Recent Progress of Boron-based Materials in Lithium-sulfur Battery

Gaoran LI; Hongyang LI; Haibo ZENG

doi:10.15541/jim20210183

[1] B DUNN, H KAMATH, M TARASCON J. Electrical energy storage for the grid: a battery of choices. Science, 334, 928-935(2011).

[2] S ARICO A, P BRUCE, B SCROSATI et al. Nanostructured materials for advanced energy conversion and storage devices. Nature Materials, 4, 366-377(2005).

[3] R LIANG Y, Z ZHAO C, H YUAN et al. A review of rechargeable batteries for portable electronic devices. InfoMat, 1, 6-32(2019).

[4] B GOODENOUGH J, S PARK K. The Li-ion rechargeable battery: a perspective. Journal of the American Chemical Society, 135, 1167-1176(2013).

[5] M TARASCON J, M ARMAND. Issues and challenges facing rechargeable lithium batteries. Nature, 414, 171-179(2011).

[6] Y JIN G, C HE H, J WU et al. Cobalt-doped hollow carbon framework as sulfur host for the cathode of lithium sulfur battery. Journal of Inorganic Materials, 36, 203-209(2021).

[7] R FANG, Y ZHAO S, H SUN Z et al. More reliable lithium-sulfur batteries: tatus, solutions and prospects. Advanced Materials, 29, 1606823(2017).

[8] J HU J, R LI G, P GAO X. Current status, problems and challenges in lithium-sulfur batteries. Journal of Inorganic Materials, 28, 1181-1186(2013).

[9] R LI G, S WANG, N ZHANG Y et al. Revisiting the role of polysulfides in lithium-sulfur batteries. Advanced Materials, 30, 1705590(2018).

[10] J PENG H, Q HUANG J, Q ZHANG. A review of flexible lithium-sulfur and analogous alkali metal-chalcogen rechargeable batteries. Chemical Society Reviews, 46, 5237-5288(2017).

[11] M JANA, R XU, B CHENG X et al. Rational design of two-dimensional nanomaterials for lithium-sulfur batteries. Energy & Environmental Science, 13, 1049-1075(2020).

[12] R HE J, A MANTHIRAM. A review on the status and challenges of electrocatalysts in lithium-sulfur batteries. Energy Storage Materials, 20, 55-70(2019).

[13] W SEH Z, M SUN Y, F ZHANG Q et al. Designing high-energy lithium-sulfur batteries. Chemical Society Reviews, 45, 5605-5634(2016).

[14] L JI X, S EVERS, R BLACK et al. Stabilizing lithium-sulphur cathodes using polysulphide reservoirs. Nature Communications, 2, 325(2011).

[15] Z ZHANG, L KONG L, S LIU et al. A high-efficiency sulfur/ carbon composite based on 3D graphene nanosheet@carbon nanotube matrix as cathode for lithium-sulfur battery. Advanced Energy Materials, 7, 1602543(2017).

[16] C XU W, X PAN X, X MENG et al. A conductive sulfur-hosting material involving ultrafine vanadium nitride nanoparticles for high-performance lithium-sulfur battery. Electrochimica Acta, 331, 135287(2020).

[17] T LIU Y, S LIU, R LI G et al. High volumetric energy density sulfur cathode with heavy and catalytic metal oxide host for lithium-sulfur battery. Advanced Science, 7, 1903693(2020).

[18] H CHEN H, W XIAO Y, C CHEN et al. Conductive MOF modified separator for mitigating the shuttle effect of lithium- sulfur battery through a filtration method. ACS Applied Materials & Interfaces, 11, 11459-11465(2019).

[19] J YOO, J CHO S, Y JUNG G et al. COF-net on CNT-net as a molecularly designed, hierarchical porous chemical trap for polysulfides in lithium-sulfur batteries. Nano Letters, 16, 3292-3300(2016).

[20] Y HU, C LIU. Introduction of 1,2-migration for organoboron compounds. University Chemistry, 34, 39-44(2019).

[21] M SOREN K, W SUNING. Boron-based stimuli responsive materials. Chemical Society Reviews, 48, 3537-3549(2019).

[22] G HUANG Z, N WANG S, D DEWHURST R et al. Boron: its role in energy-related processes and applications. Angewandte Chemie International Edition, 59, 8800-8816(2020).

[23] H ZHU Y, M GAO S, S HOSMANE N. Boron-enriched advanced energy materials. Inorganica Chimica Acta, 471, 577-586(2017).

[24] K KHAN, K TAREEN A, M ASLAM et al. Synthesis, properties and novel electrocatalytic applications of the 2D-borophene xenes. Progress in Solid State Chemistry, 59, 100283(2020).

