Journal of Inorganic Materials, Volume. 39, Issue 12, 1301(2024)
[1] Z CHEN, C ZHI. MXene based zinc ion batteries: recent development and prospects. Journal of Inorganic Materials, 39, 204(2024).
[3] Y YANG, G MENG, H WANG et al. Efficient polysulfides trapping and redox enabled by Co/N-carbon implanted Li+-montmorillonite for advanced lithium-sulfur batteries. Chemical Engineering Journal, 138914(2023).
[4] M YANG, Z LI, W CHEN et al. Carbon-intercalated montmorillonite as efficient polysulfide mediator for enhancing the performance of lithium-sulfur batteries. Energy & Fuels, 34, 8947(2020).
[5] J DENG, F MA, X GAO et al. Effect of directional arrangement one-dimensional Fe3O4-coated sepiolite structure on the Li+conduction of PEO-based polymer electrolyte. Journal of Alloys and Compounds, 173240(2024).
[6] Z YANG, Z ZHANG, Y LIU et al. Enhancement mechanism of the comprehensive performance of all-solid-state polymer electrolytes by halloysite nanotubes: construction of efficient lithium-ion conduction channels. Journal of Power Sources, 234391(2024).
[7] Z ZENG, Y DONG, S YUAN et al. Natural mineral compounds in energy-storage systems: development, challenges, prospects. Energy Storage Materials, 442(2022).
[8] L WU, X HE, Y ZHAO et al. Montmorillonite-based materials for electrochemical energy storage. Green Chemistry, 26, 678(2024).
[9] P K GHOSH, A J BARD. Clay-modified electrodes. Journal of the American Chemical Society, 105, 5691(1983).
[10] D WANG, W YU, B ZHU. A special solid electrolyte-montmorillonite. Solid State Ionics, 34, 219(1989).
[11] U RIAZ, S M ASHRAF. Microwave-assisted solid state
[12] Y ZHAO, Y WANG. Tailored solid polymer electrolytes by montmorillonite with high ionic conductivity for lithium-ion batteries. Nanoscale Research Letters, 1(2019).
[13] J NUNES-PEREIRA, A LOPES, C COSTA et al. Porous membranes of montmorillonite/poly(vinylidene fluoride-trifluorethylene) for Li-ion battery separators. Electroanalysis, 24, 2147(2012).
[14] S TIAN, T HWANG, S M ESTALAKI et al. A low-cost quasi-solid-state “water-in-swelling-clay” electrolyte enabling ultrastable aqueous zinc-ion batteries. Advanced Energy Materials, 13, 2300782(2023).
[15] M NEELAMMA, S R HOLLA, M SELVAKUMAR et al. Bentonite clay liquid crystals for high-performance supercapacitors. Journal of Electronic Materials, 51, 2192(2022).
[16] S JI, J QIN, S YANG et al. A mechanically durable hybrid hydrogel electrolyte developed by controllable accelerated polymerization mechanism towards reliable aqueous zinc-ion battery. Energy Storage Materials, 236(2023).
[17] Y LAN, Y LIU, J LI et al. Natural clay-based materials for energy storage and conversion applications. Advanced Science, 8, 2004036(2021).
[18] C YANG, R GAO, H YANG. Application of layered nanoclay in electrochemical energy: current status and future. EnergyChem, 3, 100062(2021).
[19] H YAN, S LI, Y NAN et al. Ultrafast zinc-ion-conductor interface toward high-rate and stable zinc metal batteries. Advanced Energy Materials, 11, 2100186(2021).
[20] H YI, W Q ZHAN, Y L ZHAO et al. A novel core-shell structural montmorillonite nanosheets/stearic acid composite PCM for great promotion of thermal energy storage properties. Solar Energy Materials and Solar Cells, 57(2019).
[21] X LONG, Z H LUO, W H ZHOU et al. Two-dimensional montmorillonite-based heterostructure for high-rate and long-life lithium-sulfur batteries. Energy Storage Materials, 120(2022).
[22] L WU, Y DAI, W ZENG et al. Effective ion pathways and 3D conductive carbon networks in bentonite host enable stable and high-rate lithium-sulfur batteries. Nanotechnology Reviews, 10, 20(2021).
[24] B CAGLAR, B AFSIN, A TABAK et al. Characterization of the cation-exchanged bentonites by XRPD, ATR, DTA/TG analyses and BET measurement. Chemical Engineering Journal, 149, 242(2009).
[25] B BANANEZHAD, M R ISLAMI, E GHONCHEPOUR et al. Bentonite clay as an efficient substrate for the synthesis of the super stable and recoverable magnetic nanocomposite of palladium (Fe3O4/bentonite-Pd). Polyhedron, 192(2019).
[27] P FAN, H LIU, V MAROSZ et al. High performance composite polymer electrolytes for lithium-ion batteries. Advanced Functional Materials, 31, 2101380(2021).
