Recent advances in cathode catalysts for room-temperature Na-S batteries

doi:10.19799/j.cnki.2095-4239.2023.0687

Abstract

Abstract:

Room-temperature sodium-sulfur (RT Na-S) battery is regarded as a highly competitive electrochemical energy storage system because of the abundant natural resources, low cost, and excellent energy density. However, the serious shuttle effect and sluggish reaction kinetics are two major obstacles restricting the sustainable development and practical applications of RT Na-S batteries. Incorporating suitable catalysts into sulfur cathodes is widely proved as an effective strategy to inhibit the shuttle effect of polysulfides and promote their redox kinetics, thus becoming the research focus in this field. In this review, mainstream catalysts for sulfur cathodes in RT Na-S batteries are first summarized from the perspective of materials design and optimization, including metals, metal oxides, metal sulfides, metal nitrides, metal carbides, MXenes, single atoms, and others. Then, various effective strategies to regulate adsorption and catalysis properties are discussed, involving size tailoring, defect engineering, electrochemical sodiation, and heterostructure engineering. Finally, the future development tendency of catalysts is pointed out based on their research status, and prospects regarding future developmental directions of RT Na-S batteries are offered in view of the major challenges facing RT Na-S batteries, involving two aspects of fundamental research and practical design.

Key words: room-temperature Na-S batteries, shuttle effect, catalyst, kinetics

CLC Number:

TM 911

Xianglong HUANG, Yi LI, Maowen XU. Recent advances in cathode catalysts for room-temperature Na-S batteries[J]. Energy Storage Science and Technology, 2024, 13(1): 231-239.

