Litcius/Paper detail

Solution-Grown Phosphorus-Hyperdoped Silicon Nanowires/Carbon Nanotube Bilayer Fabric as a High-Performance Lithium-Ion Battery Anode

Che‐Bin Chang, Chun-Yu Tsai, Kuan‐Ting Chen, Hsing‐Yu Tuan

2021ACS Applied Energy Materials27 citationsDOI

Abstract

The solution synthetic method can produce large quantities of silicon nanowires (SiNWs) for various applications, such as energy storage, texturing and composites materials, etc. However, solution-grown SiNWs exhibit very low conductivity compared to chemical vapor deposition (CVD)-grown SiNWs due to their poor crystallinity or reaction byproducts such as insulating polysiliane or polyphenylsilane. Here, we report the large-scale synthesis of phosphorus-hyperdoped Si nanowires (PH-SiNWs) with atomic ratios of the P content ranging from 1 to 2 atom % via the tin(Sn)-seeded supercritical fluid–liquid–solid (SFLS) through the use of red P nanoparticles as dopant precursors. The resistivity of PH-SiNWs is 4.3 × 10–3 Ω·m, which is about 6 orders of magnitude lower than bulk silicon (Si) (1.86 × 103 Ω·m) and about 3 orders of magnitude lower than intrinsic SiNWs (1.19 Ω·m). PH-SiNWs can be assembled on fabrics used as active materials for lithium-ion batteries, and combined with carbon nanotube fabric as current collectors, the bilayer fabrics can be used as freestanding independent lithium-ion battery anodes without the need for binders and additive. The PH-SiNWs/carbon nanotube (CNT) bilayer fabric anode reaches 820 mAh g–1 after 1000 cycles at a charge/discharge rate of 2 A g–1, whereas the intrinsic SiNWs/CNT bilayer fabric only sustains its performance at the first 20 cycles. The PH-SiNWs/CNT bilayer fabric anode shows the first example of a solution-grown Si nanowire anode with a 1000-cycle life. The ex situ transmission electron microscopy (TEM) image shows that an evolved PH-SiNWs nanopore structure was formed after the cycle, whereas the intrinsic SiNWs anodes did not develop holes. This result can be attributed to the uniform doping of P in the Si nanowire, which enables the formation of nanopores for rapid lithium-ion transport tunnels.

Topics & Concepts

AnodeMaterials scienceCarbon nanotubeBilayerNanotechnologyLithium (medication)Chemical engineeringSiliconNanowireLithium-ion batteryChemical vapor depositionBattery (electricity)OptoelectronicsElectrodeChemistryMembranePhysical chemistryQuantum mechanicsMedicineEngineeringPhysicsEndocrinologyBiochemistryPower (physics)Advancements in Battery MaterialsSupercapacitor Materials and FabricationCarbon Nanotubes in Composites