2023

291. Pickering phase change slurries

291. Pickering phase change slurries

Saber, S., Zargartalebi, M., Kazemi, A. & Sinton, D. Journal of Colloid and Interface Science 651, 1028–1042 (2023).

290. Performance analysis of phase change slurries for closed-loop geothermal system

290. Performance analysis of phase change slurries for closed-loop geothermal system

Soni, V., Darzi, A., McPhee, H., Saber, S., Zargartalebi, M., Riordon, J., Ozden, A., Holmes, M., Zatonski, V., Toews, M. & Sinton, D. Renewable Energy 216, 119044 (2023).

289. High carbon efficiency in CO-to-alcohol electroreduction using a CO reservoir

289. High carbon efficiency in CO-to-alcohol electroreduction using a CO reservoir

Park, S., Grigioni, I., Alkayyali, T., Lee, B.-H., Kim, J., Shirzadi, E., Dorakhan, R., Lee, G., Abed, J., Bossola, F., Jung, E. D., Liang, Y., Lee, M. G., Shayesteh Zeraati, A., Kim, D., Sinton, D. & Sargent, E. Joule 7, 2335–2348 (2023).

288. Scale-Dependent Techno-Economic Analysis of CO2 Capture and Electroreduction to Ethylene

288. Scale-Dependent Techno-Economic Analysis of CO2 Capture and Electroreduction to Ethylene

Alerte, T., Gaona, A., Edwards, J. P., Gabardo, C. M., O’Brien, C. P., Wicks, J., Bonnenfant, L., Rasouli, A. S., Young, D., Abed, J., Kershaw, L., Xiao, Y. C., Sarkar, A., Jaffer, S. A., Schreiber, M. W., Sinton, D., MacLean, H. L. & Sargent, E. H. ACS Sustainable Chemistry & Engineering 11, 15651–15662 (2023).

287. Electrified Cement Production via Anion-Mediated Electrochemical Calcium Extraction

287. Electrified Cement Production via Anion-Mediated Electrochemical Calcium Extraction

Miao, R. K., Wang, N., Hung, S.-F., Huang, W.-Y., Zhang, J., Zhao, Y., Ou, P., Wang, S., Edwards, J. P., Tian, C., Han, J., Xu, Y., Fan, M., Huang, J. E., Xiao, Y. C., Ip, A. H., Liang, H., Sargent, E. H. & Sinton, D. ACS Energy Letters 8, 4694–4701 (2023).

286. Direct Membrane Deposition for CO2 Electrolysis

286. Direct Membrane Deposition for CO2 Electrolysis

Alkayyali, T., Zeraati, A. S., Mar, H., Arabyarmohammadi, F., Saber, S., Miao, R. K., O’Brien, C. P., Liu, H., Xie, Z., Wang, G., Sargent, E. H., Zhao, N. & Sinton, D. ACS Energy Letters 8, 4674–4683 (2023).

285. Regeneration of direct air CO2 capture liquid via alternating electrocatalysis

285. Regeneration of direct air CO2 capture liquid via alternating electrocatalysis

Xu, Y., Liu, S., Edwards, J. P., Xiao, Y. C., Zhao, Y., Miao, R. K., Fan, M., Chen, Y., Huang, J. E., Sargent, E. H. & Sinton, D. Joule 7, 2107–2117 (2023).

284. Selective electrochemical synthesis of urea from nitrate and CO2 via relay catalysis on hybrid catalysts

284. Selective electrochemical synthesis of urea from nitrate and CO2 via relay catalysis on hybrid catalysts

Luo, Y., Xie, K., Ou, P., Lavallais, C., Peng, T., Chen, Z., Zhang, Z., Wang, N., Li, X.-Y., Grigioni, I., Liu, B., Sinton, D., Dunn, J. B. & Sargent, E. H. Nature Catalysis 6, 939–948 (2023).

283. Paired Electrosynthesis of H2 and Acetic Acid at A/cm2 Current Densities

283. Paired Electrosynthesis of H2 and Acetic Acid at A/cm2 Current Densities

Tian, C., Li, X.-Y., Nelson, V. E., Ou, P., Zhou, D., Chen, Y., Zhang, J., Huang, J. E., Wang, N., Yu, J., Liu, H., Liu, C., Yang, Y., Peng, T., Zhao, Y., Lee, B.-H., Wang, S., Shirzadi, E., Chen, Z., Miao, R. K., Sinton, D. & Sargent, E. H. ACS Energy Letters 8, 4096–4103 (2023).

