參考文獻 |
[1] Our World in Data, Global CO2 emissions from fossil fuels, 2021; Available from:
https://ourworldindata.org/co2-emissions
[2] TrendForce’s Department of Green Energy Research. 2022; Available from:
https://www.trendforce.com/presscenter/news/20220728-11319.html
[3] X. Shan, J. Wu, X. Zhang, and L. Wang et al., Wood for Application in Electrochemical Energy Storage Devices, Cell Reports Physical Science, 2, 2021, 100654.
[4] A. A. Kebede, T. Kalogiannisa, and J. V. Mierloa et al., A comprehensive review of stationary energy storage devices for large scale renewable energy sources grid integration, Renewable and Sustainable Energy Reviews, 159, 2022, 112213.
[5] K. Mizushima, P.C. Jones, and J.B. Goodenough et al., LixCoO2 (0 < x < -1): A new cathode material for batteries of high energy density, Materials Research, 15, 1980, 783-789
[6] G. Ceder, Y.M. Chiang, and D.R. Sadoway et al., Identification of cathode materials for lithium batteries guided by first-principles calculations, Nature, 392, 1998, 694-696.
[7] S. Li, K. Wang, and S. Li et al., Fast Charging Anode Materials for Lithium‐Ion Batteries: Current Status and Perspectives. Advanced Functional Materials, 32, 2022, 2200796.
[8] B. Xu, D. Qian, and Z. Wang et al., Recent progress in cathode materials research for advanced lithium ion batteries, Materials Science and Engineering: R: Reports, 73, 2012, 51-65.
[9] M.M. Thackeray, W.I.F. David, and J.B. Goodenough et al., Lithium insertion into manganese spinels, Materials Research Bulletin, 18, 1983, 461-472.
[10] J.B. Goodenough, M.M. Thackeray, and W.I.F. David et al., Lithium insertion/extraction reactions with manganese oxides, Revue de chimie minérale, 21, 1984, 435-455.
[11] W.I.F. David, M.M. Thackeray, and J.B. Goodenough et al., Lithium insertion into βMnO2 and the rutile-spinel transformation, Materials Research Bulletin, 19, 1984, 99–106.
[12] D. Aurbach, M.D. Levi, and K. Gamulski et al., Capacity fading of LixMn2O4 spinel electrodes studied by XRD and electroanalytical techniques, Journal of Power Sources, 81-82, 1999, 472-479.
[13] J.H. Kim, S.T. Myung, and C.S. Yoon et al., Comparative Study of LiNi0.5Mn1.5O4-δ and LiNi0.5Mn1.5O4 Cathodes Having Two Crystallographic Structures: Fd3-m and P4332, Chemistry of Materials, 16, 2004, 906-914.
[14] J. Molenda, J. Marzec, and K. Świerczek et al., The effect of 3d substitutions in the manganese sublattice on the charge transport mechanism and electrochemical properties of manganese spinel, Solid State Ionics, 171, 2004, 215-227.
[15] K. Takahashi, M. Saitoh, and M. Sano et al., Electrochemical and Structural Properties of a 4.7 V-Class LiNi0.5Mn1.5O4 Positive Electrode Material Prepared with a Self-Reaction Method, Journal of the Electrochemical Society, 151, 2004, 173-177.
[16] S.T. Myung, S. Komaba, and N. Kumagai et al., Nano-crystalline LiNi0.5Mn1.5O4 synthesized by emulsion drying method, Electrochimica Acta, 47, 2002, 2543-2549.
[17] H. Cheng, J. G. Shapter, and Y. Li et al., Recent progress of advanced anode materials of lithium-ion batteries, Journal of Energy Chemistry, 57, 2021, 451-468.
[18] Bo Liang, Yanping Liu, and Yunhua Xu et al., Silicon-based materials as high capacity anodes for next generation lithium ion batteries, Journal of Power Sources, 267,2014, 469-490.
