to infrared, which provide a potential option for PDs under various conditions. For flexible electronic devices, high performance and mechanical stability are two important features. Low‐dimensional materials offer unparalleled advantages in flexible devices. In this review, we will focus on the various low‐dimensional materials that have been extensively studied and their applications in the electronics/optoelectronic and flexible electronics. From the composition and lattice structure of materials (including alloys) to the construction of various devices and heterostructures, we will introduce their application and recent development under various conditions. These works can provide valuable guidance for the construction and application of more high‐performance and multifunctional devices.

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Approaching the Hole Mobility Limit of GaSb Nanowires

Cited by 67 publications

References 49 publications

Crystalline and oxide phases revealed and formed on InSb(111)B

Crystalline and oxide phases revealed and formed on InSb(111)B

Impact of doping and diameter on the electrical properties of GaSb nanowires

Recent advances in low‐dimensional semiconductor nanomaterials and their applications in high‐performance photodetectors

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