2025

340. Passive direct air capture via evaporative carbonate crystallization

340. Passive direct air capture via evaporative carbonate crystallization

Kim, D., Liu, S., Devasagayam, T., Miao, R. K., Kim, J., Lee, H. S., Gao, Y., Golovin, K., Scheidt, T., Sinton, D., Nature Chemical Engineering 1–11 (2025).

339. Accurate and rapid measurement of fluid thermal conductivity

339. Accurate and rapid measurement of fluid thermal conductivity

Kazemi, A., Zargartalebi, M., Sinton, D., Nature Communications 16, 10531 (2025).

338. Efficient amino-acid-based reactive capture of CO2 via nickel molecular catalyst

338. Efficient amino-acid-based reactive capture of CO2 via nickel molecular catalyst

Guo, Z., Li, F., Xiao, Y. C., Hung, S.-F., Lu, Y.-R., Foroozan, A., Liu, J., Sun, S. S., Liu, S., Che, Y., Wang, Q., Liu, M., Wang, C., Li, Y., Peng, K.-S., Liu, Y.-C., Fan, M., Azimi Dijvejin, Z., Papangelakis, P., Wang, Y., Shayesteh Zeraati, A., Han, K., Corbett, P., Higgins, D., Miao, R. K., Sinton, D., Nature Communications 16, 10373 (2025).

337. Accelerated discovery of CO2-to-C3-hydrocarbon electrocatalysts with human-in-the-loop

337. Accelerated discovery of CO2-to-C3-hydrocarbon electrocatalysts with human-in-the-loop

Kim, J., Mahesh, S., Lee, H. S., Dorakhan, R., Bai, Y., Imran, M., Li, K., Liu, Y., Kim, D., Park, S., Zeraati, A. S., Moon, H. S., Li, X., Arabyarmohammadi, F., Abed, J., Wander, B., Wu, C., Liu, S., Xiao, Y. C., Miao, R. K., Hoogland, S., Hattrick-Simpers, J., Sargent, E. H., Sinton, D., Joule (2025).

336. Ambipolar Ion Transport Membranes Enable Stable Noble-Metal-Free CO2 Electrolysis in Neutral Media

336. Ambipolar Ion Transport Membranes Enable Stable Noble-Metal-Free CO2 Electrolysis in Neutral Media

Pham, T. H., Lai, H. D. T., Dang, N. K., Nguyen, T. N., Golovanova, V., Dias, E. H., Ho, A.-D., Xia, L., Crane, J., de Arquer, F. P. G., Sargent, E. H., Sinton, D., Dinh, C.-T., Advanced Energy Materials (2025).

335. Closed-loop geothermal system is a potential source of low-carbon renewable energy

335. Closed-loop geothermal system is a potential source of low-carbon renewable energy

Zargartalebi, M., Darzi, A., Kazemi, A., Sinton, D., Communications Earth & Environment 6, 812 (2025).

334. Hydroxyl-mediated interfacial oxophilicity engineering for efficient CO2-to-C2+ oxygenates conversion at industrial current densities

334. Hydroxyl-mediated interfacial oxophilicity engineering for efficient CO2-to-C2+ oxygenates conversion at industrial current densities

Wang, L., Yao, X., Jana, S., Wu, C., Chen, N., Singh, C. V., Sinton, D., Wu, Y. A., Applied Catalysis B: Environment and Energy 383, 126133 (2026).

333. Co-electroreduction of CO and glyoxal promotes C3 products

333. Co-electroreduction of CO and glyoxal promotes C3 products

Dorakhan, R., Sarkar, S., Shirzadi, E., Abbas, H. G., Shayesteh, A., Park, S., Huang, J. E., Sinton, D., Sargent, E. H., Nature Chemistry 1–9 (2025).

332. Metric-based evaluation of electric vehicle battery immersion coolants

332. Metric-based evaluation of electric vehicle battery immersion coolants

Rezaei, H., Rajabi-Kochi, M., Ebrahimiazar, M., Zargartalebi, M., Moosavi, S. M., Sinton, D., Journal of Energy Storage 140, 119036 (2025).