[19] S.D. Beattie, M.J. Loveridge, and M.J. Lain et al., Understanding capacity fade in silicon based electrodes for lithium-ion batteries using three electrode cells and upper cut-off voltage studies, Journal of Power Sources, 302, 2016, 426-430.
[20] X. Su, Q. Wu, and J. Li et al., Silicon‐Based Nanomaterials for Lithium‐Ion Batteries: A Review, Advanced Energy Materials, 4, 2014, 1300882.
[21] F. Wu, J. Maier, and Y. Yu et al., Guidelines and trends for next-generation rechargeable lithium and lithium-ion batteries. Chemical Society Reviews, 49, 2020, 1569-1614.
[22] S.S. Zhang, A review on electrolyte additives for lithium-ion batteries. Journal of Power Sources, 244, 2013, 19-28.
[23] P. Arora, Z. (John) Zhang, Battery separators, Chemical reviews,104, 2004, 4419-4462.
[24] Y. Yao, Investigation on a glass fiber-based composite separator for lithium-ion batteries., Journal of Power Sources, 205, 2012, 473-478.
[25] Y. Huang, L. Wang, and J. Xie et al., A review of biodegradable materials for environmentally-friendly lithium-ion batteries. Energy Storage Materials, 30, 2020, 101-121.
[26] P. Zhu, D. Gastol, and J. Marshall et al., A review of current collectors for lithium-ion batteries, Journal of Power Sources, 485, 2021, 229321.
[27] Y. Shi, X. Zhou, and G. Yu et al., Material and Structural Design of Novel Binder Systems for High-Energy, High-Power Lithium-Ion Batteries. Accounts of Chemical Research, 50, 2017, 2642-2652.
[28] P. Parikh, M. Sina, and A. Banerjee et al., Role of Polyacrylic Acid (PAA) Binder on the Solid Electrolyte Interphase in Silicon Anodes, Chemistry of Materials, 31,2019, 2535-2544
[29] J. Xu, S. Dou, and H. Liu et al., Cathode materials for next generation lithium ion batteries, Nano Energy, 2, 2013, 439-442
[30] T. Ohzuku and R.J. Brodd, An Overview of Positive Electrode Materials for Advanced Lithium-Ion Batteries , Journal of Power Sources, 174, 2007, 449-456.
[31] T. Kawamura, A. Kimura, and M. Egashira et al., Thermal stability of alkyl carbonate mixed-solvent electrolytes for lithium ion cells, Journal of Power Sources, 2002, 104, 260-264.
[32] C. Schultz, S. Vedder, and B. Streipert et al., Quantitative investigation of the decomposition of organic lithium ion battery electrolytes with LC-MS/MS. RSC Advances, 7, 2017, 27853-27862.
[33] L. Hanf, J. Henschel, and M. Diehl et al., Mn2+ or Mn3+ ? Investigating transition metal dissolution of manganese species in lithium ion battery electrolytes by capillary electrophoresis, Electrophoresis, 2020, 41, 697-704.
[34] G. Liang, V.K. Peterson, and K.W. See et al., Developing high-voltage spinel LiNi0.5Mn1.5O4 cathodes for high-energy density lithium-ion batteries: current achievements and future prospects, Journal of Materials Chemistry A, 2020, 8, 15373-15398.
[35] J. Wang, M. Yang, and C. Zhao et al., Unveiling the benefits of potassium doping on the structural integrity of Li–Mn-rich layered oxides during prolonged cycling by dual-mode EPR spectroscopy, Physical Chemistry Chemical Physics, 2019, 21, 24017-24025.
[36] K.R. Chemelewski, D.W. Shin, and W. Li et al., Octahedral and Truncated High-Voltage Spinel Cathodes: the Role of Morphology and Surface Planes in Electrochemical Properties, Journal of Materials Chemistry A , 2013, 1, 3347-3354.
[37] Z. Chen, R. Zhao, and P. Du et al., Polyhedral LiNi0.5Mn1.5O4 with Excellent Electrochemical Properties for Lithium-Ion Batteries, Journal of Materials Chemistry A, 2014, 2, 12835-12848.
