Chemical Industry and Engineering Progress ›› 2021, Vol. 40 ›› Issue (9): 4837-4852.DOI: 10.16085/j.issn.1000-6613.2021-0745
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ZHU Sheng(), PENG Yiting, MIN Yulin, LIU Haimei, XU Qunjie()
Received:
2021-04-09
Revised:
2021-06-24
Online:
2021-09-13
Published:
2021-09-05
Contact:
XU Qunjie
通讯作者:
徐群杰
作者简介:
朱晟(1984—),男,讲师,研究方向为能源转换材料。E-mail:基金资助:
CLC Number:
ZHU Sheng, PENG Yiting, MIN Yulin, LIU Haimei, XU Qunjie. Research progress on materials and technologies for electrochemical energy storage[J]. Chemical Industry and Engineering Progress, 2021, 40(9): 4837-4852.
朱晟, 彭怡婷, 闵宇霖, 刘海梅, 徐群杰. 电化学储能材料及储能技术研究进展[J]. 化工进展, 2021, 40(9): 4837-4852.
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1 | 李建林, 孟高军, 葛乐, 等. 全球能源互联网中的储能技术及应用[J]. 电器与能效管理技术, 2020(1): 1-8. |
LI Jianlin, MENG Gaojun, GE Le, et al. Energy storage technology and its application in global energy Internet[J]. Electrical & Energy Management Technology, 2020(1): 1-8. | |
2 | 李雷, 杨春, 谢晓峰. 我国储能产业发展现状、机遇与挑战[J]. 化工进展, 2011, 30(S1): 748-754. |
LI Lei, YANG Chun, XIE Xiaofeng. Current situation, opportunities and challenges of energy storage industry in China[J]. Chemical Industry and Engineering Progress, 2011, 30(S1): 748-754. | |
3 | 孙玉树, 杨敏, 师长立, 等. 储能的应用现状和发展趋势分析[J]. 高电压技术, 2020, 46(1): 80-89. |
SUN Yushu, YANG Min, SHI Changli, et al. Analysis of application status and development trend of energy storage[J]. High Voltage Engineering, 2020, 46(1): 80-89. | |
4 | 张文建, 崔青汝, 李志强, 等. 电化学储能在发电侧的应用[J]. 储能科学与技术, 2020, 9(1): 287-295. |
ZHANG Wenjian, CUI Qingru, LI Zhiqiang, et al. Application of electrochemical energy storage in power generation[J]. Energy Storage Science and Technology, 2020, 9(1): 287-295. | |
5 | 胡静, 黄碧斌, 蒋莉萍, 等. 适应电力市场环境下的电化学储能应用及关键问题[J]. 中国电力, 2020, 53(1): 100-107. |
HU Jing, HUANG Bibin, JIANG Liping, et al. Application and major issues of electrochemical energy storage under the environment of power market[J]. Electric Power, 2020, 53(1): 100-107. | |
6 | 郭松林, 孙博洋, 姚峣, 等. 储能技术及其在新能源并网系统中的典型应用[J]. 工业控制计算机, 2020, 33(11): 142-144, 148. |
GUO Songlin, SUN Boyang,YAO Yao, et al. Energy storage technology and its typical application in new energy grid connection system[J]. Industrial Control Computer, 2020, 33(11): 142-144, 148. | |
7 | 李先锋, 张洪章, 郑琼, 等. 能源革命中的电化学储能技术[J]. 中国科学院院刊, 2019, 34(4): 443-449. |
LI Xianfeng, ZHANG Hongzhang, ZHENG Qiong, et al. Electrochemical energy storage technology in energy revolution[J]. Bulletin of Chinese Academy of Sciences, 2019, 34(4): 443-449. | |
8 | NITTA N, WU F X, LEE J T, et al. Li-ion battery materials: present and future[J]. Materials Today, 2015, 18(5): 252-264. |
9 | KIM H, CHOI W, YOON J, et al. Exploring anomalous charge storage in anode materials for next-generation Li rechargeable batteries[J]. Chemical Reviews, 2020, 120(14): 6934-6976. |
10 | WU F X, MAIER J, YU Y. Guidelines and trends for next-generation rechargeable lithium and lithium-ion batteries[J]. Chemical Society Reviews, 2020, 49(5): 1569-1614. |
11 | GUAN P Y, ZHOU L, YU Z L, et al. Recent progress of surface coating on cathode materials for high-performance lithium-ion batteries[J]. Journal of Energy Chemistry, 2020, 43: 220-235. |
12 | LI M, LU J, CHEN Z W, et al. 30 Years of lithium-ion batteries[J]. Advanced Materials, 2018, 30(33): 1800561. |
