[1] QIU Z P, ZHANG Y J, XIA S B et al. Research progress on interface properties of inorganic solid state lithium ion batteries[D]. Acta Chim.Sinica, 73, 992-1001(2015).

[2] XU X X, LI H. A review of solid-state lithium batteries[D]. Energ. Stor. Sci. Technol, 7, 1-7(2018).

[3] KIM J G, SON B, MUKHERJEE S et al. A review of lithium and non-lithium based solid state batteries[J]. Power Sources, 282, 299-322(2015).

[4] MAUGER A, ARMAND M, JULIEN C M et al. Challenges and issues facing lithium metal for solid-state rechargeable batteries.[J]. Power Sources, 353, 333-342(2017).

[5] SUN C, LIU J, GONG Y et al. Recent advances in all-solid-state rechargeable lithium batteries[D]. Nano Energy, 33, 363-386(2017).

[6] TAKADA K. Progress and prospective of solid-state lithium batteries[D]. Acta Mater, 61, 759-770(2013).

[7] MEESALA Y, JENA A, CHANG H et al. Recent advancements in Li-ion conductors for all-solid-state Li-ion batteries[D]. ACS Energy Lett, 2, 2734-2751(2017).

[8] KERMAN K, LUNTZ A, VISWANATHAN V et al. Review- practical challenges hindering the development of solid state Li ion batteries.[J]. Electrochem. Soc, 164, A1731-A1744(2017).

[9] CHEN L, CHI S S, DONG Y et al. Research progress of key materials for all-solid-state lithium batteries.[J]. Chin. Ceram. Soc, 46, 21-34(2018).

[10] KAZUNORI TAKADA. Progress in solid electrolytes toward realizing solid-state lithium batteries.[J]. Power Sources, 394, 74-85(2018).

[11] CHENG J, LI H, WANG C. Recent progress in solid-state electrolytes for alkali-ion batteries[D]. Sci. Bull, 62, 1473-1490(2017).

[12] ZHENG F, KOTOBUKI M, SONG S et al. Review on solid electrolytes for all-solid-state lithium-ion batteries.[J]. Power Sources, 389, 198-213(2018).

[13] ZHU Y, HE X, MO Y. Origin of outstanding stability in the lithium solid electrolyte materials: insights from thermodynamic analyses based on first-principles calculations[D]. ACS Appl. Mater. Interfaces, 7, 23685-23693(2015).

[14] ZHONG S W, HUANG B. Effects of excess lithium salt on properties of perovskite-type solid electrolyte Li_3/8Sr_7/16Ta_3/4Hf_1/4O₃[D]. Nonferr. Metal. Sci. Eng, 8, 70-74(2017).

[15] XU C, LUO J B, PENG W W et al. SPS sintering and properties of NASICON type solid electrolyte Li_1.1Y_0.1Zr_1.9(PO₄)₃[D]. Nonferr. Metal. Sci. Eng, 9, 66-70(2018).

[16] LUO J B, LI T T, YOU W X et al. Preparation of Li_3/8Sr_7/16Ta_3/4Hf_1/4O₃ perovskite solid electrolyte by hot pressing sintering[D]. Nonferr. Metal. Sci. Eng, 9, 66-69(2018).

[17] BACHMAN J C, MUY S, GRIMAUD A et al. Inorganic solid-state electrolytes for lithium batteries: mechanisms and properties governing ion conduction[D]. Chem. Rev, 116, 140-162(2016).

[18] LIN Z J, HE X M, LI J J et al. Recent advances of all solid state polymer electrolyte for Li-ion batteries[D]. Prog. Chem, 18, 459-466(2006).

[19] RICHARDS W D, MIARA L J, WANG Y et al. Interface stability in solid-state batteries[D]. Chem. Mater, 28, 266-273(2016).

[20] DUAN H, ZHENG H, ZHOU Y et al. Stability of garnet-type Li ion conductors: an overview[D]. Solid State Ionics, 318, 45-53(2018).

[21] CHAN C K, YANG T, WELLER J M. Nanostructured garnet-type Li₇La₃Zr₂O₁₂: synthesis, properties, and opportunities as electrolytes for Li-ion batteries[D]. Electrochim. Acta, 253, 268-280(2017).

[22] RAMAKUMAR S, DEVIANNAPOORANI C, DHIVYA L et al. Lithium garnets: synthesis, structure, Li +, conductivity, Li +, dynamics and applications[D]. Prog. Mater. Sci, 88, 325-411(2017).

[23] LIU Q, GENG Z, HAN C et al. Challenges and perspectives of garnet solid electrolytes for all solid-state lithium batteries.[J]. Power Sources, 389, 120-134(2018).