282. Cationic-group-functionalized electrocatalysts enable stable acidic CO2 electrolysis.

282. Cationic-group-functionalized electrocatalysts enable stable acidic CO2 electrolysis.

Fan, M., Huang, J. E., Miao, R. K., Mao, Y., Ou, P., Li, F., Li, X.-Y., Cao, Y., Zhang, Z., Zhang, J., Yan, Y., Ozden, A., Ni, W., Wang, Y., Zhao, Y., Chen, Z., Khatir, B., O’Brien, C. P., Xu, Y., Xiao, Y. C., Waterhouse, G. I. N., Golovin, K., Wang, Z., Sargent, E. H. & Sinton, D. Nature Catalysis 6, 763–772 (2023).

281. Early Warning for the Electrolyzer: Monitoring CO2 Reduction via In-Line Electrochemical Impedance Spectroscopy

281. Early Warning for the Electrolyzer: Monitoring CO2 Reduction via In-Line Electrochemical Impedance Spectroscopy

Warkentin, H., O’Brien, C. P., Holowka, S., Maxwell, B., Awara, M., Bouman, M., Zeraati, A. S., Nicholas, R., Ip, A. H., Elsahwi, E. S., Gabardo, C. M. & Sinton, D. ChemSusChem n/a, e202300657

280. Accelerated high-throughput imaging and phenotyping system for small organisms

280. Accelerated high-throughput imaging and phenotyping system for small organisms

Kose, T., Lins, T. F., Wang, J., O’Brien, A. M., Sinton, D. & Frederickson, M. E. PLoS One 18, e0287739 (2023).

279. CO2 electroreduction to multicarbon products from carbonate capture liquid

279. CO2 electroreduction to multicarbon products from carbonate capture liquid

Lee, G., Rasouli, A. S., Lee, B.-H., Zhang, J., Won, D. H., Xiao, Y. C., Edwards, J. P., Lee, M. G., Jung, E. D., Arabyarmohammadi, F., Liu, H., Grigioni, I., Abed, J., Alkayyali, T., Liu, S., Xie, K., Miao, R. K., Park, S., Dorakhan, R., Zhao, Y., O’Brien, C. P., Chen, Z., Sinton, D. & Sargent, E. Joule 7, 1277–1288 (2023).

278. Pressure dependence in aqueous-based electrochemical CO2 reduction

278. Pressure dependence in aqueous-based electrochemical CO2 reduction

Huang, L., Gao, G., Yang, C., Li, X.-Y., Miao, R. K., Xue, Y., Xie, K., Ou, P., Yavuz, C. T., Han, Y., Magnotti, G., Sinton, D., Sargent, E. H. & Lu, X. Nature Communications 14, 2958 (2023).

277. Human sperm cooperate to transit highly viscous regions on the competitive pathway to fertilization

277. Human sperm cooperate to transit highly viscous regions on the competitive pathway to fertilization

Xiao, S., Riordon, J., Lagunov, A., Ghaffarzadeh, M., Hannam, T., Nosrati, R. & Sinton, D. Communications Biology 6, 1–11 (2023).

276. Constrained C2 adsorbate orientation enables CO-to-acetate electroreduction

276. Constrained C2 adsorbate orientation enables CO-to-acetate electroreduction

Jin, J., Wicks, J., Min, Q., Li, J., Hu, Y., Ma, J., Wang, Y., Jiang, Z., Xu, Y., Lu, R., Si, G., Papangelakis, P., Shakouri, M., Xiao, Q., Ou, P., Wang, X., Chen, Z., Zhang, W., Yu, K., Song, J., Jiang, X., Qiu, P., Lou, Y., Wu, D., Mao, Y., Ozden, A., Wang, C., Xia, B. Y., Hu, X., Dravid, V. P., Yiu, Y.-M., Sham, T.-K., Wang, Z., Sinton, D., Mai, L., Sargent, E. H. & Pang, Y. Nature 617, 724–729 (2023).

