Modified Al negative electrode for stable high-capacity Al—Te batteries

Xuefeng Zhang; Shuqiang Jiao

doi:10.1007/s12613-022-2410-y

International Journal of Minerals, Metallurgy, and Materials ›› 2022, Vol. 29 ›› Issue (4) :896 -904. DOI: 10.1007/s12613-022-2410-y

Article

Modified Al negative electrode for stable high-capacity Al—Te batteries

Xuefeng Zhang ¹
, Shuqiang Jiao ¹^,^b

Author information +

History +

PDF

Abstract

Metal aluminum batteries (MABs) are considered potential large-scale energy storage devices because of their high energy density, resource abundance, low cost, safety, and environmental friendliness. Given their high electrical conductivity, high theoretical specific capacity, and high discharge potential, Te is considered a potential positive electrode material for MABs. Nonetheless, the critical issues induced by the chemical and electrochemical dissolution of tellurium and subsequent chemical precipitation on bare Al negative electrodes result in poor cycle stability and low discharge capacity of Al—Te batteries. Here an efficient TiB₂-based modified layer has been proposed to address bare Al electrodes (Al/TB). Consequently, the low-voltage hysteresis and long cycle life of the Al/TB negative electrode have been achieved. In addition, the electrochemical performance of the Al—Te battery based on the Al/TB negative electrode is dramatically improved. Furthermore, the modified separator technology is introduced to match with the as-designed Al/TB negative electrode. Therefore, the record-setting long-term cycle stability of up to 500 cycles has been achieved in the Al—Te battery. The facile strategy also opens a potential route for other high-energy density battery systems, such as Al—S and Al—Se batteries.

Keywords

metal aluminum battery / negative electrode / electrochemically inert TiB₂ / tellurium

Cite this article

Download citation ▾

Xuefeng Zhang, Shuqiang Jiao. Modified Al negative electrode for stable high-capacity Al—Te batteries. International Journal of Minerals, Metallurgy, and Materials, 2022, 29(4): 896-904 DOI:10.1007/s12613-022-2410-y

登录浏览全文

4963

注册一个新账户忘记密码

References

Publishing order | Descend order by publishing year | Descend order by cited within

[1]	Kong L, Yan C, Huang JQ, Zhao MQ, Titirici MM, Xiang R, Zhang Q. A review of advanced energy materials for magnesium—sulfur batteries. Energy Environ. Mater., 2018, 1(3): 100.

[2]	McAllister BT, Kyne LT, Schon TB, Seferos DS. Potential for disruption with organic magnesium-ion batteries. Joule, 2019, 3(3): 620.

[3]	T. Xiong, Y.X. Zhang, W.S.V. Lee, and J.M. Xue, Defect engineering in manganese-based oxides for aqueous rechargeable zinc-ion batteries: A review, Adv. Energy Mater., 10(2020), No. 34, art. No. 2001769.

[4]	Fang GZ, Zhou J, Pan AQ, Liang SQ. Recent advances in aqueous zinc-ion batteries. ACS Energy Lett., 2018, 3(10): 2480.

[5]	Tu JG, Song WL, Lei HP, Yu ZJ, Chen LL, Wang MY, Jiao SQ. Nonaqueous rechargeable aluminum batteries: Progresses, challenges, and perspectives. Chem. Rev., 2021, 121(8): 4903.

[6]	Zhang KQ, Kirlikovali KO, Suh JM, Choi JW, Jang HW, Varma RS, Farha OK, Shokouhimehr M. Recent advances in rechargeable aluminum-ion batteries and considerations for their future progress. ACS Appl. Energy Mater., 2020, 3(7): 6019.

[7]	Sun HB, Wang W, Yu ZJ, Yuan Y, Wang S, Jiao SQ. A new aluminium-ion battery with high voltage, high safety and low cost. Chem. Commun., 2015, 51(59): 11892.

[8]	H. Chen, F. Guo, Y.J. Liu, T.Q. Huang, B.N. Zheng, N. Ananth, Z. Xu, W.W. Gao, and C. Gao, A defect-free principle for advanced graphene cathode of aluminum-ion battery, Adv. Mater., 29(2017), No. 12, art. No. 1605958.

[9]	J.F. Li, K.S. Hui, S.P. Ji, C.Y. Zha, C.Z. Yuan, S.X. Wu, F. Bin, X. Fan, F.M. Chen, Z.P. Shao, and K.N. Hui, Electrodeposition of a dendrite-free 3D Al anode for improving cycling of an aluminum—graphite battery, Carbon Energy, 2021. DOI: https://doi.org/10.1002/cey2.155

[10]	X.L. Xu, K.S. Hui, K.N. Hui, J.X. Shen, G.W. Zhou, J.H. Liu, and Y.C. Sun, Engineering strategies for low-cost and high-power density aluminum-ion batteries, Chem. Eng. J., 418(2021), art. No. 129385.