[24] WU J F, PANG W K, PETERSON V K et al. Garnet-type fast Li-ion conductors with high ionic conductivities for all-solid-state batteries[D]. ACS Appl. Mater. Interfaces, 9, 12461-12468(2017).

[25] HAN X, GONG Y, FU K K et al. Negating interfacial impedance in garnet-based solid-state Li metal batteries[D]. Nat. Mater, 16, 572-579(2017).

[26] FU K K, GONG Y, LIU B et al. Toward garnet electrolyte-based Li metal batteries: an ultrathin, highly effective, artificial solid-state electrolyte/metallic Li interface[D]. Sci. Adv, 3, e1601659(2017).

[27] WANG C, GONG Y, LIU B et al. Conformal, nanoscale ZnO surface modification of garnet-based solid state electrolyte for lithium metal anodes[D]. Nano Lett, 17, 565-571(2016).

[28] TIAN Y, DING F, ZHONG H et al. Li_6.75La₃Zr_1.75Ta_0.25O₁₂ @amorphous Li₃OCl composite electrolyte for solid state lithium- metal batteries[D]. Energy Storage Mater, 14, 49-57(2018).

[29] GAO Z H, SUN H B, FU L et al. Promises, challenges,recent progress of inorganic solid-state electrolytes for all-solid-state lithium batteries[D]. Adv Mater, 30(2018).

[30] ZHENG B, WANG H, MA J, GONG Z, YANG Y. A review of inorganic solid electrolyte/electrode interface in all-solid-state lithium batteries[D]. Sci. Sin. Chim, 47, 579-593(2017).

[31] YU S, SCHMIDT R D, GARCIA-MENDEZ R et al. Elastic properties of the solid electrolyte Li₇La₃Zr₂O₁₂( LLZO)[D]. Chem. Mater, 28, 197-206(2016).

[32] ZHAN X, LAI S, GOBET M P et al. Defect chemistry and electrical properties of garnet-type Li₇La₃Zr₂O₁₂[D]. Phys. Chem. Chem. Phys, 20, 1447-1459(2018).

[33] LIU T, ZHANG Y, CHEN R et al. Non-successive degradation in bulk-type all-solid-state lithium battery with rigid interfacial contact[D]. Electrochem. Commun, 79, 1-4(2017).

[34] YAMADA H, ITO T, HONGAHALLY BASAPPA R et al. Influence of strain on local structure and lithium ionic conduction in garnet-type solid electrolyte.[J]. Power Sources, 368, 97-106(2017).

[35] BUCCI G, SWAMY T, CHIANG Y M et al. Modeling of internal mechanical failure of all-solid-state batteries during electrochemical cycling, and implications for battery design[D]. J. Mater. Chem. A, 5, 19422-19430(2017).

[36] CHENG L, CRUMLIN E J, CHEN W et al. The origin of high electrolyte-electrode interfacial resistances in lithium cells containing garnet type solid electrolytes[D]. Phys. Chem. Chem. Phys, 16, 18294-18300(2014).

[37] CHENG L, WU C H, JARRY A et al. Interrelationships among grain size, surface composition, air stability, and interfacial resistance of Al-substituted Li₇La₃Zr₂O₁₂ solid electrolytes[D]. ACS Appl. Mater. Interfaces, 7, 17649-19655(2015).

[38] SHARAFI A. Impact of air exposure and surface chemistry on Li-Li₇La₃Zr₂O₁₂ interfacial resistance[D]. J. Mater. Chem. A, 5, 13475-13487(2017).

[39] AHN C W, CHOI J J, RYU J et al. Electrochemical properties of Li₇La₃Zr₂O₁₂-based solid state battery.[J]. Power Sources, 272, 554-558(2014).

[40] XIA W, XU B, DUAN H et al. Reaction mechanisms of lithium garnet pellets in ambient air: the effect of humidity and CO₂.[J]. Am. Ceram. Soc, 100, 2832-2839(2017).

[41] KANG S G, SHOLL D S. First-principles study of chemical stability of the lithium oxide garnets Li₇La₃M₂O₁₂ (M=Zr, Sn, or Hf)[D]. J. Phys. Chem. C, 118, 17402-17406(2014).

[42] HOFSTETTER K, SAMSON A J, NARAYANAN S et al. Present understanding of the stability of Li-stuffed garnets with moisture, carbon dioxide, and metallic lithium.[J]. Power Sources, 390, 297-312(2018).

[43] JIN Y, MCGINN P J. Li₇La₃Zr₂O₁₂, electrolyte stability in air and fabrication of a Li/Li₇La₃Zr₂O₁₂/Cu_0.1V₂O₅ solid-state battery.[J]. Power Sources, 239, 326-331(2013).

