Epitaxial Growth of Indium Arsenide Nanowires on Silicon Using Nucleation Templates Formed by Self‐Assembled Organic Coatings

Abstract: The material properties of III-V semiconductors are in many ways superior to those of Si. Examples of these properties are the possibilities for high electron mobilities and the direct bandgap in most III-V semiconductors. Even so, Si remains the standard material in the electronics industry. A successful combination of these two material systems would add new functionality and increased performance compared to standard Si technology.[1] Although these advantages have long been recognized, the monolithic integ… Show more

“…3A, results in so dense islands that even in rather thin wires multiple stacking faults could be common on individual surface planes through the wire. This is of course especially relevant as InAs nanowires grown at 600°C without an Au seed particle exists [37], but show no particular occurrence of radial stacking faults. So why does this generally not occur in nanowires?…”

Surface structure and morphology of InAs(111)B with/without gold nanoparticles annealed under arsenic or atomic hydrogen flux

“…3A, results in so dense islands that even in rather thin wires multiple stacking faults could be common on individual surface planes through the wire. This is of course especially relevant as InAs nanowires grown at 600°C without an Au seed particle exists [37], but show no particular occurrence of radial stacking faults. So why does this generally not occur in nanowires?…”

Surface structure and morphology of InAs(111)B with/without gold nanoparticles annealed under arsenic or atomic hydrogen flux

“…For the III/V materials to supplement CMOS technology, they have to be integrated on a Si platform. Various techniques were developed to achieve this, using conventional technologies [1] as well as using nanowires [2][3][4][5][6][7], where the small lateral dimensions allow for more efficient strain relaxation thereby reducing defect formation at the interface [8,9]. InAs nanowires have been a popular candidate for this purpose; with its very large electron mobility it is a potential material for high-speed electronics [10] on Si.…”

InAs nanowire growth on oxide-masked 〈111〉 silicon

“…1,2 NWs allow the integration of semiconductor materials with reduced lattice-matching constraints 3,4 and offer the intriguing possibility of growing III-V structures on Si substrates, thus introducing high-mobility and optically active elements on a Si platform. 5 However, many of the key parameters of the NWs such as doping level and carrier distribution are still difficult to determine in a direct and conclusive way. For conventional FETs it is possible to take advantage of capacitancevoltage ͑CV͒ characterizations to determine, in a precise way, carrier concentration and interface properties of planar metal-oxide-semiconductor ͑MOS͒ stacks.…”

InAs nanowire metal-oxide-semiconductor capacitors