[38] R. Amin, I. Belharouak, Part-II: exchange current density and ionic diffusivity studies on the ordered and disordered spinel LiNi0.5Mn1.5O4 cathode, Journal of Power Sources, 348 2017, 318–325.
[39] Y.Y. Sun, Y.F. Yang, and H. Zhan et al., Synthesis of high power Type LiMn1.5Ni0.5O4 by optimizing its preparation conditions, Journal of Power Sources, 195, 2010, 4322–4326.
[40] X. Fang, N. Ding, and X.Y. Feng et al., Study of LiNi0.5Mn1.5O4 synthesized via a chloride-ammonia co-precipitation method: electrochemical performance, diffusion coefficient and capacity loss mechanism, Electrochimica Acta, 54, 2009, 7471–7475.
[41] X. Huang, Q. Zhang, and J. Gan et al., Hydrothermal Synthesis of a Nanosized LiNi0.5Mn1.5O4 Cathode Material for High Power Lithium-Ion Batteries, Journal of The Electrochemical Society, 158 ,2011,139-145.
[42] Y. Liu, M. Zhang, and Y. Xia et al., One-step hydrothermal method synthesis of core–shell LiNi0.5Mn1.5O4 spinel cathodes for Li-ion batteries, Journal of Power Sources, 256, 2014, 66-71.
[43] K.M. Shaju and P.G. Bruce, Nano-LiNi0.5Mn1.5O4 spinel: a high power electrode for Li-ion batteries, Dalton Transactions, 40, 2008, 5471–5475.
[44] M. Chen, X. Xiang, and D. Chen et al., Polyethylene glycol-assisted synthesis of hierarchically porous layered lithium-rich oxide as cathode of lithium ion battery, Journal of Power Sources, 279, 2015, 197-204.
[45] Y. Xue, Z. Wang, and F. Yu et al., Ethanol-assisted hydrothermal synthesis of LiNi0.5Mn1.5O4 with excellent long-term cyclability at high rate for lithium-ion batteries. Journal of Materials Chemistry A, 2, 2014, 4185-4191.
[46] H.I. Chen and H.Y. Chang, Homogeneous precipitation of cerium dioxide nanoparticles in alcohol/water mixed solvents, Colloids and Surfaces A: Physicochemical and Engineering Aspects, 242, 2004, 61-69.
[47] J.J. Perry IV, J.A. Permana, and M.J. Zaworotko, Design and synthesis of metal-organic frameworks using metal-organic polyhedra as supermolecular building blocks, Chemical Society Reviews, 38, 2009, 1400-1417.
[48] Y.R. Lee, J. Kim, and W.S. Ahn, Synthesis of metal-organic frameworks: A mini review, Korean Journal of Chemical Engineering, 30, 2013, 1667-1680.
[49] X. Xu, R. Cao, and S. Jeong et al., Spindle-like Mesoporous α-Fe2O3 anode Material Prepared from MOF Template for High-Rate Lithium Batteries, Nano Letters, 12, 2012, 4988-4991.
[50] S. Yang, W. Ren, and J. Chen, Facile synthesis of spinel LiNi0.5Mn1.5O4 cathode materials using M2(OH)2(C8H4O4)-class metal-organic frameworks, Ionics, 23, 2017, 2969-2980.
[51] G.Q. Liu, L. Wen, and Y.M. Liu, Spinel LiNi0.5Mn1.5O4 and its derivatives as cathodes for high-voltage Li-ion batteries. J Journal of Solid State Electrochemistry, 14, 2010, 2191–2202.
[52] S.H. Oh, K.Y. Chung, and S.H. Jeon et al., Structural and electrochemical investigations on the LiNi0.5−xMn1.5−yMx+yO4 (M =Cr, Al, Zr) compound for 5V cathode material, Journal of Alloys and Compounds, 469, 2009, 244-250.
[53] G.B. Zhong, Y.Y. Wang, and Y.Q. Yu et al., Electrochemical investigations of the LiNi0.45M0.10Mn1.45O4 (M=Fe, Co, Cr) 5V cathode materials for lithium ion batteries, Journal of Power Sources, 205, 2012, 385-393.
