Polypropylene Carbonate-Based Adaptive Buffer Layer for Stable Interfaces of Solid Polymer Lithium Metal Batteries

Yang, Haochen; Zhang, Yamin; Tennenbaum, Michael; Althouse, Zachary D.; Ma, Yao; He, Yubin; Wu, Yutong; Wu, Tzu−Ho; Mathur, Anmol; Chen, Peng; Huang, Yanghang; Fernández‐Nieves, Alberto; Kohl, Paul A.; Liu, Nian

doi:10.1021/acsami.9b08285

Cited by 27 publications

(22 citation statements)

References 66 publications

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“…In fact, PPC has already been reported as a superb buffer layer in both solid‐state batteries and in liquid lithium metal batteries. [ 59–61 ] For example, Yang and co‐workers used PPC between PEO and Li and observed better contact and slower interfacial degradation. [ 61 ] Yue et al also reported similar results where they show PPC could enhance the compatibility of composite polymer electrolytes and Li.…”

Section: Resultsmentioning

confidence: 99%

“…[ 59–61 ] For example, Yang and co‐workers used PPC between PEO and Li and observed better contact and slower interfacial degradation. [ 61 ] Yue et al also reported similar results where they show PPC could enhance the compatibility of composite polymer electrolytes and Li. [ 62 ] In this work, we take a step further and show that, with the unique property of PPC, it can serve as a superb interphasial layer to block dendrites in polycrystalline ceramic solid electrolytes via the homogenizing effect.…”

Section: Resultsmentioning

confidence: 99%

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Modulating Nanoinhomogeneity at Electrode–Solid Electrolyte Interfaces for Dendrite‐Proof Solid‐State Batteries and Long‐Life Memristors

Yang

et al. 2021

Advanced Energy Materials

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Dendrite penetration in ceramic lithium conductors severely constrains the development of solid‐state batteries (SSBs) while its nanoscale origin remains unelucidated. An in situ nanoscopic electrochemical characterization technique is developed based on conductive‐atomic force microscopy (c‐AFM) to reveal the local dendrite growth kinetics. Using Li7La3Zr2O12 (LLZO) as a model system, significant local inhomogeneity is observed with a hundredfold decrease in the dendrite triggering bias at grain boundaries compared with that at grain interiors. The origin of the local weakening is assigned to the nanoscale variation of elastic modulus and lithium flux detouring. An ionic‐conductive polymeric homogenizing layer is designed which achieves a high critical current density of 1.8 mA cm–2 and a low interfacial resistance of 14 Ω cm2. Practical SSBs based on LiFePO4 cathodes can be stably cycled over 300 times. Beyond this, highly reversible electrochemical dendrite healing in LLZO is discovered using the c‐AFM electrode, based on which a model memristor with a high on/off ratio of ≈105 is demonstrated for >200 cycles. This work not only provides a novel tool to investigate and design interfaces in SSBs but also offers opportunities for solid electrolytes beyond energy applications.

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Section: Resultsmentioning

confidence: 99%

Section: Resultsmentioning

confidence: 99%

Modulating Nanoinhomogeneity at Electrode–Solid Electrolyte Interfaces for Dendrite‐Proof Solid‐State Batteries and Long‐Life Memristors

Yang

et al. 2021

Advanced Energy Materials

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“…The large volume changes of the anode during the Li plating/stripping process is also detrimental for the interface integrity, leading to insufficient cycling [30][31][32][33][34]. Therefore, approaches including polymer structural modification [35,36], optimizing the structure and proportion of Li salts [37,38], introducing organic plasticizers [39,40], and inorganic fillers [41,42] have been extensively explored for constructing a healthy anode/electrolyte interface between PEO-LiTFSI and Li metal.…”

Section: Introductionmentioning

confidence: 99%

In-situ construction of a Mg-modified interface to guide uniform lithium deposition for stable all-solid-state batteries

Liu

Zheng

et al. 2021

Journal of Energy Chemistry

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“…Further improvement in the transference number (i. e., closer to unity) may be possible with a lower molecular weight PEG or stabilization of lithium metal SEI. An improved SEI, such as by the introduction of propylene carbonate oligomers [21] or other SEI‐forming organic and inorganic additives (e. g., fluoroethylene carbonate, LiNO 3 and LiBOB [22] ) would stabilize the electrode‐electrolyte interface and series resistance. Nevertheless, a higher lithium ion transference number value was measured with both plasticizers showing that the tethered anion approach holds promise for mitigating voltage droop problems.…”

Section: Resultsmentioning

confidence: 99%

Lithium Ion Conduction in Diblock Polymer Electrolyte with Tethered Anion

Liu

Kohl

2021

ChemistrySelect

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Solid polymer electrolyte (SPE) may provide a path for next generation high-performance, hazard-free lithium ion batteries. However, the low lithium ion transference number (t Li +) and electrolyte conductivity limit device performance. In this study, a diblock copolymer with a polycarbonate first block and poly (sulfonated styrene) second block has been synthesized and characterized for conductivity and shows improved t Li +. The low dissociation of lithium salts from the tethered sulfonate anion was overcome by incorporating plasticizers. The diblock SPE material had room temperature conductivity of up to 1.95 ⋅ 10 À 6 S/cm, and lithium transference number of up to 0.83 with the tethered sulfonate anion.

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Polypropylene Carbonate-Based Adaptive Buffer Layer for Stable Interfaces of Solid Polymer Lithium Metal Batteries

Cited by 27 publications

References 66 publications

Modulating Nanoinhomogeneity at Electrode–Solid Electrolyte Interfaces for Dendrite‐Proof Solid‐State Batteries and Long‐Life Memristors

Modulating Nanoinhomogeneity at Electrode–Solid Electrolyte Interfaces for Dendrite‐Proof Solid‐State Batteries and Long‐Life Memristors

In-situ construction of a Mg-modified interface to guide uniform lithium deposition for stable all-solid-state batteries

Lithium Ion Conduction in Diblock Polymer Electrolyte with Tethered Anion

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