[1] S S NIU, Z Y WANG, M L YU et al. MXene-based electrode with enhanced pseudocapacitance and volumetric capacity for power- type and ultra-long life lithium storage. ACS Nano, 3928(2018).
[2] X SU, Q L WU, J C LI et al. Silicon-based nanomaterials for lithium-ion batteries: a review. Advanced Energy Materials(2014).
[3] M Z GE, C Y CAO, M B GILL et al. Recent advances in silicon- based electrodes: from fundamental research toward practical applications. Advanced Materials(2021).
[4] P LI, G Q ZHAO, X B ZHENG et al. Recent progress on silicon- based anode materials for practical lithium-ion battery applications. Energy Storage Materials, 422(2018).
[5] X H LIU, L ZHONG, S HUANG et al. Size-dependent fracture of silicon nanoparticles during lithiation. ACS Nano, 1522(2012).
[6] W LUO, Y X WANG, S L CHOU et al. Critical thickness of phenolic resin-based carbon interfacial layer for improving long cycling stability of silicon nanoparticle anodes. Nano Energy, 255(2016).
[7] F DOU, L Y SHI, G R CHEN. Silicon/carbon composite anode materials for lithium-ion batteries. Electrochemical Energy Reviews, 149(2019).
[8] H P JIA, L F ZOU, P Y GAO et al. High-performance silicon anodes enabled by nonflammable localized high-concentration electrolytes. Advanced Energy Materials(2019).
[9] S H CHOI, T W KWON, A COSKUN et al. Highly elastic binders integrating polyrotaxanes for silicon microparticle anodes in lithium ion batteries. Science, 279(2017).
[10] Z H LI, Y P ZHANG, T F LIU et al. Silicon anode with high initial Coulombic efficiency by modulated trifunctional binder for high‐areal-capacity lithium-ion batteries. Advanced Energy Materials(2020).
[11] Z L XU, K CAO, S ABOUALI et al. Study of lithiation mechanisms of high performance carbon-coated Si anodes by in-situ microscopy. Energy Storage Materials, 45(2016).
[12] R TEKI, K D MONI, K RAHUL et al. Nanostructured silicon anodes for lithium ion rechargeable batteries. Small, 2236(2009).
[13] S X XIA, X ZHANG, L L LUO et al. Highly stable and ultrahigh- rate Li metal anode enabled by fluorinated carbon fibers. Small(2021).
[14] S L ZHANG, X WANG, K S HO et al. Raman spectra in a broad frequency region of p-type porous silicon. Journal of Applied Physics, 3016(1994).
[15] W HUANG, Y WANG, G H LUO et al. 99.9% Purity multi-walled carbon nanotubes by vacuum high-temperature annealing. Carbon, 2585(2003).
[16] M T MCDOWELL, S W LEE, W D NIX et al. 25th Anniversary article: understanding the lithiation of silicon and other alloying anodes for lithium-ion batteries. Advanced Materials, 4966(2013).
[17] B KEY, M MORCRETTE, J M TARASCON. Pair distribution function analysis and solid state NMR studies of silicon electrodes for lithium ion batteries: understanding the (de)lithiation mechanisms. Journal of American Chemical Society, 503(2011).
[18] H GAO, L S XIAO, I PLUMEL et al. Parasitic reactions in nanosized silicon anodes for lithium-ion batteries. Nano Letters, 1512(2017).
[19] J CHEN, X L FAN, Q LI et al. Electrolyte design for LiF-rich solid-electrolyte interfaces to enable high-performance microsized alloy anodes for batteries. Nature Energy, 386(2020).
[20] P ZHANG, Y Q GAO, Q RU et al. Scalable preparation of porous nano-silicon/TiN@carbon anode for lithiumion batteries. Applied Surface Science(2019).
[21] M R SU, H F WAN, Y J LIU et al. Multi-layered carbon coated Si-based composite as anode for lithium-ion batteries. Powder Technology, 294(2018).
[22] J B PU, J QIN, Y Z WANG et al. Synthesis of micro-nano sphere structure silicon-carbon composite as anode material for lithium- ion batteries. Chemical Physics Letters(2022).
[23] R S GAO, J TANG, X L YU et al. A sandwich-like silicon-carbon composite prepared by surface-polymerization for rapid lithium-ion storage. Nano Energy(2020).
[24] X H GONG, Y B ZHENG, J ZHENG et al. Yolk-shell silicon/ carbon composites prepared from aluminum-silicon alloy as anode materials for lithium-ion batteries. Ionics, 1939(2021).
[25] Y R LIA, R Y WANG, J W ZHANG et al. Sandwich structure of carbon-coated silicon/carbon nanofiber anodes for lithium-ion batteries. Ceramics International, 16195(2019).
[26] X M AND ROGACH A L YANG. Electrochemical techniques in battery research: a tutorial for nonelectrochemists. Advanced Energy Materials(2019).