13 | GOODENOUGH J B, KIM Y. Challenges for rechargeable Li batteries[J]. Chemistry of Materials, 2010, 22(3): 587-603. |
14 | MANTHIRAM A. A reflection on lithium-ion battery cathode chemistry[J]. Nature Communications, 2020, 11(1): 1550. |
15 | LI M, LIU T C, BI X X, et al. Cationic and anionic redox in lithium-ion based batteries[J]. Chemical Society Reviews, 2020, 49(6): 1688-1705. |
16 | DU M J, LIAO K M, LU Q, et al. Recent advances in the interface engineering of solid-state Li-ion batteries with artificial buffer layers: challenges, materials, construction, and characterization[J]. Energy & Environmental Science, 2019, 12(6): 1780-1804. |
17 | YUAN M Q, LIU K. Rational design on separators and liquid electrolytes for safer lithium-ion batteries[J]. Journal of Energy Chemistry, 2020, 43: 58-70. |
18 | CHENG X B, ZHANG R, ZHAO C Z, et al. Toward safe lithium metal anode in rechargeable batteries: a review[J]. Chemical Reviews, 2017, 117(15): 10403-10473. |
19 | ZHAO Y, WANG L P, SOUGRATI M T, et al. A review on design strategies for carbon based metal oxides and sulfides nanocomposites for high performance Li and Na ion battery anodes[J]. Advanced Energy Materials, 2017, 7(9): 1601424. |
20 | REDDY M V, SUBBA RAO G V, CHOWDARI B V R. Metal oxides and oxysalts as anode materials for Li ion batteries[J]. Chemical Reviews, 2013, 113(7): 5364-5457. |
21 | ZOU F, CHEN Y M, LIU K W, et al. Metal organic frameworks derived hierarchical hollow NiO/Ni/graphene composites for lithium and sodium storage[J]. ACS Nano, 2016, 10(1): 377-386. |
22 | LI H, SU Y, SUN W W, et al. Carbon nanotubes rooted in porous ternary metal Sulfide@N/S-doped carbon dodecahedron: bimetal-organic-frameworks derivation and electrochemical application for high-capacity and long-life lithium-ion batteries[J]. Advanced Functional Materials, 2016, 26(45): 8345-8353. |
23 | LIU J, KOPOLD P, VAN AKEN P A, et al. Energy storage materials from nature through nanotechnology: a sustainable route from reed plants to a silicon anode for lithium-ion batteries[J]. Angewandte Chemie International Edition, 2015, 54(33): 9632-9636. |
24 | JIANG T C, BU F X, FENG X X, et al. Porous Fe2O3 nanoframeworks encapsulated within three-dimensional graphene as high-performance flexible anode for lithium-ion battery[J]. ACS Nano, 2017, 11(5): 5140-5147. |
25 | WU D B, WANG C, WU H J, et al. Synthesis of hollow Co3O4 nanocrystals in situ anchored on holey graphene for high rate lithium-ion batteries[J]. Carbon, 2020, 163: 137-144. |
26 | WEI H H, ZHANG Q, WANG Y, et al. Baby diaper-inspired construction of 3D porous composites for long-term lithium-ion batteries[J]. Advanced Functional Materials, 2018, 28(3): 1704440. |
27 | CROCE F, APPETECCHI G B, PERSI L, et al. Nanocomposite polymer electrolytes for lithium batteries[J]. Nature, 1998, 394(6692): 456-458. |
28 | TIKEKAR M D, ARCHER L A, KOCH D L. Stabilizing electrodeposition in elastic solid electrolytes containing immobilized anions[J]. Science Advances, 2016, 2(7): e1600320. |
29 | WU B B, WANG S Y, EVANS W J, et al. Interfacial behaviours between lithium ion conductors and electrode materials in various battery systems[J]. Journal of Materials Chemistry A, 2016, 4(40): 15266-15280. |