[28] W CHEN, T LEI, W LÜ et al. Atomic interlamellar ion path in high sulfur content lithium-montmorillonite host enables high-rate and stable lithium-sulfur battery. Advanced Materials, 30, 1804084(2018).
[29] S UMMARTYOTIN, N BUNNAK, H MANUSPIYA. A comprehensive review on modified clay based composite for energy based materials. Renewable and Sustainable Energy Reviews, 466(2016).
[30] H TANG, M SUN, C WANG. 2D silicate materials for composite polymer electrolytes. Chemistry — An Asian Journal, 16, 2842(2021).
[32] P G BALKANLOO, A P MARJANI, F ZANBILI et al. Clay mineral/polymer composite: characteristics, synthesis, and application in Li-ion batteries: a review. Applied Clay Science, 106632(2022).
[33] C H CHEN, Y Z MA, C L WANG. Investigation of electrochemical performance of montmorillonite clay as Li-ion battery electrode. Sustainable Materials and Technologies, e00086(2018).
[34] B P BAKHMATYUK, I I GRYGORCHAK, A Y PIDLUZHNA et al. Intercalation of bentonite: thermodynamics, kinetics, and practical applications. Inorganic Materials, 43, 537(2007).
[35] M S CHEN, W FU, Y HU et al. Controllable growth of carbon nanosheets in the montmorillonite interlayers for high-rate and stable anode in lithium ion battery. Nanoscale, 12, 16262(2020).
[36] L FENG, J SONG, C SUN et al. Improving the performance of SiO
[37] H TANG, S ZHAO, Q WENG et al. Fast Li-ion conductor additive toward high-rate lithium storage capacity for Li2ZnTi3O8 in lithium-ion batteries. Ionics, 29, 3001(2023).
[38] Y FENG, B ZHONG, R ZHANG et al. Achieving high-power and dendrite-free lithium metal anodes
[39] T ZENG, Y YAN, M HE et al. A single-ion-conducting lithium- based montmorillonite interfacial layer for stable lithium-metal batteries. Journal of Materials Chemistry A, 10, 23712(2022).
[40] Y WANG, Y FAN, D LIAO et al. Highly Zn2+-conductive and robust modified montmorillonite protective layer of electrodes toward high-performance rechargeable zinc-ion batteries. Energy Storage Materials, 212(2022).
[41] Y HAN, F WANG, B ZHANG et al. Building block effect induces horizontally oriented bottom Zn(002) deposition for a highly stable zinc anode. Energy Storage Materials, 102928(2023).
[42] C LUO, H WANG, Y QIAN et al. Montmorillonite as a sodium- ion-conductor interface for stable sodium metal anodes. Journal of Power Sources, 232038(2022).
[44] C ZHANG, Y HE, Y WANG et al. CoFe2O4 nanoparticles loaded N-doped carbon nanofibers networks as electrocatalyst for enhancing redox kinetics in Li-S batteries. Applied Surface Science, 149908(2021).
[46] W DONG, L JI, M ZHAO et al. Nitrogen-doped nanotubes and few-layer montmorillonite composites as an effective polysulfides adsorbent for lithium-sulfur batteries. Diamond and Related Materials, 110265(2023).
[47] L WU, Y YU, Y DAI et al. Multisize CoS2 particles intercalated/ coated-montmorillonite as efficient sulfur host for high-performance lithium-sulfur batteries. ChemSusChem, 15, e202101991(2022).
[48] V MOLAHALLI, V S BHAT, A SHETTY et al. ZnO doped SnO2 nano flower decorated on graphene oxide/polypyrrole nanotubes for symmetric supercapacitor applications. Journal of Energy Storage, 107953(2023).
[49] M B ARVAS. Hydrothermal synthesis of polypyrrole/dye- functionalized carbon cloth electrode for wide potential window supercapacitor. Synthetic Metals, 117275(2023).
[50] W GE, Q MA, Z AI et al. Three-dimensional reduced graphene oxide/montmorillonite nanosheet aerogels as electrode material for supercapacitor application. Applied Clay Science, 106022(2021).
[51] D JIANG, M ZHENG, Y YOU.
[52] G XU, M WANG, H BAO et al. Design of Ni(OH)2/M-MMT nanocomposite with higher charge transport as a high capacity supercapacitor. Frontiers in Chemistry, 916860(2022).
[53] X F LUO, F Y HSU, Y H GAN et al. Intercalation of Fe-montmorillonite for developing nacre-inspired flexible all-solid- state supercapacitor with circular economy approach. Chinese Journal of Physics, 405(2023).
[54] F HAMIDOUCHE, Z GHEBACHE, J C LEPRETRE et al. Montmorillonite/poly(pyrrole) for low-cost supercapacitor electrode hybrid materials. Polymers, 16, 919(2024).