Figures/Tables 5

Fig. 1

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Fig. 3

Table 1

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References 64

1	WANG Y X, LAI W H, CHOU S L, et al. Sodium-sulfur batteries: Remedies for polysulfide dissolution in room-temperature sodium-sulfur batteries[J]. Advanced Materials, 2020, 32(18): 1903952.
2	JIN F, WANG B, WANG J L, et al. Boosting electrochemical kinetics of S cathodes for room temperature Na/S batteries[J]. Matter, 2021, 4(6): 1768-1800.
3	ZHANG S P, YAO Y, YU Y. Frontiers for room-temperature sodium-sulfur batteries[J]. ACS Energy Letters, 2021, 6(2): 529-536.
4	HUANG X L, WANG Y X, CHOU S L, et al. Materials engineering for adsorption and catalysis in room-temperature Na-S batteries[J]. Energy & Environmental Science, 2021, 14(7): 3757-3795.
5	WU C, LAI W H, CAI X L, et al. Carbonaceous hosts for sulfur cathode in alkali-metal/S (alkali metal=lithium, sodium, potassium) batteries[J]. Small, 2021, 17(48): 2006504.
6	WANG Y, HUANG X L, LIU H W, et al. Nanostructure engineering strategies of cathode materials for room-temperature Na-S batteries[J]. ACS Nano, 2022, 16(4): 5103-5130.
7	LEI Y J, LIU H W, YANG Z, et al. A review on the status and challenges of cathodes in room-temperature Na-S batteries[J]. Advanced Functional Materials, 2023, 33(11): 2212600.
8	WANG P Y, SUN S M, RUI X H, et al. Polar electrocatalysts for preventing polysulfide migration and accelerating redox kinetics in room-temperature sodium-sulfur batteries[J]. Small Methods, 2023, 7(6): 2201728.
9	HUANG X L, DOU S X, WANG Z M. Metal-based electrocatalysts for room-temperature Na-S batteries[J]. Materials Horizons, 2021, 8(11): 2870-2885.
10	ZHOU J H, XU S M, YANG Y E. Strategies for polysulfide immobilization in sulfur cathodes for room-temperature sodium-sulfur batteries[J]. Small, 2021, 17(32): 2100057.
11	ZHANG B W, SHENG T, LIU Y D, et al. Atomic cobalt as an efficient electrocatalyst in sulfur cathodes for superior room-temperature sodium-sulfur batteries[J]. Nature Communications, 2018, 9: 4082.
12	YANG H L, ZHOU S, ZHANG B W, et al. Architecting freestanding sulfur cathodes for superior room-temperature Na-S batteries[J]. Advanced Functional Materials, 2021, 31(32): 2102280.
13	MOU J R, LI Y J, LIU T, et al. Metal-organic frameworks-derived nitrogen-doped porous carbon nanocubes with embedded co nanoparticles as efficient sulfur immobilizers for room temperature sodium-sulfur batteries[J]. Small Methods, 2021, 5(8): 2100455.
14	GUO B S, DU W Y, YANG T T, et al. Nickel hollow spheres concatenated by nitrogen-doped carbon fibers for enhancing electrochemical kinetics of sodium-sulfur batteries[J]. Advanced Science, 2020, 7(4): 1902617.
15	ZHANG B W, SHENG T A, WANG Y X, et al. Long-life room-temperature sodium-sulfur batteries by virtue of transition-metal-nanocluster-sulfur interactions[J]. Angewandte Chemie International Edition, 2019, 58(5): 1484-1488.
16	WANG N N, WANG Y X, BAI Z C, et al. High-performance room-temperature sodium-sulfur battery enabled by electrocatalytic sodium polysulfides full conversion[J]. Energy & Environmental Science, 2020, 13(2): 562-570.
17	YAN Z C, TIAN Q, LIANG Y R, et al. Electrochemical release of catalysts in nanoreactors for solid sulfur redox reactions in room-temperature sodium-sulfur batteries[J]. Cell Reports Physical Science, 2021, 2(8): 100539.
18	LIU Y P, MA S Y, ROSEBROCK M, et al. Tungsten nanoparticles accelerate polysulfides conversion: A viable route toward stable room-temperature sodium-sulfur batteries[J]. Advanced Science, 2022, 9(11): 2105544.
19	WANG L F, WANG H Y, ZHANG S P, et al. Manipulating the electronic structure of nickel via alloying with iron: Toward high-kinetics sulfur cathode for Na-S batteries[J]. ACS Nano, 2021, 15(9): 15218-15228.
20	MA D T, LI Y L, YANG J B, et al. New strategy for polysulfide protection based on atomic layer deposition of TiO₂ onto ferroelectric-encapsulated cathode: Toward ultrastable free-standing room temperature sodium-sulfur batteries[J]. Advanced Functional Materials, 2018, 28(11): 1705537.
21	ZHOU J H, YANG Y E, ZHANG Y C, et al. Sulfur in amorphous silica for an advanced room-temperature sodium-sulfur battery[J]. Angewandte Chemie International Edition, 2021, 60(18): 10129-10136.
22	SAROHA R, HEO J, LIU Y, et al. V₂O₃-decorated carbon nanofibers as a robust interlayer for long-lived, high-performance, room-temperature sodium-sulfur batteries[J]. Chemical Engineering Journal, 2022, 431: 134205.
23	DU W Y, WU Y K, YANG T T, et al. Rational construction of rGO/VO₂ nanoflowers as sulfur multifunctional hosts for room temperature Na-S batteries[J]. Chemical Engineering Journal, 2020, 379: 122359.