[25] W RAO D, J LIU X, H YANG et al. Interfacial competition between a borophene-based cathode and electrolyte for the multiple-sulfide immobilization of a lithium sulfur battery. Journal of Materials Chemistry A, 7, 7092-7098(2019).

[26] R JIANG H, W SHYY, M LIU et al. Borophene and defective borophene as potential anchoring materials for lithium-sulfur batteries: a first-principles study. Journal of Materials Chemistry A, 6, 2107-2114(2018).

[27] Y ZHANG C, Q HE, W CHU et al. Transition metals doped borophene-graphene heterostructure for robust polysulfide anchoring: a first principle study. Applied Surface Science, 534, 147575(2020).

[28] L ZHANG, P LIANG, B SHU H et al. Borophene as efficient sulfur hosts for lithium-sulfur batteries: suppressing shuttle effect and improving conductivity. Journal of Physical Chemistry C, 121, 15549-15555(2017).

[29] S GRIXTI, S MUKHERJEE, V SINGH C. Two-dimensional boron as an impressive lithium-sulphur battery cathode material. Energy Storage Materials, 13, 80-87(2018).

[30] J MANNIX A, F ZHOU X, B KIRALY et al. Synthesis of borophenes: anisotropic, two-dimensional boron polymorphs. Science, 350, 1513-1516(2015).

[31] J FENG B, J ZHANG, Q ZHONG et al. Experimental realization of two-dimensional boron sheets. Nature Chemistry, 8, 564-569(2016).

[32] P PARAKNOWITSCH J, A THOMAS. Doping carbons beyond nitrogen: an overview of advanced heteroatom doped carbons with boron, sulphur and phosphorus for energy applications. Energy & Environmental Science, 6, 2839-2855(2013).

[33] B WANG H, T MAIYALAGAN, X WANG. Review on recent progress in nitrogen-doped graphene: synthesis, characterization, and its potential applications. ACS Catalysis, 2, 781-794(2012).

[34] Y XIE, Z MENG, W CAI T et al. Effect of boron-doping on the graphene aerogel used as cathode for the lithium sulfur battery. ACS Applied Materials & Interfaces, 7, 25202-25210(2015).

[35] C SHI P, Y WANG, X LIANG et al. Simultaneously exfoliated boron-doped graphene sheets to encapsulate sulfur for applications in lithium-sulfur batteries. ACS Sustainable Chemistry & Engineering, 6, 9661-9670(2018).

[36] J YANG L, J JIANG S, Y ZHAO et al. Boron-doped carbon nanotubes as metal-free electrocatalysts for the oxygen reduction reaction. Angewandte Chemie International Edition, 50, 7132-7135(2011).

[37] W AI, W LI J, Z DU Z et al. Dual confinement of polysulfides in boron-doped porous carbon sphere/graphene hybrid for advanced Li-S batteries. Nano Research, 11, 4562-4573(2018).

[38] P YANG C, X YIN Y, H YE et al. Insight into the effect of boron doping on sulfur/carbon cathode in lithium-sulfur batteries. ACS Applied Materials & Interfaces, 6, 8789-8795(2014).

[39] X XU C, H ZHOU H, P FU C et al. Hydrothermal synthesis of boron-doped unzipped carbon nanotubes/sulfur composite for high-performance lithium-sulfur batteries. Electrochimica Acta, 232, 156-163(2017).

[40] P HAN, A MANTHIRAM. Boron- and nitrogen-doped reduced graphene oxide coated separators for high-performance Li-S batteries. Journal of Power Sources, 369, 87-94(2017).

[41] Z HOU T, X CHEN, J PENG H et al. Design principles for heteroatom-doped nanocarbon to achieve strong anchoring of polysulfides for lithium-sulfur batteries. Small, 12, 3283-3291(2016).

[42] G XIONG D, Z ZHANG, Y HUANG X et al. Boosting the polysulfide confinement in B/N-codoped hierarchically porous carbon nanosheets via Lewis acid-base interaction for stable Li-S batteries. Journal of Energy Chemistry, 51, 90-100(2020).

[43] Y YUAN S, L BAO J, N WANG L et al. Graphene-supported nitrogen and boron rich carbon layer for improved performance of lithium-sulfur batteries due to enhanced chemisorption of lithium polysulfides. Advanced Energy Materials, 6, 1501733(2016).

[44] L CHEN, R FENG J, H ZHOU H et al. Hydrothermal preparation of nitrogen, boron co-doped curved graphene nanoribbons with high dopant amounts for high-performance lithium sulfur battery cathodes. Journal of Materials Chemistry A, 5, 7403-7415(2017).

[45] B JIN C, K ZHANG W, Z ZHUANG Z et al. Enhanced sulfide chemisorption using boron and oxygen dually doped multi-walled carbon nanotubes for advanced lithium-sulfur batteries. Journal of Materials Chemistry A, 5, 632-640(2017).