[55] D T RATHNAYAKE, K S KARUNADASA, A S WIJEKOON et al. Polyaniline-conjugated graphite-montmorillonite composite electrode prepared by
[58] Y AN, X HAN, Y LIU et al. Progress in solid polymer electrolytes for lithium-ion batteries and beyond. Small, 18, 2103617(2022).
[59] B ZHU, D Z WANG, W H YU. The study of structure and electrical properties of montmorillonite solid electrolyte. Solid State Ionics, 36, 15(1989).
[60] E RUIZ-HITZKY, P ARANDA. Polymer-salt intercalation complexes in layer silicates. Advanced Materials, 2, 545(1990).
[61] S CHOUDHARY, R SENGWA. Effect of different anions of lithium salt and MMT nanofiller on ion conduction in melt-compounded PEO-LiX-MMT electrolytes. Ionics, 18, 379(2012).
[62] R A VAIA, S VASUDEVAN, W KRAWIEC et al. New polymer electrolyte nanocomposites: melt intercalation of poly(ethylene oxide) in mica-type silicates. Advanced Materials, 7, 154(1995).
[63] H W CHEN, F C CHANG. The novel polymer electrolyte nanocomposite composed of poly(ethylene oxide), lithium triflate and mineral clay. Polymer, 42, 9763(2001).
[64] M MORENO, R QUIJADA, ANA M A SANTA et al. Electrical and mechanical properties of poly(ethylene oxide)/intercalated clay polymer electrolyte. Electrochimica Acta, 112(2011).
[65] A K NATH, B SHARMA, B J BORAH et al. Structural and electrochemical properties of montmorillonite-poly(ethylene oxide) intercalated nanocomposites for lithium-ion batteries. International Journal of Polymer Analysis and Characterization, 28, 279(2023).
[66] X TIAN, S ZOU, R LV et al. Well-dispersed polydopamine
[67] Y MA, L B LI, G X GAO et al. Effect of montmorillonite on the ionic conductivity and electrochemical properties of a composite solid polymer electrolyte based on polyvinylidenedifluoride/ polyvinyl alcohol matrix for lithium ion batteries. Electrochimica Acta, 535(2016).
[68] E M MASOUD. Montmorillonite incorporated polymethylmethacrylate matrix containing lithium trifluoromethanesulphonate (LTF) salt: thermally stable polymer nanocomposite electrolyte for lithium-ion batteries application. Ionics, 25, 2645(2019).
[69] Y M JEON, S KIM, M LEE et al. Polymer-clay nanocomposite solid-state electrolyte with selective cation transport boosting and retarded lithium dendrite formation. Advanced Energy Materials, 10, 2003114(2020).
[70] L LI, Y SHAN, X YANG. New insights for constructing solid polymer electrolytes with ideal lithium-ion transfer channels by using inorganic filler. Materials Today Communications, 101910(2021).
[71] S ZHOU, Z HAN, X WANG et al. Low-cost and high-safety montmorillonite-based solid electrolyte for lithium metal batteries. Applied Clay Science, 107329(2024).
[72] Y ZHU, Y ZHENG, J LIU et al. Molecular coupling strategy achieving
[73] Y ZHAO, L LI, Y SHAN et al.
[74] L WANG, S YI, Q LIU et al. Bifunctional lithium-montmorillonite enabling solid electrolyte with superhigh ionic conductivity for high-performanced lithium metal batteries. Energy Storage Materials, 102961(2023).
[75] X LI, Y WANG, K XI et al. Quasi-solid-state ion-conducting arrays composite electrolytes with fast ion transport vertical- aligned interfaces for all-weather practical lithium-metal batteries. Nano-Micro Letters, 14, 210(2022).
[76] M RILEY, P S FEDKIW, S A KHAN. Transport properties of lithium hectorite-based composite electrolytes. Journal of the Electrochemical Society, 149, A667(2002).
[78] Y G ZHANG, Y ZHAO, Z BAKENOV et al. Poly(vinylidene fluoride-co-hexafluoropropylene)/poly(methylmethacrylate)/nanoclay composite gel polymer electrolyte for lithium/sulfur batteries. Journal of Solid State Electrochemistry, 18, 1111(2014).
[79] H PORTHAULT, C CALBERG, J AMIRAN et al. Development of a thin flexible Li battery design with a new gel polymer electrolyte operating at room temperature. Journal of Power Sources, 229055(2021).
[80] E O SAMUILOVA, V E SITNIKOVA, R O OLEKHNOVICH et al. Studying the collapse of bentonite-containing composites based on acrylic copolymers. Russian Journal of Physical Chemistry A, 92, 1602(2018).