24	ZHANG H, SONG B, ZHANG W W, et al. Bidirectional tandem electrocatalysis manipulated sulfur speciation pathway for high-capacity and stable Na-S battery[J]. Angewandte Chemie International Edition, 2023, 62(6): e202217009.
25	ZHANG C Y, LU X, HAN X, et al. Identifying the role of the cationic geometric configuration in spinel catalysts for polysulfide conversion in sodium-sulfur batteries[J]. Journal of the American Chemical Society, 2023, 145(34): 18992-19004.
26	HUANG X L, ZHANG X F, ZHOU L J, et al. Orthorhombic Nb₂O₅ decorated carbon nanoreactors enable bidirectionally regulated redox behaviors in room-temperature Na-S batteries[J]. Advanced Science, 2023, 10(4): 2212600.
27	ZHANG C Y, GONG L, ZHANG C Q, et al. Sodium-sulfur batteries with unprecedented capacity, cycling stability and operation temperature range enabled by a CoFe₂O₄ catalytic additive under an external magnetic field[J]. Advanced Functional Materials, 2023, 33(48): 2305908.
28	YE X, LUO S N, LI Z Q, et al. Engineering CoMoO₄ in reduced graphene oxide as superior cathode hosts for advanced room-temperature sodium-sulfur batteries[J]. Journal of Energy Chemistry, 2023, 86: 620-627.
29	ASLAM M K, SEYMOUR I D, KATYAL N, et al. Metal chalcogenide hollow polar bipyramid prisms as efficient sulfur hosts for Na-S batteries[J]. Nature Communications, 2020, 11: 5242.
30	WANG Y X, LAI Y Y, CHU J, et al. Tunable electrocatalytic behavior of sodiated MoS₂ active sites toward efficient sulfur redox reactions in room-temperature Na-S batteries[J]. Advanced Materials, 2021, 33(16): 2100229.
31	ZHANG R X, ESPOSITO A M, THORNBURG E S, et al. Conversion of co nanoparticles to CoS in metal-organic framework-derived porous carbon during cycling facilitates Na₂S reactivity in a Na-S battery[J]. ACS Applied Materials & Interfaces, 2020: acsami.0c05370.
32	MA C S, WANG X A, LAN J Q, et al. Dynamic multistage coupling of FeS₂/S enables ultrahigh reversible Na-S batteries[J]. Advanced Functional Materials, 2023, 33(5): 2211821.
33	WANG H M, DENG C, LI X L, et al. Designing dual-defending system based on catalytic and kinetic iron Pyrite@C hybrid fibers for long-life room-temperature sodium-sulfur batteries[J]. Chemical Engineering Journal, 2021, 420: 129681.
34	YAN Z C, XIAO J, LAI W H, et al. Nickel sulfide nanocrystals on nitrogen-doped porous carbon nanotubes with high-efficiency electrocatalysis for room-temperature sodium-sulfur batteries[J]. Nature Communications, 2019, 10: 4793.
35	WU Y, XU Q, HUANG L, et al. Encapsulation of sulfur in MoS₂-modified metal-organic framework-derived N, O-codoped carbon host for sodium-sulfur batteries[J]. Journal of Colloid and Interface Science, 2024, 654: 649-659.
36	YAN Z C, LIANG Y R, XIAO J, et al. A high-kinetics sulfur cathode with a highly efficient mechanism for superior room-temperature Na-S batteries[J]. Advanced Materials, 2020, 32(8): 1906700.
37	QI Y R, LI Q J, WU Y K, et al. A Fe₃N/carbon composite electrocatalyst for effective polysulfides regulation in room-temperature Na-S batteries[J]. Nature Communications, 2021, 12: 6347.
38	LI Z, WANG C L, LING F X, et al. Room-temperature sodium-sulfur batteries: Rules for catalyst selection and electrode design[J]. Advanced Materials, 2022, 34(32): 2204214.
39	ASLAM M K, HUSSAIN T, TABASSUM H, et al. Sulfur encapsulation into yolk-shell Fe₂N@nitrogen doped carbon for ambient-temperature sodium-sulfur battery cathode[J]. Chemical Engineering Journal, 2022, 429: 132389.
40	LI Y, WANG X Z, SUN M H, et al. Co₄N embedded nitrogen doped carbon with 2D/3D hybrid structure as sulfur host for room-temperature sodium-sulfur batteries[J]. Electrochimica Acta, 2023, 451: 142288.
41	YE C, JIN H Y, SHAN J Q, et al. A Mo₅N₆ electrocatalyst for efficient Na₂S electrodeposition in room-temperature sodium-sulfur batteries[J]. Nature Communications, 2021, 12: 7195.
42	TANG W W, ZHONG W, WU Y K, et al. Vanadium carbide nanoparticles incorporation in carbon nanofibers for room-temperature sodium sulfur batteries: Confining, trapping, and catalyzing[J]. Chemical Engineering Journal, 2020, 395: 124978.
43	ZHOU X F, YU Z X, YAO Y, et al. A high-efficiency Mo₂ C electrocatalyst promoting the polysulfide redox kinetics for Na-S batteries[J]. Advanced Materials, 2022, 34(14): e2200479.
44	HAO H C, WANG Y X, KATYAL N, et al. Molybdenum carbide electrocatalyst in situ embedded in porous nitrogen-rich carbon nanotubes promotes rapid kinetics in sodium-metal-sulfur batteries[J]. Advanced Materials, 2022, 34(26): 2106572.