30 | MAO X F, SHI L Y, ZHANG H J, et al. Polyethylene separator activated by hybrid coating improving Li+ ion transference number and ionic conductivity for Li-metal battery[J]. Journal of Power Sources, 2017, 342: 816-824. |
31 | ZHANG T W, CHEN J L, TIAN T, et al. Sustainable separators for high-performance lithium ion batteries enabled by chemical modifications[J]. Advanced Functional Materials, 2019, 29(28): 1902023. |
32 | ZHANG C, SHEN L, SHEN J Q, et al. Anion-sorbent composite separators for high-rate lithium-ion batteries[J]. Advanced Materials, 2019, 31(21): 1808338. |
33 | ZHANG X H, ZOU L F, XU Y B, et al. Advanced electrolytes for fast-charging high-voltage lithium-ion batteries in wide-temperature range[J]. Advanced Energy Materials, 2020, 10(22): 2000368. |
34 | KIM J, LEE J, MA H, et al. Controllable solid electrolyte interphase in nickel-rich cathodes by an electrochemical rearrangement for stable lithium-ion batteries[J]. Advanced Materials, 2018, 30(5): 1704309. |
35 | WIEMERS-MEYER S, JEREMIAS S, WINTER M, et al. Influence of battery cell components and water on the thermal and chemical stability of LiPF6 based lithium ion battery electrolytes[J]. Electrochimica Acta, 2016, 222: 1267-1271. |
36 | PIECZONKA N P W, LIU Z Y, LU P, et al. Understanding transition-metal dissolution behavior in LiNi0.5Mn1.5O4 high-voltage spinel for lithium ion batteries[J]. The Journal of Physical Chemistry C, 2013, 117(31): 15947-15957. |
37 | ZHAO W M, ZHENG B Z, LIU H D, et al. Toward a durable solid electrolyte film on the electrodes for Li-ion batteries with high performance[J]. Nano Energy, 2019, 63: 103815. |
38 | LIAO B, LI H Y, XU M Q, et al. Designing low impedance interface films simultaneously on anode and cathode for high energy batteries[J]. Advanced Energy Materials, 2018, 8(22): 1800802. |
39 | CHEN Y, ZHAO W M, ZHANG Q H, et al. Armoring LiNi1/3Co1/3Mn1/3O2 cathode with reliable fluorinated organic-inorganic hybrid interphase layer toward durable high rate battery[J]. Advanced Functional Materials, 2020, 30(19): 2000396. |
40 | BRUCE P G, FREUNBERGER S A, HARDWICK L J, et al. Li-O2 and Li-S batteries with high energy storage[J]. Nature Materials, 2012, 11(1): 19-29. |
41 | ZHOU B, GUO L M, ZHANG Y T, et al. A high-performance Li-O2 battery with a strongly solvating hexamethylphosphoramide electrolyte and a LiPON-protected lithium anode[J]. Advanced Materials, 2017, 29(30): 1701568. |
42 | JIN S, SUN Z W, GUO Y L, et al. High areal capacity and lithium utilization in anodes made of covalently connected graphite microtubes[J]. Advanced Materials, 2017, 29(38): 1700783. |
43 | LIANG X, PANG Q, KOCHETKOV I R, et al. A facile surface chemistry route to a stabilized lithium metal anode[J]. Nature Energy, 2017, 2: 17119. |
44 | LIN D C, LIU Y Y, CUI Y. Reviving the lithium metal anode for high-energy batteries[J]. Nature Nanotechnology, 2017, 12(3): 194-206. |
45 | FAN L, ZHUANG H L, ZHANG W D, et al. Stable lithium electrodeposition at ultra-high current densities enabled by 3D PMF/Li composite anode[J]. Advanced Energy Materials, 2018, 8(15): 1703360. |
46 | CHI S S, LIU Y C, SONG W L, et al. Prestoring lithium into stable 3D nickel foam host as dendrite-free lithium metal anode[J]. Advanced Functional Materials, 2017, 27(24): 1700348. |