331. Direct Electrosynthesis of C3+ Hydrocarbons from CO2 via Size-Controlled Nickel Nanoislands on a Carbon Support

331. Direct Electrosynthesis of C3+ Hydrocarbons from CO2 via Size-Controlled Nickel Nanoislands on a Carbon Support

Vafaie, M., Dorakhan, R., Morteza Najarian, A., Teimouri, Z., Pofelski, A., Barati, N., Chou, C.-H., Chang, Y.-C., Hung, S.-F., Sun, Q., Azimi Dijvejin, Z., Ngunjiri, R., Li, Y., Shayesteh Zeraati, A., Salem, K. E., Miao, R. K., Hoogland, S., Higgins, D., Sargent, E. H., Sinton, D., Journal of the American Chemical Society 147, 40454–40465 (2025).

330. Electrosynthesis of ethanol via CO-CHx cross-coupling on copper alloy catalysts with engineered oxygen affinity

330. Electrosynthesis of ethanol via CO-CHx cross-coupling on copper alloy catalysts with engineered oxygen affinity

Liu, P., Sun, N., Su, J., Wang, Y., Peng, Z., Chen, S., Papangelakis, P., Ozden, A., Miao, R. K., Wang, X., Xu, Y., Zeng, J., Wang, H., Liu, H., Zhao, Y., Shi, S., Shakouri, M., Liang, H., Wang, Z., Zhang, H., Hu, Y., Yao, Z., Sinton, D., Li, J., Nature Synthesis 4, 1462–1472 (2025).

329. CO electrolysers with 51% energy efficiency towards C2+ using porous separators

329. CO electrolysers with 51% energy efficiency towards C2+ using porous separators

Miao, R. K., Fan, M., Wang, N., Zhao, Y., Li, F., Liu, M., Arabyarmohammadi, F., Liang, Y., Ni, W., Xie, K., Chen, Y., Sun, P., Huang, J. E., Wu, J., Kim, J., O’Brien, C. P., Xiao, Y. C., Guo, Z., Papangelakis, P., Shayesteh Zeraati, A., Xu, Y., Dinh, C.-T., Sargent, E. H., Sinton, D., Nature Energy 1–8 (2025).

328. Voltage distribution within carbon dioxide reduction electrolysers

328. Voltage distribution within carbon dioxide reduction electrolysers

Arabyarmohammadi, F., Miao, R. K., Zeraati, A. S., Zargartalebi, M., O’Brien, C. P., Dorakhan, R., Alkayyali, T., Lee, G., Fan, M., Abed, J., Li, F., Sargent, E. H., Sinton, D., Nature Sustainability 1–9 (2025).

327. High-Nuclearity Copper Molecular Catalysts for Electrocatalytic CO-to-Acetate Conversion

327. High-Nuclearity Copper Molecular Catalysts for Electrocatalytic CO-to-Acetate Conversion

Bodiuzzaman, M., Fan, L., M Halappa, N., Chen, Y., Yan, Y., Thomas, S., Miao, R. K., Xiao, Y. C., Wu, J., Dorakhan, R., Abulikemu, M., El Tall, O., Sinton, D., Alshareef, H. N., Mohammed, O. F., Sargent, E. H., Bakr, O. M., Journal of the American Chemical Society 147, 31713–31721 (2025).

326. Enduring CO Electrolysis with Ampere-Level Reaction Rates Using Nickel-Doped Iridium Catalysts

326. Enduring CO Electrolysis with Ampere-Level Reaction Rates Using Nickel-Doped Iridium Catalysts

Liu, H., Ozden, A., Lu, R., Sun, N., Miao, R. K., Yao, K., Xie, R., Xu, Y., Zhang, H., Hu, Y., Wang, Z., Li, J., Sinton, D., Journal of the American Chemical Society 147, 30, 26595–26604 (2025).

325. Screening biodegradable alternatives to mineral oil coolants

325. Screening biodegradable alternatives to mineral oil coolants

Dekkers, M., Ebrahimiazar, M., Kazemi, A., Zargartalebi, M., Sinton, D., Energy Conversion and Management 338, 119848 (2025).

324. Scaled CO Electroreduction to Alcohols

324. Scaled CO Electroreduction to Alcohols

Papangelakis, P., O’Brien, C. P., Shayesteh Zeraati, A., Liu, S., Paik, A., Nelson, V., Park, S., Xiao, Y. C., Dorakhan, R., Sun, P., Wu, J., Gabardo, C. M., Wang, N., Miao, R. K., Sargent, E. H., Sinton, D., Nature Communications 16, 1, 4969 (2025).

