2018
DOI: 10.1002/smll.201704371
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Nanocellulose Modified Polyethylene Separators for Lithium Metal Batteries

Abstract: Poor cycling stability and safety concerns regarding lithium (Li) metal anodes are two major issues preventing the commercialization of high-energy density Li metal-based batteries. Herein, a novel tri-layer separator design that significantly enhances the cycling stability and safety of Li metal-based batteries is presented. A thin, thermally stable, flexible, and hydrophilic cellulose nanofiber layer, produced using a straightforward paper-making process, is directly laminated on each side of a plasma-treate… Show more

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Cited by 158 publications
(128 citation statements)
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“…Issues resulted from dendritic lithium deposition, infinite volume change, and unstable solid-electrolyte interface (SEI) layers all contribute to the impracticality of lithium metal batteries [2][3][4] . Over the past several decades, researchers have developed various strategies to counteract these obstacles, including replacing Li metal with a LiX alloy 5 , developing new solid electrolytes or optimizing electrolyte components [6][7][8][9] , modifying separators [10][11][12][13] , constructing an artificial upper interfacial layer for Li metal anodes [14][15][16][17][18] , designing two-dimensional/three-dimensional (2-D/3-D) Lihosting materials 4,[19][20][21] , and various other techniques 22 .…”
mentioning
confidence: 99%
“…Issues resulted from dendritic lithium deposition, infinite volume change, and unstable solid-electrolyte interface (SEI) layers all contribute to the impracticality of lithium metal batteries [2][3][4] . Over the past several decades, researchers have developed various strategies to counteract these obstacles, including replacing Li metal with a LiX alloy 5 , developing new solid electrolytes or optimizing electrolyte components [6][7][8][9] , modifying separators [10][11][12][13] , constructing an artificial upper interfacial layer for Li metal anodes [14][15][16][17][18] , designing two-dimensional/three-dimensional (2-D/3-D) Lihosting materials 4,[19][20][21] , and various other techniques 22 .…”
mentioning
confidence: 99%
“…[ 6–9 ] Among the next‐generation candidates, lithium–sulfur batteries (LSBs) show great promise due to their low gravimetric densities (Li: 0.534 g cm −3 ; S: 2.07 g cm −3 ), large theoretical capacities (Li: 3860 mA h g −1 ; S: 1675 mA h g −1 ), and high energy density (2600 W h kg −1 ). [ 10–14 ] Despite these remarkable advantages, the commercialization of LSBs is still challenged by several issues on Li metal anodes and S cathodes, and thereby blocking access to the market: i) uncontrollable Li dendrite growth owing to uneven current density during repeated deposition and dissolution, causing short lifespan and even safety hazards; [ 15,16 ] ii) unstable solid electrolyte interface (SEI) layer with periodic breakage and regeneration during continuous plating/stripping, which will bring about poor ion transport and large interfacial impedance; [ 17–19 ] iii) a large excess (over 100% oversize) of Li metal with low depth of discharge, which is far from sustainable targets for commercialization; [ 17,20,21 ] iv) intrinsic insulating nature of S and Li 2 S, resulting in insufficient utilization of active material; [ 22,23 ] v) dissolution of intermediate lithium polysulfides, which leads to notorious shuttle effect and thus sluggish reaction kinetics; [ 24,25 ] and vi) huge volume expansion both in Li anode (infinite) and S cathode (≈80%) during cycling process. [ 23 ] Given all that, it is highly desirable to keep plugging away at developing stable LSBs by rationally designing anodes and cathodes, respectively.…”
Section: Figurementioning
confidence: 99%
“…Whereas, the high reactivity of Li metal and interfacial resistance with alien layers still prohibit its further development. [ 14,21 ] Recently, our group reported another brand new example of a spray quenching (SQ) method to in situ construct an organic–inorganic composite SEI on molten Li with high ion conductivity and mechanical durability. [ 17 ] It has been verified that this strategy can effectively suppress the dendrite growth and enhance the integrality of electrodes.…”
Section: Figurementioning
confidence: 99%
“…Nanocellulose/polypyrrole [111] Nanocellulose/polyethylene [112] Graphene/nanocellulose/silicon [113] Solar cells/panels Nanofibers from sisal with graphene oxide [73] (Super)capacitors Bacterial nanocellulose/carbon nanotubes/triblock-copolymer ion gels [114] Nanocellulose with polyaniline [115] Acoustics Membranes for loudspeakers Cellulose nanofibers with Fe3O4 nanoparticles [71] (Bio)sensors Optical SERSbased Detection of pesticides, dyes, bacteria [116,117] Optical fluorescencebased Detection of heavy metals [118] Detection of thiols [119] Detection of elastase [120] Chemical Detection of vapors (NH3.H2O, H2O, HCl, acetic acid) [16] Electrochemical Detection of cations in biological fluids (Na + , K + , Ca 2+ ) [38] Detection of cholesterol [121] Detection of avian leukosis virus [122] Piezoelectric Based on bacterial cellulose [123] Based on plant-derived cellulose nanofibrils [124] Based on nanocellulose with chitosan [125] Preprints (www.preprints.org) | NOT PEER-REVIEWED | Posted: 14 December 2018 Preprints (www.preprints.org) | NOT PEER-REVIEWED | Posted: 14 December 2018 doi:10.20944/preprints201812.0170.v1…”
Section: Lithium Batteriesmentioning
confidence: 99%