275. Surface hydroxide promotes CO2 electrolysis to ethylene in acidic conditions

275. Surface hydroxide promotes CO2 electrolysis to ethylene in acidic conditions

Cao, Y., Chen, Z., Li, P., Ozden, A., Ou, P., Ni, W., Abed, J., Shirzadi, E., Zhang, J., Sinton, D., Ge, J. & Sargent, E. H. Nature Communications 14, 2387 (2023).

274. High-throughput sperm DNA analysis at the single-cell and population levels

274. High-throughput sperm DNA analysis at the single-cell and population levels

Simchi, M., Riordon, J., Wang, Y., McCallum, C., You, J. B., Jarvi, K., Nosrati, R. & Sinton, D. Analyst 148, 3748–3757 (2023).

273. Single-site decorated copper enables energy- and carbon-efficient CO2 methanation in acidic conditions

273. Single-site decorated copper enables energy- and carbon-efficient CO2 methanation in acidic conditions

Fan, M., Miao, R. K., Ou, P., Xu, Y., Lin, Z.-Y., Lee, T.-J., Hung, S.-F., Xie, K., Huang, J. E., Ni, W., Li, J., Zhao, Y., Ozden, A., O’Brien, C. P., Chen, Y., Xiao, Y. C., Liu, S., Wicks, J., Wang, X., Abed, J., Shirzadi, E., Sargent, E. H., and Sinton, D. Nature Communications 14, 3314,(2023).

272. Pilot-Scale CO2 Electrolysis Enables a Semi-empirical Electrolyzer Model

272. Pilot-Scale CO2 Electrolysis Enables a Semi-empirical Electrolyzer Model

Edwards, J. P., Alerte, T., O’Brien, C. P., Gabardo, C. M., Liu, S., Wicks, J., Gaona, A., Abed, J., Xiao, Y. C., Young, D., Sedighian Rasouli, A., Sarkar, A., Jaffer, S. A., MacLean, H. L., Sargent, E. H. & Sinton, D. ACS Energy Letters. 2576–2584, (2023), https://doi.org/10.1021/acsenergylett.3c00620

271. Doping shortens the metal/metal distance and promotes OH coverage in non-noble acidic oxygen evolution reaction catalysts

271. Doping shortens the metal/metal distance and promotes OH coverage in non-noble acidic oxygen evolution reaction catalysts

Wang, N., Ou, P., Miao, R. K., Chang, Y., Wang, Z., Hung, S.-F., Abed, J., Ozden, A., Chen, H.-Y., Wu, H.-L., Huang, J. E., Zhou, D., Ni, W., Fan, L, Yan, Y., Peng, T., Sinton, D., Liu, Y., Liang, H., and Sargent, E. H., Journal of the American Chemical Society 145, 14, 7829-7836, (2023), https://doi.org/10.1021/jacs.2c12431

270. Selective synthesis of butane from carbon monoxide using cascade electrolysis and thermocatalysis at ambient conditions

270. Selective synthesis of butane from carbon monoxide using cascade electrolysis and thermocatalysis at ambient conditions

Lee, M. G., Li, X. Y., Ozden, A., Wicks, J., Ou, P., Li., Y., Dorakhan, R., Lee, J., Park, H. K., Yang, J. W., Chen, B., Abed, J., dos Reis, R., Lee, G., Huang, J. E., Peng, T., Chin, Y.-H., Sinton, D., Sargent, E. H., Nature Catalysis, 1-9, (2023), https://doi.org/10.1038/s41929-023-00937-0

269. A silver-copper oxide catalyst for acetate electrosynthesis from carbon monoxide

269. A silver-copper oxide catalyst for acetate electrosynthesis from carbon monoxide

Dorakhan, R., Grigioni, I., Lee, B. H., Ou, P., Abed, J., O’Brien, C., Rasouli, A. S., Plodinec, M., Miao, R. K., Shirzadi, E., Wicks, J., Park, S., Lee, G., Zhang, J., Sinton, D., and Sargent, E. H., Nature Synthesis 1-10, (2023), https://doi.org/10.1038/s44160-023-00259-w

268. Strong-proton-adsorption co-based electrocatalysts achieve active and stable neutral seawater splitting

268. Strong-proton-adsorption co-based electrocatalysts achieve active and stable neutral seawater splitting

Wang, N., Ou, P., Hung, S.-F., Huang, J. E., Ozden, A., Abed, J., Grigioni, I., Chen, C., Miao, R. K., Yan, Y., Zhang, J., Wang, Z., Dorakhan, R., Badreldin, A., Abdel-Wahab A., Sinton, D., Liu, Y., Liang, H., and Sargent, E. H., Advanced Materials, https://doi.org/10.1002/adma.202210057