[54] T.A. Arunkumar and A. Manthiram, Influence of chromium doping on the electrochemical performance of the 5V spinel cathode LiMn1.5Ni0.5O4, Electrochimica Acta, 50, 2005, 5568-5572.
[55] J. Mao, K. Dai, and M. Xuan et al., Effect of Chromium and Niobium Doping on the Morphology and Electrochemical Performance of High-Voltage Spinel LiNi0.5Mn1.5O4 Cathode Material, ACS Applied Materials & Interfaces, 8, 2016, 9116-9124.
[56] F. Zou, Z. Cui, and H. C. Nallan et al., Long-Term Cycling of a Mn-Rich High-Voltage Spinel Cathode by Stabilizing the Surface with a Small Dose of Iron, ACS Applied Materials & Interfaces, 4, 2021, 13297-13306.
[57] T.A. Arunkumar and A. Manthiram, Influence of chromium doping on the electrochemical performance of the 5V spinel cathode LiMn1.5Ni0.5O4, Electrochimica Acta, 50, 2005, 5568-5572.
[58] A. Bhaskar, W. Gruner, and D. Mikhailova et al., Thermal stability of Li1−ΔM0.5Mn1.5O4 (M = Fe, Co, Ni) cathodes in different states of delithiation Δ, RSC Advances, 2013, 3, 5909-5916.
[59] N. Kiziltas-Yavuz, M. Yavuz, and S. Indris et al., Enhancement of electrochemical performance by simultaneous substitution of Ni and Mn with Fe in Ni-Mn spinel cathodes for Li-ion batteries, Journal of Power Sources, 327, 2016, 507-518.
[60] E. Lester, G. Aksomaityte, and J. Li et al, Controlled continuous hydrothermal synthesis of cobalt oxide (Co3O4) nanoparticles. Progress in Crystal Growth and Characterization of Materials, 58, 2012, 3-13.
[61] M.A. Jalil, M.N.I. Khan, and S. Mandal et al, Impact of reaction temperatures on the particle size of V2O5 synthesized by facile hydrothermal technique and their auspicious photocatalytic performance in dye degradation, AIP Advances,13,2023, 015010.
[62] R. Sibille, A. Mesbah, and T. Mazet et al., Magnetic measurements and neutron diffraction study of the layered hybrid compounds Mn (C8H4O4)(H2O)2 and Mn2(OH)2(C8H4O4), Journal of Solid State Chemistry, 186, 2012,134-141.
[63] A. Mesbah, B. Malaman, and T. Mazet et al., Location of metallic elements in (Co1−xFex)2(OH)2(C8H4O4): use of MAD, neutron diffraction and 57Fe Mössbauer spectroscopy, CrystEngComm, 12, 2010, 3126-3131.
[64] L. Si, L. Yue, and D. Jin et al., Solvothermal synthesis of flower-like lanthanum tartrate and lanthanum oxide microspheres in ethanol-water mixed system, Crystal Research and Technology, 46, 2011, 1149-1154.
[65] H. Chen and H.Y. Chang, Homogeneous precipitation of cerium dioxide nanoparticles in alcohol/water mixed solvents, Colloids and Surfaces A: Physicochemical and Engineering Aspects, 242, 2004, 61-69.
[66] Z. Wang, Y. Liu, and C. Gao et al., A porous Co(OH)2 material derived from a MOF template and its superior energy storage performance for supercapacitors, Journal of Materials Chemistry A, 3, 2015, 20658-20663.
[67] S. He, Z. Li, and J. Wang et al., MOF-derived NixCo1−x(OH)2 composite microspheres for high-performance supercapacitors, RSC Advances, 6, 2016, 49478-49486.
[68] J. Zhang, G. Sun, and Y. Han et al., Boosted electrochemical performance of LiNi0.5Mn1.5O4 via synergistic modification of Li+-Conductive Li2ZrO3 coating layer and superficial Zr-doping, Electrochimica Acta, 343, 2020, 136105.
