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Nitrile-functionalized poly(siloxane) as electrolytes for high-energy-density solid-state Li batteries
Okur, F., Sheima, Y., Zimmerli, C., Zhang, H., Helbling, P., Fäh, A., … Kravchyk, K. V. (2024). Nitrile-functionalized poly(siloxane) as electrolytes for high-energy-density solid-state Li batteries. ChemSusChem, 17(3), e202301285 (8 pp.). https://doi.org/10.1002/cssc.202301285
The colloidal properties of nanocellulose
Benselfelt, T., Kummer, N., Nordenström, M., Fall, A. B., Nyström, G., & Wågberg, L. (2023). The colloidal properties of nanocellulose. ChemSusChem, 16(8), e202201955 (38 pp.). https://doi.org/10.1002/cssc.202201955
Methodological studies of the mechanism of anion insertion in nanometer-sized carbon micropores
Welty, C., Taylor, E. E., Posey, S., Vailati, P., Kravchyk, K. V., Kovalenko, M. V., & Stadie, N. P. (2023). Methodological studies of the mechanism of anion insertion in nanometer-sized carbon micropores. ChemSusChem, 16(4), e202201847 (11 pp.). https://doi.org/10.1002/cssc.202201847
Thiol-amine-based solution processing of Cu<sub>2</sub>S thin films for photoelectrochemical water splitting
Zhang, X., Yang, W., Niu, W., Adams, P., Siol, S., Wang, Z., & Tilley, S. D. (2021). Thiol-amine-based solution processing of Cu2S thin films for photoelectrochemical water splitting. ChemSusChem, 14(18), 3967-3974. https://doi.org/10.1002/cssc.202101347
Solvent- and catalyst-free carbon dioxide capture and reduction to formate with borohydride ionic liquid
Lombardo, L., Yang, H., Zhao, K., Dyson, P. J., & Züttel, A. (2020). Solvent- and catalyst-free carbon dioxide capture and reduction to formate with borohydride ionic liquid. ChemSusChem, 13(8), 2025-2031. https://doi.org/10.1002/cssc.201903514
Scaling up electrodes for photoelectrochemical water splitting: fabrication process and performance of 40 cm&lt;sup&gt;2&lt;/sup&gt; LaTiO&lt;sub&gt;2&lt;/sub&gt;N photoanodes
Dilger, S., Trottmann, M., & Pokrant, S. (2019). Scaling up electrodes for photoelectrochemical water splitting: fabrication process and performance of 40 cm2 LaTiO2N photoanodes. ChemSusChem, 12(9), 1931-1938. https://doi.org/10.1002/cssc.201802645
Direct solution‐based synthesis of the Na&lt;sub&gt;4&lt;/sub&gt;(B&lt;sub&gt;12&lt;/sub&gt;H&lt;sub&gt;12&lt;/sub&gt;)(B&lt;sub&gt;10&lt;/sub&gt;H&lt;sub&gt;10&lt;/sub&gt;) solid electrolyte
Gigante, A., Duchêne, L., Moury, R., Pupier, M., Remhof, A., & Hagemann, H. (2019). Direct solution‐based synthesis of the Na4(B12H12)(B10H10) solid electrolyte. ChemSusChem, 12(21), 4832-4837. https://doi.org/10.1002/cssc.201902152
New Ni&lt;sub&gt;0.5&lt;/sub&gt;Ti&lt;sub&gt;2&lt;/sub&gt;(PO&lt;sub&gt;4&lt;/sub&gt;)&lt;sub&gt;3&lt;/sub&gt;@C NASICON‐type electrode material with high rate capability performance for lithium‐ion batteries: synthesis and electrochemical properties
Srout, M., Kwon, N. H., Luo, W., Züttel, A., Fromm, K. M., & Saadoune, I. (2019). New Ni0.5Ti2(PO4)3@C NASICON‐type electrode material with high rate capability performance for lithium‐ion batteries: synthesis and electrochemical properties. ChemSusChem, 12(21), 4846-4853. https://doi.org/10.1002/cssc.201902002
Early-stage sustainability evaluation of nanoscale cathode materials for lithium ion batteries
Hischier, R., Kwon, N. H., Brog, J. P., & Fromm, K. M. (2018). Early-stage sustainability evaluation of nanoscale cathode materials for lithium ion batteries. ChemSusChem, 11(13), 2068-2076. https://doi.org/10.1002/cssc.201800109
Solvothermally-prepared Cu<SUB>2</SUB>O electrocatalysts for CO<SUB>2</SUB> reduction with tunable selectivity by the introduction of p-block elements
Larrazábal, G. O., Martín, A. J., Krumeich, F., Hauert, R., & Pérez-Ramírez, J. (2017). Solvothermally-prepared Cu2O electrocatalysts for CO2 reduction with tunable selectivity by the introduction of p-block elements. ChemSusChem, 10(6), 1255-1265. https://doi.org/10.1002/cssc.201601578
Design guidelines for high-performance particle-based photoanodes for water splitting: lanthanum titanium oxynitride as a model
Landsmann, S., Maegli, A. E., Trottmann, M., Battaglia, C., Weidenkaff, A., & Pokrant, S. (2015). Design guidelines for high-performance particle-based photoanodes for water splitting: lanthanum titanium oxynitride as a model. ChemSusChem, 8(20), 3451-3458. https://doi.org/10.1002/cssc.201500830
Controlled silylation of nanofibrillated cellulose in water: reinforcement of a model polydimethylsiloxane network
Zhang, Z., Tingaut, P., Rentsch, D., Zimmermann, T., & Sèbe, G. (2015). Controlled silylation of nanofibrillated cellulose in water: reinforcement of a model polydimethylsiloxane network. ChemSusChem, 8(16), 2681-2690. https://doi.org/10.1002/cssc.201500525
Renewable and functional wood materials by grafting polymerization within cell walls
Cabane, E., Keplinger, T., Merk, V., Hass, P., & Burgert, I. (2014). Renewable and functional wood materials by grafting polymerization within cell walls. ChemSusChem, 7(4), 1020-1025. https://doi.org/10.1002/cssc.201301107
Debinding mechanisms in thermoplastic processing of a Ba<SUB>0.5</SUB>Sr<SUB>0.5</SUB>Co<SUB>0.8</SUB>Fe<SUB>0.2</SUB>O<SUB>3−</SUB><I><SUB>δ</SUB></I>- stearic acid–polystyrene mixture
Salehi, M., Clemens, F., Otal, E. H., Ferri, D., Graule, T., & Grobéty, B. (2013). Debinding mechanisms in thermoplastic processing of a Ba0.5Sr0.5Co0.8Fe0.2O3−δ- stearic acid–polystyrene mixture. ChemSusChem, 6(2), 336-344. https://doi.org/10.1002/cssc.201200540