Copper-coordinated cellulose ion conductors for solid-state batteries

Yang, Chunpeng; Wu, Qisheng; Xie, Wei-Qi; Zhang, Xin; Brozena, Alexandra H.; Jin, Zheng; Garaga, Mounesha N.; Ko, Byung Hee; Mao, Yimin; He, Shuaiming; Gao, Yue; Wang, Pengbo; Tyagi, Madhusudan; Jiao, Feng; Briber, Robert M.; Albertus, Paul; Wang, Chunsheng; Greenbaum, Steven; Hu, Yan‐Yan; Isogai, Akira; Winter, Martin; Xu, Kang; Qi, Yue; Hu, Liangbing

doi:10.1038/s41586-021-03885-6

Cited by 298 publications

(227 citation statements)

References 63 publications

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“…Based on our experiments (Figure 1), we see that: 1) Since there are many more types of natural materials with abundant internal surfaces (like clays and woods [ 25 ] ) than the materials studied in this work, it is reasonable to conjecture that more solid proton electrolytes with superfast proton conductivity and special properties can be synthesized by integrating proton carriers (water and acids) into the hydrophilic networks. The suppression of first‐order freezing transition and the associated drastic drop in proton conductivity down to −82 °C is one of the benefits of this approach.…”

Section: Discussionmentioning

confidence: 90%

Acid‐in‐Clay Electrolyte for Wide‐Temperature‐Range and Long‐Cycle Proton Batteries

et al. 2022

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Proton conduction underlies many important electrochemical technologies. A family of new proton electrolytes is reported: acid‐in‐clay electrolyte (AiCE) prepared by integrating fast proton carriers in a natural phyllosilicate clay network, which can be made into thin‐film (tens of micrometers) fluid‐impervious membranes. The chosen example systems (sepiolite–phosphoric acid) rank top among the solid proton conductors in terms of proton conductivities (15 mS cm−1 at 25 °C, 0.023 mS cm−1 at −82 °C), electrochemical stability window (3.35 V), and reduced chemical reactivity. A proton battery is assembled using AiCE as the solid electrolyte membrane. Benefitting from the wider electrochemical stability window, reduced corrosivity, and excellent ionic selectivity of AiCE, the two main problems (gassing and cyclability) of proton batteries are successfully solved. This work draws attention to the element cross‐over problem in proton batteries and the generic “acid‐in‐clay” solid electrolyte approach with superfast proton transport, outstanding selectivity, and improved stability for room‐ to cryogenic‐temperature protonic applications.

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Section: Discussionmentioning

confidence: 90%

Acid‐in‐Clay Electrolyte for Wide‐Temperature‐Range and Long‐Cycle Proton Batteries

et al. 2022

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“…However, transport of lithium ions in SPEs mainly occurs with the segmental relaxation of polymer chains, which results in a low Li + conductivity (<10 −5 S cm −1 ) at room temperature (RT) and inferior cationic transference number t + , generally 0.2-0.4. [3][4][5][6] Filling the SPEs with a ceramic singleion conductor (SIC) is a practical strategy to promote Li + conductivity. Such polymerceramic composite electrolytes (CPEs) could alleviate brittleness associated with the solid-solid contact of ceramic electrolytes, which generally causes poor interfacial Li + transport and dendrite proliferation along grain boundaries.…”

Section: Doi: 101002/adma202201410mentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Foldable Solid‐State Batteries Enabled by Electrolyte Mediation in Covalent Organic Frameworks

et al. 2022

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Solid‐state electrolytes with high Li+ conductivity, flexibility, durability, and stability offer an attractive solution to enhance safety and energy density. However, meeting these stringent requirements poses challenges to the existing solid polymeric or ceramic electrolytes. Here, an electrolyte‐mediated single‐Li+‐conductive covalent organic framework (COF) is presented, which represents a new category of quality solid‐state Li+ conductors. In situ solidification of a tailored liquid electrolyte boosts the charge‐carrier concentration in the COF channels, decouples Li+ cations from both COF walls and molecular chains, and eliminates defects by crystal soldering. Such an altered microenvironment activates the motion of Li+ ions in a directional manner, which leads to an increase in Li+ conductivity by 100 times with a transference number of 0.85 achieved at room temperature. Moreover, the electrolyte conversion cements the ultrathin COF membrane with fortified mechanical toughness. With the COF membrane, foldable solid‐state pouch cells are demonstrated.

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“…In the meantime, how to rationally control the chemical and physical properties of nanocellulose to further enhance the electrochemical performance of devices needs to be considered at a scaled-up level [454]. In addition, most of the development of nanocellulose research in batteries and supercapacitors in the past few decades has been limited to sizes no smaller than the elementary fibril level, while the fundamental science and technologies at the molecular level of nanocellulose deserve further exploration [455]. All in all, the emerging applications of nanocellulose are of obvious benefits to energy storage toward carbon neutrality, but more efforts are needed to overcome existing shortcomings of technologies enabled by nanocellulose.…”

Section: Introduction To Energy Applications Of Nanocellulosementioning

confidence: 99%

Current international research into cellulose as a functional nanomaterial for advanced applications

et al. 2022

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This review paper provides a recent overview of current international research that is being conducted into the functional properties of cellulose as a nanomaterial. A particular emphasis is placed on fundamental and applied research that is being undertaken to generate applications, which are now becoming a real prospect given the developments in the field over the last 20 years. A short introduction covers the context of the work, and definitions of the different forms of cellulose nanomaterials (CNMs) that are most widely studied. We also address the terminology used for CNMs, suggesting a standard way to classify these materials. The reviews are separated out into theme areas, namely healthcare, water purification, biocomposites, and energy. Each section contains a short review of the field within the theme and summarizes recent work being undertaken by the groups represented. Topics that are covered include cellulose nanocrystals for directed growth of tissues, bacterial cellulose in healthcare, nanocellulose for drug delivery, nanocellulose for water purification, nanocellulose for thermoplastic composites, nanocellulose for structurally colored materials, transparent wood biocomposites, supercapacitors and batteries.

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Copper-coordinated cellulose ion conductors for solid-state batteries

Cited by 298 publications

References 63 publications

Acid‐in‐Clay Electrolyte for Wide‐Temperature‐Range and Long‐Cycle Proton Batteries

Acid‐in‐Clay Electrolyte for Wide‐Temperature‐Range and Long‐Cycle Proton Batteries

Foldable Solid‐State Batteries Enabled by Electrolyte Mediation in Covalent Organic Frameworks

Current international research into cellulose as a functional nanomaterial for advanced applications

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