47 | ZHAO H, LEI D N, HE Y B, et al. Compact 3D copper with uniform porous structure derived by electrochemical dealloying as dendrite-free lithium metal anode current collector[J]. Advanced Energy Materials, 2018, 8(19): 1800266. |
48 | HUANG K, LI Z, XU Q J, et al. Lithiophilic CuO nanoflowers on Ti-mesh inducing lithium lateral plating enabling stable lithium-metal anodes with ultrahigh rates and ultralong cycle life[J]. Advanced Energy Materials, 2019, 9(29): 1900853. |
49 | YABUUCHI N, KUBOTA K, DAHBI M, et al. Research development on sodium-ion batteries[J]. Chemical Reviews, 2014, 114(23): 11636-11682. |
50 | FANG Y J, YU X Y, LOU X W. Nanostructured electrode materials for advanced sodium-ion batteries[J]. Matter, 2019, 1(1): 90-114. |
51 | 朱子翼, 董鹏, 张举峰, 等. 新一代储能钠离子电池正极材料的改性研究进展[J]. 化工进展, 2020, 39(3): 1043-1056. |
ZHU Ziyi, DONG Peng, ZHANG Jufeng, et al. Research progress on modification of cathode materials for new generation energy storage sodium-ion batteries[J]. Chemical Industry and Engineering Progress, 2020, 39(3): 1043-1056. | |
52 | TAN H T, CHEN D, RUI X H, et al. Peering into alloy anodes for sodium-ion batteries: current trends, challenges, and opportunities[J]. Advanced Functional Materials, 2019, 29(14): 1808745. |
53 | LIU Y, ZHOU Y R, ZHANG J X, et al. Monoclinic phase Na3Fe2(PO4)3: synthesis, structure, and electrochemical performance as cathode material in sodium-ion batteries[J]. ACS Sustainable Chemistry & Engineering, 2017, 5(2): 1306-1314. |
54 | KIM J, SEO D H, KIM H, et al. Unexpected discovery of low-cost maricite NaFePO4 as a high-performance electrode for Na-ion batteries[J]. Energy & Environmental Science, 2015, 8(2): 540-545. |
55 | KOSOVA N V, BELOTSERKOVSKY V A. Sodium and mixed sodium/lithium iron ortho-pyrophosphates: synthesis, structure and electrochemical properties[J]. Electrochimica Acta, 2018, 278: 182-195. |
56 | KIM H, PARK I, LEE S, et al. Understanding the electrochemical mechanism of the new iron-based mixed-phosphate Na4Fe3(PO4)2(P2O7) in a Na rechargeable battery[J]. Chemistry of Materials, 2013, 25(18): 3614-3622. |
57 | WU X H, ZHONG G M, YANG Y. Sol-gel synthesis of Na4Fe3(PO4)2(P2O7)/C nanocomposite for sodium ion batteries and new insights into microstructural evolution during sodium extraction[J]. Journal of Power Sources, 2016, 327: 666-674. |
58 | YUAN T C, WANG Y X, ZHANG J X, et al. 3D graphene decorated Na4Fe3(PO4)2(P2O7) microspheres as low-cost and high-performance cathode materials for sodium-ion batteries[J]. Nano Energy, 2019, 56: 160-168. |
59 | CHEN M Z, HUA W B, XIAO J, et al. NASICON-type air-stable and all-climate cathode for sodium-ion batteries with low cost and high-power density[J]. Nature Communications, 2019, 10: 1480. |
60 | CAO Y J, YANG C, LIU Y, et al. A new polyanion Na3Fe2(PO4)P2O7 cathode with high electrochemical performance for sodium-ion batteries[J]. ACS Energy Letters, 2020, 5(12): 3788-3796. |
61 | XU Z L, LIM K, PARK K Y, et al. Engineering solid electrolyte interphase for pseudocapacitive anatase TiO2 anodes in sodium-ion batteries[J]. Advanced Functional Materials, 2018, 28(29): 1802099. |
62 | LIU Y, LIU J Y, BIN D, et al. Ultrasmall TiO2-coated reduced graphene oxide composite as a high-rate and long-cycle-life anode material for sodium-ion batteries[J]. ACS Applied Materials & Interfaces, 2018, 10(17): 14818-14826. |