[44] WANG Y X, LAI W. Phase transition in lithium garnet oxide ionic conductors Li₇La₃Zr₂O₁₂: the role of Ta substitution and H₂O/CO₂ exposure.[J]. Power Sources, 275, 612-620(2015).

[45] TIAN Y, SHI T, RICHARDS W D et al. Compatibility issues between electrodes and electrolytes in solid-state batteries[D]. Energy Environ. Sci, 10, 1150-1166(2017).

[46] KIM K H, IRIYAMA Y, YAMAMOTO K et al. Characterization of the interface between LiCoO₂, and Li₇La₃Zr₂O₁₂, in an all-solid-state rechargeable lithium battery.[J]. Power Sources, 196, 764-767(2011).

[47] OHTA S, SEKI J, YAGI Y et al. Co-sinterable lithium garnet-type oxide electrolyte with cathode for all-solid-state lithium ion battery.[J]. Power Sources, 265, 40-44(2014).

[48] REN Y, LIU T, SHEN Y et al. Chemical compatibility between garnet-like solid state electrolyte Li_6.75La₃Zr_1.75Ta_0.25O₁₂, and major commercial lithium battery cathode materials.[J]. Materiomics, 2, 256-264(2016).

[49] MIARA L, WINDMÜLLER A, TSAI C L et al. About the compatibility between high voltage spinel cathode materials and solid oxide electrolytes as function of temperature[D]. ACS Appl. Mater. Interfaces, 8, 26842-26850(2016).

[50] MIARA L J, RICHARDS W D, WANG Y E et al. First-principles studies on cation dopants and electrolyte|cathode interphases for lithium garnets[D]. Chem. Mater, 27, 4040-4047(2015).

[51] HÄNSEL C, AFYON S, RUPP J L. Investigating the all-solid-state batteries based on lithium garnets and a high potential cathode- LiMn_1.5Ni_0.5O₄[D]. Nanoscale, 8, 18412-18420(2016).

[52] PARK K, YU B C, JUNG J W et al. Electrochemical nature of the cathode interface for a solid-state lithium-ion battery: interface between LiCoO₂ and garnet-Li₇La₃Zr₂O₁₂[D]. Chem. Mater, 28, 8051-8059(2016).

[53] DU F, ZHAO N, LI Y et al. All solid state lithium batteries based on lamellar garnet-type ceramic electrolytes.[J]. Power Sources, 300, 24-28(2015).

[54] LIU T, REN Y, SHEN Y et al. Achieving high capacity in bulk-type solid-state lithium ion battery based on Li_6.75La₃Zr_1.75Ta_0.25O₁₂, electrolyte: interfacial resistance.[J]. Power Sources, 324, 349-357(2016).

[55] HE M, CUI Z, HAN F et al. Construction of conductive and flexible composite cathodes for room-temperature solid-state lithium batteries.[J]. Alloys Compd, 762, 157-162(2018).

[56] LIU T, ZHANG Y, ZHANG X et al. Enhanced electrochemical performance of bulk type oxide ceramic lithium battery enabled by interface modification[D]. J. Mater. Chem. A, 6, 4649-4657(2018).

[57] YAN X F, LI Z B, WEN Z Y et al. Li/Li₇La₃Zr₂O₁₂/LiFePO₄ all-solid-state battery with ultrathin nanoscale solid electrolyte[D]. J. Phys. Chem. C, 121, 1431-1435(2017).

[58] WAKAYAMA H, YONEKURA H, KAWAI Y. Three-dimensional bicontinuous nanocomposite from a self-assembled block copolymer for a high-capacity all-solid-state lithium battery cathode[D]. Chem. Mater, 28, 4453-4459(2016).

[59] WAKAYAMA H, KAWAI Y. Effect of LiCoO₂/Li₇La₃Zr₂O₁₂ ratio on the structure and electrochemical properties of nanocomposite cathodes for all-solid-state lithium batteries[D]. J. Mater. Chem. A, 5, 18816-18822(2017).

[60] GAI J, ZHAO E, MA F et al. Improving the Li-ion conductivity and air stability of cubic Li₇La₃Zr₂O₁₂ by the co-doping of Nb, Y on the Zr site.[J]. Eur. Ceram. Soc, 38, 1673-1678(2017).

[61] OHTA S, KOBAYASHI T, SEKI J et al. Electrochemical performance of an all-solid-state lithium ion battery with garnet-type oxide electrolyte.[J]. Power Sources, 202, 332-335(2012).

[62] KOTOBUKI M, MUNAKATA H, KANAMURA K et al. Compatibility of Li₇La₃Zr₂O₁₂ solid electrolyte to all-solid-state battery using Li metal anode.[J]. Electrochem. Soc, 157, A1076-A1079(2010).