[81] S BASHIR, M HINA, J IQBAL et al. Self-healable poly(
[82] Q LIU, A ZHAO, X HE et al. Full-temperature all-solid-state Ti3C2T
[83] Q HU, X SHI, K SUN et al. A super-stretchable and thermally stable hydrogel electrolyte for high performance supercapacitor with wide operation temperature. Journal of Alloys and Compounds, 164646(2022).
[84] B KAIBARTA, A K DASMAHAPATRA. Carbon-based hierarchical mesoporous polyaniline/montmorillonite nanocomposites for high energy density supercapacitors. Journal of Energy Storage, 110703(2024).
[85] Y XIA, T S MATHIS, M Q ZHAO et al. Thickness-independent capacitance of vertically aligned liquid-crystalline MXenes. Nature, 557, 409(2018).
[88] J DENG, J XIE, G ZHANG et al. Research progress of cross- linked fiber membranes for lithium-ion battery separators. Chemical Engineering Science, 118970(2023).
[90] M L PARA, D VERSACI, J AMICI et al. Synthesis and characterization of montmorillonite/polyaniline composites and its usage to modify a commercial separator. Journal of Electroanalytical Chemistry, 114876(2021).
[91] C J FANG, S L YANG, X F ZHAO et al. Electrospun montmorillonite modified poly(vinylidene fluoride) nanocomposite separators for lithium-ion batteries. Materials Research Bulletin, 1(2016).
[92] M J KOH, H Y HWANG, D J KIM et al. Preparation and characterization of porous PVdF-HFP/clay nanocomposite membranes. Journal of Materials Science & Technology, 26, 633(2010).
[93] J LI, J YU, Y WANG et al. Intercalated montmorillonite reinforced polyimide separator prepared by solution blow spinning for lithium-ion batteries. Industrial & Engineering Chemistry Research, 59, 12879(2020).
[94] M QIAO, G ZHANG, J DENG et al. Electrospun polyimide@organic-montmorillonite composite separator with enhanced mechanical and thermal performances for high-safety lithium-ion battery. Journal of Materials Science, 57, 11796(2022).
[95] H LI, T FENG, Y LIANG et al. Construction of PMIA@PAN/PVDF-HFP/TiO2 coaxial fibrous separator with enhanced mechanical strength and electrolyte affinity for lithium-ion batteries. Chinese Chemical Letters, 34, 108350(2023).
[96] Z ZHANG, J WANG, H QIN et al. Constructing an anion-braking separator to regulate local Li+ solvation structure for stabilizing lithium metal batteries. ACS Nano, 18, 2250(2024).
[97] M YANG, N JUE, Y CHEN et al. Improving cyclability of lithium metal anode
[98] W AHN, S N LIM, D U LEE et al. Interaction mechanism between functionalized protection layer and dissolved polysulfide for extended cycle life of lithium sulfur batteries. Journal of Materials Chemistry A, 3, 9461(2015).
[99] Y WANG, Y WU, P MAO et al. A Keggin Al13-montmorillonite modified separator retards the polysulfide shuttling and accelerates Li-ion transfer in Li-S batteries. Small, 20, 2304898(2023).
[100] M X ZHOU, W H ZHOU, X LONG et al. A 2D montmorillonite- carbon nanotube interconnected porous network that prevents polysulfide shuttling. New Carbon Materials, 38, 1070(2023).
[101] W WANG, K XI, B LI et al. A sustainable multipurpose separator directed against the shuttle effect of polysulfides for high-performance lithium- sulfur batteries. Advanced Energy Materials, 12, 2200160(2022).
[102] L WU, Y ZHAO, Y YU et al. FeS2 intercalated montmorillonite as a multifunctional separator coating for high-performance lithium- sulfur batteries. Inorganic Chemistry Frontiers, 10, 651(2023).
[103] L WU, Y ZHAO, Y DAI et al. CoS2@montmorillonite as an efficient separator coating for high-performance lithium-sulfur batteries. Inorganic Chemistry Frontiers, 9, 3335(2022).
[104] H WANG, C LIANG, Y LI et al. A porous ceramic separator prepared from natural minerals: research on the mechanism of high liquid absorption and electrochemical properties of mineral material separator. Materials Chemistry and Physics, 125032(2021).
[105] L HONG, X WU, C MA et al. Boosting the Zn-ion transfer kinetics to stabilize the Zn metal interface for high-performance rechargeable Zn-ion batteries. Journal of Materials Chemistry A, 9, 16814(2021).
Get Citation
Copy Citation Text
Zhipeng WEN, Yi WEI, Xianghua HOU, Jiawen GUO, Qu LI, Manqing ZHU, Jiahao ZHANG, Kai PAN, Lian WU.
Category:
Received: May. 13, 2024
Accepted: --
Published Online: Jan. 21, 2025
The Author Email: PAN Kai (pankai_09@sina.com), WU Lian (wulian@gdcri.com)