45	MOU J R, LI Y J, OU L Q, et al. A highly-efficient electrocatalyst for room temperature sodium-sulfur batteries: Assembled nitrogen-doped hollow porous carbon spheres decorated with ultrafine α-MoC_1- x nanoparticles[J]. Energy Storage Materials, 2022, 52: 111-119.
46	BAO W Z, WANG R H, QIAN C F, et al. Porous heteroatom-doped Ti₃C₂Tx MXene microspheres enable strong adsorption of sodium polysulfides for long-life room-temperature sodium-sulfur batteries[J]. ACS Nano, 2021, 15(10): 16207-16217.
47	JIANG Y, YU Z X, ZHOU X F, et al. Single-atom vanadium catalyst boosting reaction kinetics of polysulfides in Na-S batteries[J]. Advanced Materials, 2023, 35(8): 2208873.
48	ZHANG B W, CAO L Y, TANG C, et al. Atomically dispersed dual-site cathode with a record high sulfur mass loading for high-performance room-temperature sodium-sulfur batteries[J]. Advanced Materials, 2023, 35(1): 2206828.
49	BAI R L, LIN Q S, LI X Y, et al. Toward complete transformation of sodium polysulfides by regulating the second-shell coordinating environment of atomically dispersed Fe[J]. Angewandte Chemie International Edition, 2023, 62(26): e202218165.
50	XIAO F P, WANG H K, XU J, et al. Generating short-chain sulfur suitable for efficient sodium-sulfur batteries via atomic copper sites on a N, O-codoped carbon composite[J]. Advanced Energy Materials, 2021, 11(26): 2100989.
51	LIU H W, LAI W H, LIANG Y R, et al. Sustainable S cathodes with synergic electrocatalysis for room-temperature Na-S batteries[J]. Journal of Materials Chemistry A, 2021, 9(1): 566-574.
52	FANG D L, GHOSH T, HUANG S Z, et al. Core-shell tandem catalysis coupled with interface engineering for high-performance room-temperature Na-S batteries[J]. Small, 2023, 19(41): 2302461.
53	ZHANG E H, HU X A, MENG L Z, et al. Single-atom yttrium engineering Janus electrode for rechargeable Na-S batteries[J]. Journal of the American Chemical Society, 2022, 144(41): 18995-19007.
54	HUANG Z P, SONG B, ZHANG H, et al. High-capacity and stable sodium-sulfur battery enabled by confined electrocatalytic polysulfides full conversion[J]. Advanced Functional Materials, 2021, 31(17): 2100666.
55	GHOSH A, KUMAR A, DAS T, et al. Lewis acid-base interactions between polysulfides and boehmite enables stable room-temperature sodium-sulfur batteries[J]. Advanced Functional Materials, 2020, 30(50): 2005669.
56	HE J R, BHARGAV A, SU L S, et al. Intercalation-type catalyst for non-aqueous room temperature sodium-sulfur batteries[J]. Nature Communications, 2023, 14(1): 6568.
57	MA Q Y, ZOU H D, HE H L, et al. Enhanced conversion kinetics by constructing boron and nitrogen co-doped porous carbon with sulfurophilic and sodiophilic sites in room-temperature sodium-sulfur batteries[J]. Chemical Engineering Journal, 2023, 474: 145954.
58	YUAN H, ZHANG Y W. Role of ferroelectric In₂Se₃ in polysulfide shuttling and charging/discharging kinetics in lithium/sodium-sulfur batteries[J]. ACS Applied Materials & Interfaces, 2022, 14(14): 16178-16184.
59	KONG F, CHEN L, YANG M R, et al. Investigation of the anchoring and electrocatalytic properties of pristine and doped borophosphene for Na-S batteries[J]. Physical Chemistry Chemical Physics, 2023, 25(7): 5443-5452.
60	JAYAN R, ISLAM M M. Mechanistic insights into interactions of polysulfides at VS₂ interfaces in Na-S batteries: A DFT study[J]. ACS Applied Materials & Interfaces, 2021, 13(30): 35848-35855.
61	KUMAR A, GHOSH A, GHOSH A, et al. Sub-zero and room-temperature sodium-sulfur battery cell operations: A rational current collector, catalyst and sulphur-host design and study[J]. Energy Storage Materials, 2021, 42: 608-617.
62	LUO S N, RUAN J F, WANG Y, et al. Flower-like interlayer-expanded MoS_2- x nanosheets confined in hollow carbon spheres with high-efficiency electrocatalysis sites for advanced sodium-sulfur battery[J]. Small, 2021, 17(37): 2101879.
63	QIAN S Y, YUAN Z Y, LI G S, et al. 3D layered structure Ti₃C₂Tx MXene/Ni(OH)₂/C with strong catalytic and adsorption capabilities of polysulfides for high-capacity sodium-sulfur battery[J]. Chemical Engineering Journal, 2023, 471: 144528.
64	YE X, RUAN J F, PANG Y P, et al. Enabling a stable room-temperature sodium-sulfur battery cathode by building heterostructures in multichannel carbon fibers[J]. ACS Nano, 2021, 15(3): 5639-5648.

催化剂	催化剂含量/%	倍率能力/(A/g)/(mAh/g)	循环性能
催化剂	催化剂含量/%	倍率能力/(A/g)/(mAh/g)	电流密度/(A/g)	循环寿命(n)	容量剩余/(mAh/g)
Co^[12]	15.7	8.375/240	0.8375	600	398
Nb₂O₅^[25]	16.8	2/405	0.5	600	617
FeS₂^[36]	14.5	1/395	0.1	300	524
Fe₃N^[37]	11	16.75/650	8.375	2800	698.7
Ti₃C₂T _x^[46]	—	8.375/550.6	3.35	500	577
Y-N₄^[53]	—	10/516	5	1000	510
TiN-TiO₂^[64]	—	5/440.2	5	1000	257.1

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