[11]	S. Wang, Z.J. Yu, J.G. Tu, J.X. Wang, D.H. Tian, Y.J. Liu, and S.Q. Jiao, A novel aluminum-ion battery: Al/AlCl₃—[EMIm] Cl/Ni₃S₂@graphene, Adv. Energy Mater., 6(2016), No. 13, art. No. 1600137.

[12]	Zhang XF, Wang S, Tu JG, Zhang GH, Li SJ, Tian DH, Jiao SQ. Flower-like vanadium suflide/reduced graphene oxide composite: An energy storage material for aluminum-ion batteries. ChemSusChem, 2018, 11(4): 709.

[13]	Lei HP, Wang MY, Tu JG, Jiao SQ. Single-crystal and hierarchical VSe₂ as an aluminum-ion battery cathode. Sustainable Energy Fuels, 2019, 3(10): 2717.

[14]	Jiang JL, Li H, Fu T, Hwang BJ, Li X, Zhao JB. One-dimensional Cu_2−xSe nanorods as the cathode material for high-performance aluminum-ion battery. ACS Appl. Mater. Interfaces, 2018, 10(21): 17942.

[15]	Du YQ, Zhang BY, Zhang WY, Jin HX, Qin JY, Wan JQ, Zhang JX, Chen GW. Interfacial engineering of Bi₂Te₃/Sb₂Te₃ heterojunction enables high-energy cathode for aluminum batteries. Energy Storage Mater., 2021, 38, 231.

[16]	Yu ZJ, Jiao SQ, Tu JG, Luo YW, Song WL, Jiao HD, Wang MY, Chen HS, Fang DN. Rechargeable nickel telluride/aluminum batteries with high capacity and enhanced cycling performance. ACS Nano, 2020, 14(3): 3469.

[17]	Zhang XF, Jiao SQ, Tu JG, Song WL, Xiao X, Li SJ, Wang MY, Lei HP, Tian DH, Chen HS, Fang DN. Rechargeable ultrahigh-capacity tellurium—aluminum batteries. Energy Environ. Sci., 2019, 12(6): 1918.

[18]	Zhang XF, Wang MY, Tu JG, Jiao SQ. Hierarchical N-doped porous carbon hosts for stabilizing tellurium in promoting Al—Te batteries. J. Energy Chem., 2021, 57, 378.

[19]	Zhang XF, Tu JG, Wang MY, Jiao SQ. A strategy for massively suppressing the shuttle effect in rechargeable Al—Te batteries. Inorg. Chem. Front., 2020, 7(20): 4000.

[20]	Zhao Q, Zachman MJ, Al Sadat WI, Zheng J, Kourkoutis LF, Archer L. Solid electrolyte interphases for high-energy aqueous aluminum electrochemical cells. Sci. Adv., 2018, 4(11): 8131.

[21]	Ke X, Guo SF, Zhang GS, Zhou X, Xiao L, Hao GZ, Wang N, Jiang W. Safe preparation, energetic performance and reaction mechanism of corrosion-resistant Al/PVDF nano-composite films. J. Mater. Chem. A, 2018, 6(36): 17713.

[22]	L.M. Jin, J. Ni, C. Shen, F.L. Peng, Q. Wu, D.H. Ye, J.S. Zheng, G.R. Li, C.M. Zhang, Z.P. Li, and J.P. Zheng, Metallically conductive TiB₂ as a multi-functional separator modifier for improved lithium sulfur batteries, J. Power Sources, 448(2020), art. No. 227336.

[23]	Ding JC, Zhang TF, Yun JM, Kim KH, Wang QM. Effect of Cu addition on the microstructure and properties of TiB₂ films deposited by a hybrid system combining high power impulse magnetron sputtering and pulsed dc magnetron sputtering. Surf. Coat. Technol, 2018, 344, 441.

[24]	Li CC, Liu XB, Zhu L, Huang RZ, Zhao MW, Xu LQ, Qian YT. Conductive and polar titanium boride as a sulfur host for advanced lithium—sulfur batteries. Chem. Mater., 2018, 30(20): 6969.

[25]	Song JY, Lee HH, Wang YY, Wan CC. Two- and three-electrode impedance spectroscopy of lithium-ion batteries. J. Power Sources, 2002, 111(2): 255.

[26]	Sen S, Muthe KP, Joshi N, Gadkari SC, Gupta SK, Jagannath Roy M, Deshpande SK, Yakhmi JV. Room temperature operating ammonia sensor based on tellurium thin films. Sens. Actuators B, 2004, 98(2–3): 154.