267. Coordination polymer electrocatalysts enable efficient CO-to-acetate conversion

267. Coordination polymer electrocatalysts enable efficient CO-to-acetate conversion

Luo, M., Ozden, A., Wang, Z., Li, F., Huang, J. E., H. S.-F., Wang, Y., Li, J., Nam, D.-H., Li Y. C., Xu, Y., Lu, R., Zhang, S., Lum, Y., Ren, Y., Fan, L. Wang, F., Li, H.-H., Appadoo, D., Dinh, C.-T., Liu, Y., Chen, B., Wicks, J., Chen, H., Sinton, D., and Sargent, E. H., Advanced Materials 35, 10, (2023), https://doi.org/10.1002/adma.202209567

266. Supramolecular tuning of supported metal phthalocyanine catalysis for hydrogen peroxide electrosynthesis

266. Supramolecular tuning of supported metal phthalocyanine catalysis for hydrogen peroxide electrosynthesis

Lee, B.-H., Shin, H., Rasouli, A. S., Choubisa, H., Ou, P., Dorakhan, R., Grigioni, I., Lee, G., Shirzadi, E., Miao, R. K., Wicks, J., Park, S., Lee, H. S., Zhang, J., Chen, Y., Chen, Z., Sinton, D., Hyeon, T., Sung, Y.-E., and Sargent, E. H., Nature Catalysis 6, 3, 234-243, (2023), https://doi.org/10.1038/s41929-023-00924-5

265. Rheological Behavior of Phase Change Slurries for Thermal Energy Applications

265. Rheological Behavior of Phase Change Slurries for Thermal Energy Applications

McPhee, H., Soni, V., Saber, S., Zargartalebi, M., Riordon, J., Holmes, M., Toews, M., and Sinton, D. Langmuir 39, 129–141, (2023), https://doi.org/10.1021/acs.langmuir.2c02279

264. Lab on a chip for a low-carbon future

264. Lab on a chip for a low-carbon future

Datta, S. S., Battiato, I., Fernø, M. A., Juanes, R., Parsa, S., Prigiobbe, V., Santanach-Carreras, E., Song, W., Biswal, S. L., and Sinton, D., Lab on a Chip, 2023, doi:10.1039/D2LC00020B

263. Conversion of CO2 to multicarbon products in strong acid by controlling the catalyst microenvironment

263. Conversion of CO2 to multicarbon products in strong acid by controlling the catalyst microenvironment

Zhao, Y., Hao, L., Ozden, A., Liu, S., Miao, R. K., Ou, P., Alkayyali, T., Zhang, S., Ning, J., Liang, Y., Xu, Y., Fan, M., Chen, Y., Huang, J. E., Xie, K., Zhang, J., O’Brien, C. P., Li, F., Sargent, E. H., and Sinton, D., Nature Synthesis 1–10, (2023), doi:10.1038/s44160-022-00234-x

262. Analysis of the evaporation coefficients of water, heavy water, and methanol in a high vacuum environment.

262. Analysis of the evaporation coefficients of water, heavy water, and methanol in a high vacuum environment.

Kazemi, M. A., Zandavi, S. H., Zargartalebi, M., Sinton, D., and Elliott, J. A. W. International Journal of Heat and Mass Transfer 204, 123833, (2023), doi: 10.1016/j.ijheatmasstransfer.2022.123833

261. Energy- and carbon-efficient CO2/CO electrolysis to multicarbon products via asymmetric ion migration–adsorption

261. Energy- and carbon-efficient CO2/CO electrolysis to multicarbon products via asymmetric ion migration–adsorption

Ozden, A., Li, J., Kandambeth, S., Li, X.-Y., Liu, S., Shekhah, O., Ou, P., Zou Finfrock, Y., Wang, Y.-K., Alkayyali, T., Pelayo García de Arquer, F., Kale, V. S., Bhatt, P. M., Ip, A. H., Eddaoudi, M., Sargent, E. H., and Sinton, D., Nature Energy 1–12, (2023), doi:10.1038/s41560-022-01188-2