63 | HE H N, WANG H Y, SUN D, et al. N-doped rutile TiO2/C with significantly enhanced Na storage capacity for Na-ion batteries[J]. Electrochimica Acta, 2017, 236: 43-52. |
64 | LI B S, XI B J, FENG Z Y, et al. Hierarchical porous nanosheets constructed by graphene-coated, interconnected TiO2 nanoparticles for ultrafast sodium storage[J]. Advanced Materials, 2018, 30(10): 1705788. |
65 | SUI Y L, ZHOU J, WANG X W, et al. Recent advances in black-phosphorus-based materials for electrochemical energy storage[J]. Materials Today, 2021, 42: 117-136. |
66 | NA J H, LEE Y T, LIM J A, et al. Few-layer black phosphorus field-effect transistors with reduced current fluctuation[J]. ACS Nano, 2014, 8(11): 11753-11762. |
67 | ZHANG Y, WANG H W, LUO Z Z, et al. An air-stable densely packed phosphorene-graphene composite toward advanced lithium storage properties[J]. Advanced Energy Materials, 2016, 6(12): 1600453. |
68 | ZHAO Y T, WANG H Y, HUANG H, et al. Surface coordination of black phosphorus for robust air and water stability[J]. Angewandte Chemie International Edition, 2016, 55(16): 5003-5007. |
69 | SUN J, LEE H W, PASTA M, et al. A phosphorene-graphene hybrid material as a high-capacity anode for sodium-ion batteries[J]. Nature Nanotechnology, 2015, 10(11): 980-985. |
70 | ZHANG Y, SUN W P, LUO Z Z, et al. Functionalized few-layer black phosphorus with super-wettability towards enhanced reaction kinetics for rechargeable batteries[J]. Nano Energy, 2017, 40: 576-586. |
71 | SONG T B, CHEN H, LI Z, et al. Creating an air-stable sulfur-doped black phosphorus-TiO2 composite as high-performance anode material for sodium-ion storage[J]. Advanced Functional Materials, 2019, 29(22): 1900535. |
72 | LAN F Y, ZHANG H Y, FAN J C, et al. Electrospun polymer nanofibers with TiO2@NiCo-LDH as efficient polysulfide barriers for wide-temperature-range Li-S batteries[J]. ACS Applied Materials & Interfaces, 2021, 13(2): 2734-2744. |
73 | XIE J, LI B Q, PENG H J, et al. Implanting atomic cobalt within mesoporous carbon toward highly stable lithium-sulfur batteries[J]. Advanced Materials, 2019, 31(43): 1903813. |
74 | XUE W J, SHI Z, SUO L M, et al. Intercalation-conversion hybrid cathodes enabling Li-S full-cell architectures with jointly superior gravimetric and volumetric energy densities[J]. Nature Energy, 2019, 4(5): 374-382. |
75 | DU Z Z, CHEN X J, HU W, et al. Cobalt in nitrogen-doped graphene as single-atom catalyst for high-sulfur content lithium-sulfur batteries[J]. Journal of the American Chemical Society, 2019, 141(9): 3977-3985. |
76 | SEH Z W, SUN Y M, ZHANG Q F, et al. Designing high-energy lithium-sulfur batteries[J]. Chemical Society Reviews, 2016, 45(20): 5605-5634. |
77 | 陈嘉嘉, 董全峰. 锂硫电池及关键材料研究进展[J]. 电化学, 2020, 26(5): 648-662. |
CHEN Jiajia, DONG Quanfeng. Research progress of key components in lithium-sulfur batteries[J]. Journal of Electrochemistry, 2020, 26(5): 648-662. | |
78 | JI X L, LEE K T, NAZAR L F. A highly ordered nanostructured carbon-sulphur cathode for lithium-sulphur batteries[J]. Nature Materials, 2009, 8(6): 500-506. |
79 | SONG J X, GORDIN M L, XU T, et al. Strong lithium polysulfide chemisorption on electroactive sites of nitrogen-doped carbon composites for high-performance lithium-sulfur battery cathodes[J]. Angewandte Chemie International Edition, 2015, 54(14): 4325-4329. |