323. Rapid screening of CO2 capture fluids

323. Rapid screening of CO2 capture fluids

Guo, Y., Li, F., Saber, S., Zargartalebi, M., Sonia Sun, S., Celine Xiao, Y., Bao, B., Xu, Z., Sinton, D., Lab on a Chip 25, 12, 2918-2925 (2025).

322. A redox-active polymeric network facilitates electrified reactive-capture electrosynthesis to multi-carbon products from dilute CO2-containing streams

322. A redox-active polymeric network facilitates electrified reactive-capture electrosynthesis to multi-carbon products from dilute CO2-containing streams

Zhang, J., Cao, Y., Ou, P., Lee, G., Zhao, Y., Liu, S., Shirzadi, E., Dorakhan, R., Xie, K., Tian, C., Chen, Y., Li, X., Xiao, Y. C., Shayesteh Zeraati, A., Miao, R. K., Park, S., O’Brien, C. P., Ge, J., Zhou, X., Sinton, D., Sargent, E. H., Nature Communications 16, 1, 3553 (2025).

321. Isolated iridium oxide sites on modified carbon nitride for photoreforming of plastic derivatives

321. Isolated iridium oxide sites on modified carbon nitride for photoreforming of plastic derivatives

Kumar, P., Zhang, H., Yohannes, A. G., Wang, J., Shayesteh Zeraati, A., Roy, S., Wang, X., Kannimuthu, K., Askar, A. M., Miller, K. A., Ling, K., Adnan, M., Hung, S.-F., Ma, J.-J., Huang, W.-H., Trivedi, D., Molina, M., Zhao, H., Martí, A. A., Leontowich, A. F. G., Shimizu, G. K. H., Sinton, D., Adachi, M. M., Wu, Y. A., Ajayan, P. M., Siahrostami, S., Hu, J., Kibria, M. G., Nature Communications 16, 2862 (2025).

320. Electrified synthesis of n-propanol using a dilute alloy catalyst

320. Electrified synthesis of n-propanol using a dilute alloy catalyst

Chen, Y., Wang, X., Li, X.-Y., Miao, R. K., Dong, J., Zhao, Z., Liu, C., Huang, J. E., Wu, J., Chu, S., Ni, W., Guo, Z., Xu, Y., Ou, P., Xu, B., Hou, Y., Sinton, D., Sargent, E. H., Nature Catalysis 1–9 (2025).

319. Molecular Structure of Omniphobic, Surface-Grafted Polydimethylsiloxane Chains

319. Molecular Structure of Omniphobic, Surface-Grafted Polydimethylsiloxane Chains

Khatir, B., Lin, A., Vuong, T. V., Serles, P., Shayesteh, A., Hsu, N. S. Y., Sinton, D., Tran, H., Master, E. R., Filleter, T., Golovin, K., Small 21, 8, 2406089 (2025).

318. Carbon- and energy-efficient ethanol electrosynthesis via interfacial cation enrichment

318. Carbon- and energy-efficient ethanol electrosynthesis via interfacial cation enrichment

Shayesteh Zeraati, A., Li, F., Alkayyali, T., Dorakhan, R., Shirzadi, E., Arabyarmohammadi, F., O’Brien, C. P., Gabardo, C. M., Kong, J., Ozden, A., Zargartalebi, M., Zhao, Y., Fan, L., Papangelakis, P., Kim, D., Park, S., Miao, R. K., Edwards, J. P., Young, D., Ip, A. H., Sargent, E. H., Sinton, D., Nature Synthesis 4, 75-83 (2025).

317. Atomic-level Cu active sites enable energy-efficient CO2 electroreduction to multicarbon products in strong acid

317. Atomic-level Cu active sites enable energy-efficient CO2 electroreduction to multicarbon products in strong acid

Fan, L., Li, F., Liu, T., Huang, J. E., Miao, R. K., Yan, Y., Feng, S., Tai, C.-W., Hung, S.-F., Tsai, H.-J., Chen, M.-C., Bai, Y., Kim, D., Park, S., Papangelakis, P., Wu, C., Shayesteh Zeraati, A., Dorakhan, R., Sun, L., Sinton, D., Sargent, E., Nature Synthesis 4, 262–270 (2025).