[46] S ULLAH, A DENIS P, F SATO. Unusual enhancement of the adsorption energies of sodium and potassium in sulfur-nitrogen and silicon-boron codoped graphene. ACS Omega, 3, 15821-15828(2018).

[47] Z ZHANG, G XIONG D, H SHAO A et al. Integrating metallic cobalt and N/B heteroatoms into porous carbon nanosheets as efficient sulfur immobilizer for lithium-sulfur batteries. Carbon, 167, 918-929(2020).

[48] P WANG, R KUMAR, M SANKARAN E et al. Vanadium diboride (VB₂) synthesized at high pressure: elastic, mechanical, electronic, and magnetic properties and thermal stability. Inorganic Chemistry, 57, 1096-1105(2018).

[49] J HE G, M LING, Y HAN X et al. Self-standing electrodes with core-shell structures for high-performance supercapacitors. Energy Storage Materials, 9, 119-125(2017).

[50] C WANG C, A AKBAR S, W CHEN et al. Electrical properties of high-temperature oxides, borides, carbides, and nitrides. Journal of Materials Science, 30, 1627-1641(1995).

[51] B XIAO Z, Z YANG, J ZHANG L et al. Sandwich-type NbS₂@S@I-doped graphene for high-sulfur-loaded, ultrahigh-rate, and long-life lithium sulfur batteries. ACS Nano, 11, 8488-8498(2017).

[52] J WANG L, H LIU F, Y ZHAO B et al. Carbon nanobowls filled with MoS₂ nanosheets as electrode materials for supercapacitors. ACS Applied Nano Materials, 3, 6448-6459(2020).

[53] J BALACH, J LINNEMANN, T JAUMANN et al. Metal-based nanostructured materials for advanced lithium-sulfur batteries. Journal of Materials Chemistry A, 6, 23127-23168(2018).

[54] L BEN-DOR, Y SHIMONY. Crystal structure, magnetic susceptibility and electrical conductivity of pure and NiO-doped MoO₂ and WO₂. Materials Research Bulletin, 9, 837-44(1974).

[56] S FENG L, X QUN C, Y LIN M et al. Nb-based oxides as anode materials for lithium ion batteries. Progress in Chemistry, 27, 297-309(2015).

[57] Q TAO, L MA S, T CUI et al. Structures and properties of functional transition metal borides. Acta Physica Sinica, 66, 036103(2017).

[58] F SHEN Y, C XU, M HUANG et al. Research advances of boron clusters,borane and metal-doped boron compounds. Progress in Chemistry, 28, 1601-1614(2016).

[59] S GUPTA, K PATEL M, A MIOTELLO et al. Metal boride-based catalysts for electrochemical water-splitting: a review. Advanced Functional Materials, 30, 1906481(2020).

[60] F WU, C WU. New secondary batteries and their key materials based on the concept of multi-electron reaction. Chinese Science Bulletin, 59, 3369-3376(2014).

[61] B GUAN, S FAN L, X WU et al. The facile synthesis and enhanced lithium-sulfur battery performance of an amorphous cobalt boride (Co₂B)@graphene composite cathode. Journal of Materials Chemistry A, 6, 24045-24049(2018).

[62] B GUAN, Y ZHANG, S FAN L et al. Blocking polysulfide with Co₂B@CNT via “synergetic adsorptive effect” toward ultrahigh- rate capability and robust lithium-sulfur battery. ACS Nano, 13, 6742-6750(2019).

[63] B GUAN, X SUN, Y ZHANG et al. The discovery of interfacial electronic interaction within cobalt boride@MXene for high performance lithium-sulfur batteries. Chinese Chemical Letters, 32, 2249-2253(2020).

[64] B BASU, A RAJU GSURI. Processing and properties of monolithic TiB₂ based materials. International Materials Reviews, 51, 352-374(2006).

[65] C LI C, B LIU X, L ZHU et al. Conductive and polar titanium boride as a sulfur host for advanced lithium-sulfur batteries. Chemistry of Materials, 30, 6969-6977(2018).

[66] J LI Z, R JIANG H, C LAI N et al. Designing effective solvent- catalyst interface for catalytic sulfur conversion in lithium-sulfur batteries. Chemistry of Materials, 31, 10186-10196(2019).

[67] M JIN L, J NI, C SHEN et al. Metallically conductive TiB₂ as a multi-functional separator modifier for improved lithium sulfur batteries. Journal of Power Sources, 448, 227336(2020).

[68] R WU, K XU H, W ZHAO Y et al. Borophene-like boron subunits-inserted molybdenum framework of MoB₂ enables stable and quick-acting Li₂S₆-based lithium-sulfur batteries. Energy Storage Materials, 32, 216-224(2020).