[69] N. Kiziltas-Yavuz, A. Bhaskar, and D. Dixon et al., Improving the rate capability of high voltage lithium-ion battery cathode material LiNi0.5Mn1.5O4 by ruthenium doping, Journal of Power Sources , 267, 2014, 533-541.
[70] M.M. Thackeray, Structural considerations of layered and spinel lithiated oxides for lithium ion batteries, Journal of The Electrochemical Society, 142, 1995, 2558–2563.
[71] Y.K. Sun, K.H. Lee, and S.I. Moon et al., Effect of crystallinity on the electrochemical behaviour of spinel Li1.03Mn2O4 cathode materials, Solid State Ionics, 112, 1998, 237-243.
[72] J.H. Kim, A. Huq, and M. Chi et al., Integrated nano-domains of disordered and ordered spinel phases in LiNi0.5Mn1.5O4 for li-ion batteries, Chemistry of Materials, 26, 2014, 4377-4386.
[73] C. J. Jafta, M. K. Mathe, and N. Manyala et al., Microwave-assisted synthesis of high-voltage nanostructured LiMn1.5Ni0.5O4 spinel: Tuning the Mn3+ content and electrochemical performance, ACS Applied Materials & Interfaces, 5, 2013, 7592−7598.
[74] F. Guzel, H. Yakut, and G. Topal, Determination of kinetic and equilibrium parameters of the batch adsorption of Mn (II), Co (II),Ni (II) and Cu (II) from aqueous solution by black carrot (Daucus carota L.) residues, Journal of Hazardous Materials, 153, 2008, 1275-1287.
[75] D.O. Miles, D. Jiang, and A.D. Burrows et al., Conformal transformation of [Co (bdc) (DMF)] (Co-MOF-71, bdc = 1, 4-benzenedicarboxylate, DMF = NN-dimethylformamide) into porous electrochemically active cobalt hydroxide, Electrochemistry Communications, 27, 2013, 9-13.
[76] A. Bhaskar, S. Krueger, and V. Siozios et al., Synthesis and Characterization of High-Energy, High-Power Spinel-Layered Composite Cathode Materials for LithiumIon Batteries, Advanced Energy Materials, 5, 2014, 1401156.
[77] G.B. Zhong, Y.Y. Wang, and Y.Q. Yu et al., Electrochemical investigations of the LiNi0.45M0.10Mn1.45O4 (M=Fe, Co, Cr) 5V cathode materials for lithium ion batteries, Journal of Power Sources, 205, 2012, 385-393.
[78] Y. Maeda, K. Ariyoshi, and T. Kawai et al., Effect of deviation from Ni/Mn stoichiometry in Li[Ni1/2Mn3/2]O4 upon rechargeable capacity at 4.7 V in nonaqueous lithium cells, Journal of the Ceramic Society of Japan, 117, 2009, 1216-1220.
[79] Y.H. Liu, T.Y. Tsai, Improving electrochemical performance of lithium ion batteries using a binder-free carbon fiber-based LiNi0.5(1-x)Mn1.5(1-x/3)CrxO4 cathode with a conventional electrolyte, Journal of Power Sources, 484, 2021, 229262.
[80] M.C. Kim, Y.W. Lee, and T.K. Pham et al., Chemical valence electron-engineered LiNi0.4Mn1.5MtO4 (Mt = Co and Fe) cathode materials with high-performance electrochemical properties, Applied Surface Science, 504, 2020, 144514.
[81] J.H. Kim, S.T. Myung, and C.S. Yoon et al., Comparative study of LiNi0.5Mn1.5O4-δ and LiNi0.5Mn1.5O4 cathodes having two crystallographic structures: Fd3m and P4332, Chemistry of Materials, 16, 2004, 906-914.
[82] S.K. Hong, S.I. Mho, and I.H. Yeo et al., Structural and electrochemical characteristics of morphology-controlled Li[Ni0.5Mn1.5]O4 cathodes, Electrochimica Acta, 156, 2015, 29-37.
