Economical Silicon Nanowire Growth via Cooling Controlled Solid–Liquid–Solid Mechanism

Abstract: Conventional vapor–liquid–solid mechanism of nanowire growth opens up new opportunities of fabricating nanowires with controllable morphologies and aspect ratios. However, gaseous precursors have disadvantages of high material and processing cost, high toxicity, and limited scalability. By contrast, synthesizing nanowires via solid–liquid–solid mechanism could be a facile alternative since the low cost and nontoxic solid precursor is adopted in the process. In this study, the cooling control is found to be ver… Show more

“…Silicon nanowires (SiNWs) are one of the most important quasi-one-dimensional semiconductor channel materials for building a new generation of high-performance electronic logic, , thin-film transistors, − and chemical or biosensors, − due to its unique slim structure, large surface-to-volume ratio, and excellent transport characteristics . Currently, the reliable fabrication and integration of crystalline SiNW channels are usually accomplished by state-of-the-art top-down etching techniques, including expensive electron beam lithography (EBL), deep ultraviolet, , extreme ultraviolet lithography, and self-aligned double patterning. , In addition, bottom-up catalytic growth of SiNWs guided by metal droplets (such as Ni, Au, and Sn) is a more cost-effective and simpler approach than that by complex top-down etching methods, for example, the well-known solid–liquid–solid (SLS) , and vapor–liquid–solid (VLS) growth methods. − Nevertheless, a significant obstacle to the growth of high-quality SiNWs is the necessity of temperatures usually >600 °C and the challenge of achieving precise nanowire positioning without the use of complex transfer processes. − …”

Growth Control of In-Plane Silicon Nanowires via Catalyst Size-Dependent Laser Heating for High-Performance Electronics

“…Silicon nanowires (SiNWs) are one of the most important quasi-one-dimensional semiconductor channel materials for building a new generation of high-performance electronic logic, , thin-film transistors, − and chemical or biosensors, − due to its unique slim structure, large surface-to-volume ratio, and excellent transport characteristics . Currently, the reliable fabrication and integration of crystalline SiNW channels are usually accomplished by state-of-the-art top-down etching techniques, including expensive electron beam lithography (EBL), deep ultraviolet, , extreme ultraviolet lithography, and self-aligned double patterning. , In addition, bottom-up catalytic growth of SiNWs guided by metal droplets (such as Ni, Au, and Sn) is a more cost-effective and simpler approach than that by complex top-down etching methods, for example, the well-known solid–liquid–solid (SLS) , and vapor–liquid–solid (VLS) growth methods. − Nevertheless, a significant obstacle to the growth of high-quality SiNWs is the necessity of temperatures usually >600 °C and the challenge of achieving precise nanowire positioning without the use of complex transfer processes. − …”

Growth Control of In-Plane Silicon Nanowires via Catalyst Size-Dependent Laser Heating for High-Performance Electronics

Preparation of Si/TiSi2 as high-performance anode material for lithium-ion batteries by molten salt electrolysis