[69] R HE J, A BHARGAV, A MANTHIRAM. Molybdenum boride as an efficient catalyst for polysulfide redox to enable high-energy- density lithium-sulfur batteries. Advanced Materials, 32, 2004741(2020).

[70] Q PANG, Y KWOK C, D KUNDU et al. Lightweight metallic MgB₂ mediates polysulfide redox and promises high-energy-density lithium-sulfur batteries. Joule, 3, 136-148(2019).

[71] T YU T, F GAO P, Y ZHANG et al. Boron-phosphide monolayer as a potential anchoring material for lithium-sulfur batteries: a first-principles study. Applied Surface Science, 486, 281-286(2019).

[72] S JANA, S THOMAS, H LEE C et al. B₃S monolayer: prediction of a high-performance anode material for lithium-ion batteries. Journal of Materials Chemistry A, 7, 12706-12712(2019).

[73] C SUN, X HAI C, Y ZHOU et al. Highly catalytic boron nitride nanofiber in situ grown on pretreated ketjenblack as a cathode for enhanced performance of lithium-sulfur batteries. ACS Applied Energy Materials, 3, 10841-10853(2020).

[74] R ARENAL, A LOPEZ BEZANILLA. Boron nitride materials: an overview from 0D to 3D (nano)structures. Wiley Interdisciplinary Reviews-Computational Molecular Science, 5, 299-309(2015).

[75] F JIANG X, H WENG Q, B WANG X et al. Recent progress on fabrications and applications of boron nitride nanomaterials: a review. Journal of Materials Science and Technology, 31, 589-598(2015).

[76] A PRAKASH, D NEHATE S, B SUNDARAM K. Boron carbon nitride based metal-insulator-metal UV detectors for harsh environment applications. Optics Letters, 41, 4249-4252(2016).

[77] M ZHAO Y, L YANG, X ZHAO J et al. How to make inert boron nitride nanosheets active for the immobilization of polysulfides for lithium-sulfur batteries: a computational study. Physical Chemistry Chemical Physics, 19, 18208-18216(2017).

[78] K YI Y, P LI H, H CHANG H et al. Few-layer boron nitride with engineered nitrogen vacancies for promoting conversion of polysulfide as a cathode matrix for lithium-sulfur batteries. Chemistry, 25, 8112-8117(2019).

[79] B HE, C LI W, Y ZHANG et al. Paragenesis BN/CNTs hybrid as a monoclinic sulfur host for high rate and ultra-long life lithium- sulfur battery. Journal of Materials Chemistry A, 6, 24194-24200(2018).

[80] R DENG D, D BAI C, F XUE et al. Multifunctional ion-sieve sonstructed by 2D materials as an interlayer for Li-S batteries. ACS Applied Materials & Interfaces, 11, 11474-11480(2019).

[81] K SUN, Q GUO P, N SHANG X et al. Mesoporous boron carbon nitride/graphene modified separators as efficient polysulfides barrier for highly stable lithium-sulfur batteries. Journal of Electroanalytical Chemistry, 842, 34-40(2019).

[82] Y FAN, Z YANG, X HUA W et al. Functionalized boron nitride nanosheets/graphene interlayer for fast and long-life lithium-sulfur batteries. Advanced Energy Materials, 7, 1602380(2017).

[83] H KIM P J, J SEO, K FU et al. Synergistic protective effect of a BN-carbon separator for highly stable lithium sulfur batteries. NPG Asia Materials, 9, e375(2017).

[84] A PRAMANICK, P DEY P, K DAS P. Microstructure, phase and electrical conductivity analyses of spark plasma sintered boron carbide machined with WEDM. Ceramics International, 46, 2887-2894(2020).

[85] M YEGANEH, H SARAF H, F KAFI et al. First principles investigation of vibrational, electronic and optical properties of graphene-like boron carbide. Solid State Communications, 305, 113750(2020).

[86] K CHANG Y, H SUN X, D MA M et al. Application of hard ceramic materials B₄C in energy storage: design B₄C@C core-shell nanoparticles as electrodes for flexible all-solid-state micro- supercapacitors with ultrahigh cyclability. Nano Energy, 75, 104947(2020).

[87] L LUO, H CHUNG S, Y ASL H et al. Long-life lithium-sulfur batteries with a bifunctional cathode substrate configured with boron carbide nanowires. Advanced Materials, 30, 1804149(2018).

[88] N SONG N, Z GAO, Y ZHANG Y et al. B₄C nanoskeleton enabled, flexible lithium-sulfur batteries. Nano Energy, 58, 30-39(2019).

[89] H ZHANG R, C CHI, C WU M et al. A long-life Li-S battery enabled by a cathode made of well-distributed B₄C nanoparticles decorated activated cotton fibers. Journal of Power Sources, 451, 227751(2020).