[83] S. Chong, Y. Chen, and W. Yan et al., Suppressing capacity fading and voltage decay of Li-rich layered cathode material by a surface nano-protective layer of CoF2 for lithium-ion batteries, Journal of Power Sources, 332, 2016, 230-239.
[84] T. Zhao, Y. Zhang, and Y. Li et al., Electrochemical activation of novel Fe-based Li-rich cathode material for lithium-ion batteries, Journal of Alloys and Compounds, 741, 2018 597-603.
[85] B. Li, Y. Yu, and J. Zhao, Facile synthesis of spherical xLi2MnO3·(1–x)Li (Mn0.33Co0.33Ni0.33)O2 as cathode materials for lithium-ion batteries with improved electrochemical performance, Journal of Power Sources, 275, 2015, 64-72.
[86] M. Herstedt, A.M. Andersson, and H. Rensmo et al., Characterisation of the SEI formed on natural graphite in PC-based electrolytes, Electrochimica Acta, 49, 2004, 4939-4947.
[87] S. Yoon, Effect of nitridation on LiMn1.5Ni0.5O4 and its application as cathode material in lithium-ion batteries, Journal of Applied Electrochemistry, 46, 2016, 479-485.
[88] J. Xiao, X. Chen, and P. V. Sushko et al., High-performance LiNi0.5MnO4 Spinel controlled by Mn3+ concentration and site disorder, Advanced Materials, 24, 2012, 2109–2116.
[89] C. Yin, H. Zhou, and Z. Yang et al., Synthesis and Electrochemical Properties of LiNi0.5Mn1.5O4 for Li-Ion Batteries by the Metal–Organic Framework Method, ACS Applied Materials & Interfaces, 10, 2018, 13625-13634.
[90] Q. Chen, H. Liu, and J. Hao et al., Synthesis and characterization of high-performance RGO-modified LiNi0.5Mn1.5O4 nanorods as a high power density cathode material for Li-ion batteries, Ionics, 25, 2019, 99-109.
[91] J. Wang, W. Lin, and B. Wu et al., Syntheses and electrochemical properties of the Na-doped LiNi0.5Mn1.5O4 cathode materials for lithium-ion batteries, Electrochimica Acta, 145, 2014, 245-253.
[92] X. Nie, B. Zhong, and M. Chen et al., Synthesis of LiCr0.2Ni0.4Mn1.4O4 with superior electrochemical performance via a two-step thermos polymerization technique, Electrochimica Acta, 97, 2013, 184-191.
[93] X. Fang, M. Ge, and J. Rong et al., Graphene-oxide-coated LiNi0.5Mn1.5O4 as high voltage cathode for lithium ion batteries with high energy density and long cycle life, Journal of Materials Chemistry A, 1, 2013, 4083-4088.
[94] L. Wang, J. Zhao, and J. Gao et al., Electrochemical Impedance Spectroscopy (EIS) Study of LiNi1/3Co1/3Mn1/3O2 for Li-ion Batteries, International Journal of Electrochemical Science, 7, 2012, 345-353.
[95] S. Klein, P. Harte, and Jonas Henschel et al., On the Beneficial Impact of Li2CO3 as Electrolyte Additive in NCM523∥Graphite Lithium Ion Cells Under High-Voltage Conditions, Advanced Energy Materials, 11, 2021, 2003756.
[96] A.T.S. Freiberg, M.K. Roos, and J. Wandt et al., Singlet Oxygen Reactivity with Carbonate Solvents used for Li-Ion Battery Electrolytes, The Journal of Physical Chemistry A, 122, 2018, 8828–8839.
[97] V. Kraft, W. Weber, and B. Streipert et al., Qualitative and quantitative investigation of organophosphates in an electrochemically and thermally treated lithium hexafluorophosphate-based lithium ion battery electrolyte by a developed liquid chromatography-tandem quadrupole mass spectrometry method, RSC Advances, 6, 2016, 8-17. |