80 | TANG C, ZHANG Q, ZHAO M Q, et al. Nitrogen-doped aligned carbon nanotube/graphene sandwiches: facile catalytic growth on bifunctional natural catalysts and their applications as scaffolds for high-rate lithium-sulfur batteries[J]. Advanced Materials, 2014, 26(35): 6100-6105. |
81 | ZHENG J M, TIAN J, WU D X, et al. Lewis acid-base interactions between polysulfides and metal organic framework in lithium sulfur batteries[J]. Nano Letters, 2014, 14(5): 2345-2352. |
82 | PANG Q, NAZAR L F. Long-life and high-areal-capacity Li-S batteries enabled by a light-weight polar host with intrinsic polysulfide adsorption[J]. ACS Nano, 2016, 10(4): 4111-4118. |
83 | LIANG X, GARSUCH A, NAZAR L F. Sulfur cathodes based on conductive MXene nanosheets for high-performance lithium-sulfur batteries[J]. Angewandte Chemie International Edition, 2015, 54(13): 3907-3911. |
84 | CUI Z M, ZU C X, ZHOU W D, et al. Mesoporous titanium nitride-enabled highly stable lithium-sulfur batteries[J]. Advanced Materials, 2016, 28(32): 6926-6931. |
85 | TAO Y Q, WEI Y J, LIU Y, et al. Kinetically-enhanced polysulfide redox reactions by Nb2O5 nanocrystals for high-rate lithium-sulfur battery[J]. Energy & Environmental Science, 2016, 9(10): 3230-3239. |
86 | YUAN Z, PENG H J, HOU T Z, et al. Powering lithium-sulfur battery performance by propelling polysulfide redox at sulfiphilic hosts[J]. Nano Letters, 2016, 16(1): 519-527. |
87 | REHMAN S, TANG T Y, ALI Z, et al. Integrated design of MnO2@carbon hollow nanoboxes to synergistically encapsulate polysulfides for empowering lithium sulfur batteries[J]. Small, 2017, 13(20): 1700087. |
88 | WANG Y K, ZHANG R F, CHEN J, et al. Enhancing catalytic activity of titanium oxide in lithium-sulfur batteries by band engineering[J]. Advanced Energy Materials, 2019, 9(24): 1900953. |
89 | ZHANG Y P, GU R, ZHENG S, et al. Long-life Li-S batteries based on enabling the immobilization and catalytic conversion of polysulfides[J]. Journal of Materials Chemistry A, 2019, 7(38): 21747-21758. |
90 | LIU F, XIAO Q F, WU H B, et al. Regenerative polysulfide-scavenging layers enabling lithium-sulfur batteries with high energy density and prolonged cycling life[J]. ACS Nano, 2017, 11(3): 2697-2705. |
91 | KONG W B, YAN L J, LUO Y F, et al. Ultrathin MnO2/graphene oxide/carbon nanotube interlayer as efficient polysulfide-trapping shield for high-performance Li-S batteries[J]. Advanced Functional Materials, 2017, 27(18): 1606663. |
92 | ZHAO T, YE Y S, LAO C Y, et al. A praline-like flexible interlayer with highly mounted polysulfide anchors for lithium-sulfur batteries[J]. Small, 2017, 13(40): 1700357. |
93 | GHAZI Z A, HE X, KHATTAK A M, et al. MoS2/celgard separator as efficient polysulfide barrier for long-life lithium-sulfur batteries[J]. Advanced Materials, 2017, 29(21): 1606817. |
94 | PARK J, YU B C, PARK J S, et al. Tungsten disulfide catalysts supported on a carbon cloth interlayer for high performance Li-S battery[J]. Advanced Energy Materials, 2017, 7(11): 1602567. |
95 | ZHOU T H, LV W, LI J, et al. Twinborn TiO2-TiN heterostructures enabling smooth trapping-diffusion-conversion of polysulfides towards ultralong life lithium-sulfur batteries[J]. Energy & Environmental Science, 2017, 10(7): 1694-1703. |