[63] LIU B, FU K, GONG Y et al. Rapid thermal annealing of cathode- garnet interface toward high temperature solid state batteries[D]. Nano Lett, 17, 4917-4923(2017).

[64] OHTA S, KOMAGATA S, SEKI J et al. All-solid-state lithium ion battery using garnet-type oxide and Li₃BO₃, solid electrolytes fabricated by screen-printing.[J]. Power Sources, 238, 53-56(2013).

[65] KATO T, HAMANAKA T, YAMAMOTO K et al. In-situ Li₇La₃Zr₂O₁₂/LiCoO₂ interface modification for advanced all-solid- state battery.[J]. Power Sources, 260, 292-298(2014).

[66] OHTA N, TAKADA K, ZHANG L et al. Enhancement of the high-rate capability of solid-state lithium batteries by nanoscale interfacial modification[D]. Adv. Mater, 18, 2226-2229(2006).

[67] KITAURA H, HAYASHI A, TADANAGA K et al. Improvement of electrochemical performance of all-solid-state lithium secondary batteries by surface modification of LiMn₂O₄, positive electrode[D]. Solid State Ionics, 192, 304-307(2011).

[68] SAKUDA A, KITAURA H, HAYASHI A et al. Improvement of high-rate performance of all-solid-state lithium secondary batteries using LiCoO₂ coated with Li₂O-SiO₂ glasses[D]. Electrochem. Solid-State Lett, 11, A1-A3(2008).

[69] JIN Y, LI N, CHEN C H et al. Electrochemical characterizations of commercial LiCoO₂ powders with surface modified by Li₃PO₄ nanoparticles[D]. Electrochem. Solid-State Lett, 9, A273-A276(2006).

[70] LIU B, GONG Y, FU K et al. Garnet solid electrolyte protected Li-metal batteries[D]. ACS Appl. Mater. Interfaces, 9, 18809-18815(2017).

[71] ZHANG J, ZHAO N, ZHANG M et al. Flexible and ion- conducting membrane electrolytes for solid-state lithium batteries: dispersion of garnet nanoparticles in insulating polyethylene oxide[D]. Nano Energy, 28, 447-454(2016).

[72] CHEN R J, ZHANG Y B, LIU T et al. Addressing the interface issues in all-solid-state bulk-type lithium ion battery via an all composite approach[D]. ACS Appl. Mater. Interfaces, 9, 9654-9661(2017).

[73] ZHANG X, LIU T, ZHANG S et al. Synergistic coupling between Li_6.75La₃Zr_1.75Ta_0.25O₁₂ and poly (vinylidene fluoride) induces high ionic conductivity, mechanical strength and thermal stability of solid composite electrolytes[D]. J. Am. Chem. Soc, 139, 13779-13785(2017).

[74] ZHANG W, NIE J, LI F et al. A durable and safe solid-state lithium battery with a hybrid electrolyte membrane[D]. Nano Energy, 45, 413-419(2018).

[75] YOSHIMA K, HARADA Y, TAKAMI N. Thin hybrid electrolyte based on garnet-type lithium-ion conductor Li₇La₃Zr₂O₁₂, for 12V-class bipolar batteries.[J]. Power Sources, 302, 283-290(2016).

[76] ZHANG J, ZANG X, WEN H et al. High-voltage and free- standing poly(propylene carbonate)/Li_6.75La₃Zr_1.75Ta_0.25O₁₂ composite solid electrolyte for wide temperature range and flexible solid lithium ion battery[D]. J. Mater. Chem. A, 5, 4940-4948(2017).

[77] HUO H, SUN J, CHEN C et al. Flexible interfaces between Si anodes and composite electrolytes consisting of poly(propylene carbonates) and garnets for solid-state batteries.[J]. Power Sources, 383, 150-156(2018).

[78] HUO H, ZHAO N, SUN J et al. Composite electrolytes of polyethylene oxides/garnets interfacially wetted by ionic liquid for room-temperature solid-state lithium battery.[J]. Power Sources, 372, 1-7(2017).

[79] WANG Z, WANG Z, YANG L et al. Boosting Interfacial Li ⁺, transport with a MOF-based ionic conductor for solid-state batteries[D]. Nano Energy, 49, 580-587(2018).

[80] XU B, DUAN H, LIU H et al. Stabilization of garnet/liquid electrolyte interface using superbase additives for hybrid Li batteries[D]. ACS Appl. Mater. Interfaces, 9, 21077-21082(2017).

[81] JAN V D B, AFYON S, RUPP J L M. Interface-engineered all-solid-state Li-ion batteries based on garnet-type fast Li ⁺ conductors[D]. Adv. Energy Mater, 6(2016).