96 | ZHANG Z, WANG J N, SHAO A, et al. Recyclable cobalt-molybdenum bimetallic carbide modified separator boosts the polysulfide adsorption-catalysis of lithium sulfur battery[J]. Science China Materials, 2020, 63(12): 2443-2455. |
97 | LI Z, ZHANG F, CAO T, et al. Highly stable lithium-sulfur batteries achieved by a SnS/porous carbon nanosheet architecture modified celgard separator[J]. Advanced Functional Materials, 2020, 30(48): 2006297. |
98 | 陈英放, 李媛媛, 邓梅根. 超级电容器的原理及应用[J]. 电子元件与材料, 2008, 27(4): 6-9. |
CHEN Yingfang, LI Yuanyuan, DENG Meigen. Principles and applications of supercapacitors[J]. Electronic Components and Materials, 2008, 27(4): 6-9. | |
99 | 余丽丽, 朱俊杰, 赵景泰. 超级电容器的现状及发展趋势[J]. 自然杂志, 2015, 37(3): 188-196. |
YU Lili, ZHU Junjie, ZHAO Jingtai. The present situation and development trend of supercapacitors[J]. Chinese Journal of Nature, 2015, 37(3): 188-196. | |
100 | POONAM, SHARMA K, ARORA A, et al. Review of supercapacitors: materials and devices[J]. Journal of Energy Storage, 2019, 21: 801-825. |
101 | RAZA W, ALI F, RAZA N, et al. Recent advancements in supercapacitor technology[J]. Nano Energy, 2018, 52: 441-473. |
102 | ZHAO W W, JIANG M Y, WANG W K, et al. Flexible transparent supercapacitors: materials and devices[J]. Advanced Functional Materials, 2021, 31(11): 2009136. |
103 | FENG E K, GAO W, YAN Z, et al. A multifunctional hydrogel polyelectrolyte based flexible and wearable supercapacitor[J]. Journal of Power Sources, 2020, 479: 229100. |
104 | YUN T G, PARK M, KIM D H, et al. All-transparent stretchable electrochromic supercapacitor wearable patch device[J]. ACS Nano, 2019, 13(3): 3141-3150. |
105 | BOMMIER C, XU R, WANG W, et al. Self-activation of cellulose: a new preparation methodology for activated carbon electrodes in electrochemical capacitors[J]. Nano Energy, 2015, 13: 709-717. |
106 | HAMEDI M, KARABULUT E, MARAIS A, et al. Nanocellulose aerogels functionalized by rapid layer-by-layer assembly for high charge storage and beyond[J]. Angewandte Chemie International Edition, 2013, 52(46): 12038-12042. |
107 | CHMIOLA J, YUSHIN G, GOGOTSI Y, et al. Anomalous increase in carbon capacitance at pore sizes less than 1 nanometer[J]. Science, 2006, 313(5794): 1760-1763. |
108 | PECH D, BRUNET M, DUROU H, et al. Ultrahigh-power micrometre-sized supercapacitors based on onion-like carbon[J]. Nature Nanotechnology, 2010, 5(9): 651-654. |
109 | PARAKNOWITSCH J P, THOMAS A. Doping carbons beyond nitrogen: an overview of advanced heteroatom doped carbons with boron, sulphur and phosphorus for energy applications[J]. Energy & Environmental Science, 2013, 6(10): 2839. |
110 | PENG H R, YAO B, WEI X J, et al. Pore and heteroatom engineered carbon foams for supercapacitors[J]. Advanced Energy Materials, 2019, 9(19): 1803665. |
111 | HSIEH C T, TENG H. Influence of oxygen treatment on electric double-layer capacitance of activated carbon fabrics[J]. Carbon, 2002, 40(5): 667-674. |
112 | QU D Y. Studies of the activated carbons used in double-layer supercapacitors[J]. Journal of Power Sources, 2002, 109(2): 403-411. |
113 | KIM M H, YANG J H, KANG Y M, et al. Fluorinated activated carbon with superb kinetics for the supercapacitor application in nonaqueous electrolyte[J]. Colloids and Surfaces A: Physicochemical and Engineering Aspects, 2014, 443: 535-539. |
114 | WANG T, ZANG X B, WANG X, et al. Recent advances in fluorine-doped/fluorinated carbon-based materials for supercapacitors[J]. Energy Storage Materials, 2020, 30: 367-384. |
115 | ZHOU J S, LIAN J, HOU L, et al. Ultrahigh volumetric capacitance and cyclic stability of fluorine and nitrogen co-doped carbon microspheres[J]. Nature Communications, 2015, 6: 8503. |
116 | ZHOU F, HUANG H B, XIAO C H, et al. Electrochemically scalable production of fluorine-modified graphene for flexible and high-energy ionogel-based microsupercapacitors[J]. Journal of the American Chemical Society, 2018, 140(26): 8198-8205. |
117 | ZHOU H H, PENG Y T, WU H B, et al. Fluorine-rich nanoporous carbon with enhanced surface affinity in organic electrolyte for high-performance supercapacitors[J]. Nano Energy, 2016, 21: 80-89. |
118 | MANTHIRAM A, YU X W, WANG S F. Lithium battery chemistries enabled by solid-state electrolytes[J]. Nature Reviews Materials, 2017, 2: 16103. |
119 | ZHANG Z Z, SHAO Y J, LOTSCH B, et al. New horizons for inorganic solid state ion conductors[J]. Energy & Environmental Science, 2018, 11(8): 1945-1976. |
120 | DUBAL D P, CHODANKAR N R, KIM D H, et al. Towards flexible solid-state supercapacitors for smart and wearable electronics[J]. Chemical Society Reviews, 2018, 47(6): 2065-2129. |
121 | LI J, QIAO J L, LIAN K. Hydroxide ion conducting polymer electrolytes and their applications in solid supercapacitors: a review[J]. Energy Storage Materials, 2020, 24: 6-21. |
122 | HUANG Y, ZHONG M, SHI F K, et al. An intrinsically stretchable and compressible supercapacitor containing a polyacrylamide hydrogel electrolyte[J]. Angewandte Chemie International Edition, 2017, 56(31): 9141-9145. |
123 | LU C, CHEN X. All-temperature flexible supercapacitors enabled by antifreezing and thermally stable hydrogel electrolyte[J]. Nano Letters, 2020, 20(3): 1907-1914. |
124 | TAI Z Y, WEI J J, ZHOU J, et al. Water-mediated crystallohydrate-polymer composite as a phase-change electrolyte[J]. Nature Communications, 2020, 11: 1843. |
125 | TAN D H S, BANERJEE A, CHEN Z, et al. From nanoscale interface characterization to sustainable energy storage using all-solid-state batteries[J]. Nature Nanotechnology, 2020, 15(3): 170-180. |
126 | 邹俊彦, 张焱焱, 陈石, 等. 全固态锂金属电池表界面化学的研究进展[J]. 高等学校化学学报, 2021, 42(4): 1005-1016. |
ZOU Junyan, ZHANG Yanyan, CHEN Shi, et al. Recent development on surface-interface chemistry of all-solid-state lithium batteries[J]. Chemical Journal of Chinese Universities, 2021, 42(4): 1005-1016. | |
127 | KWAK W J, ROSY, SHARON D, et al. Lithium-oxygen batteries and related systems: potential, status, and future[J]. Chemical Reviews, 2020, 120(14): 6626-6683. |
128 | WANG H F, XU Q. Materials design for rechargeable metal-air batteries[J]. Matter, 2019, 1(3): 565-595. |
129 | CHEN M Z, ZHANG Y Y, XING G C, et al. Electrochemical energy storage devices working in extreme conditions[J]. Energy & Environmental Science, 2021, 14(6): 3323-3351. |
130 | ZHAO J X, LU H Y, ZHANG Y, et al. Direct coherent multi-ink printing of fabric supercapacitors[J]. Science Advances, 2021, 7(3): eabd6978. |
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