| Year |
Citation |
Score |
| 2020 |
Digdaya IA, Sullivan I, Lin M, Han L, Cheng WH, Atwater HA, Xiang C. A direct coupled electrochemical system for capture and conversion of CO from oceanwater. Nature Communications. 11: 4412. PMID 32887872 DOI: 10.1038/S41467-020-18232-Y |
0.361 |
|
| 2020 |
Chen Y, Lewis NS, Xiang C. Modeling the Performance of A Flow-Through Gas Diffusion Electrode for Electrochemical Reduction of CO or CO2 Journal of the Electrochemical Society. 167: 114503. DOI: 10.1149/1945-7111/Ab987A |
0.486 |
|
| 2020 |
Cheng W, Richter MH, Sullivan I, Larson DM, Xiang C, Brunschwig BS, Atwater HA. CO2 Reduction to CO with 19% Efficiency in a Solar-Driven Gas Diffusion Electrode Flow Cell under Outdoor Solar Illumination Acs Energy Letters. 5: 470-476. DOI: 10.1021/Acsenergylett.9B02576 |
0.305 |
|
| 2020 |
Lee SH, Sullivan I, Larson DM, Liu G, Toma FM, Xiang C, Drisdell WS. Correlating Oxidation State and Surface Area to Activity from Operando Studies of Copper CO Electroreduction Catalysts in a Gas-Fed Device Acs Catalysis. 10: 8000-8011. DOI: 10.1021/Acscatal.0C01670 |
0.317 |
|
| 2019 |
Sullivan I, Han L, Lee SH, Lin M, Larson DM, Drisdell WS, Xiang C. A Hybrid Catalyst-Bonded Membrane Device for Electrochemical Carbon Monoxide Reduction at Different Relative Humidities Acs Sustainable Chemistry & Engineering. 7: 16964-16970. DOI: 10.1021/Acssuschemeng.9B04959 |
0.34 |
|
| 2019 |
Ho A, Zhou X, Han L, Sullivan I, Karp C, Lewis NS, Xiang C. Decoupling H2(g) and O2(g) Production in Water Splitting by a Solar-Driven V3+/2+(aq,H2SO4)|KOH(aq) Cell Acs Energy Letters. 4: 968-976. DOI: 10.1021/Acsenergylett.9B00278 |
0.483 |
|
| 2018 |
Higgins D, Hahn C, Xiang C, Jaramillo TF, Weber AZ. Gas-Diffusion Electrodes for Carbon Dioxide Reduction: A New Paradigm Acs Energy Letters. 4: 317-324. DOI: 10.1021/Acsenergylett.8B02035 |
0.301 |
|
| 2018 |
Zhou X, Xiang C. Comparative Analysis of Solar-to-Fuel Conversion Efficiency: A Direct, One-Step Electrochemical CO2 Reduction Reactor versus a Two-Step, Cascade Electrochemical CO2 Reduction Reactor Acs Energy Letters. 3: 1892-1897. DOI: 10.1021/Acsenergylett.8B01077 |
0.311 |
|
| 2018 |
Han L, Zhou W, Xiang C. High-Rate Electrochemical Reduction of Carbon Monoxide to Ethylene Using Cu-Nanoparticle-Based Gas Diffusion Electrodes Acs Energy Letters. 3: 855-860. DOI: 10.1021/Acsenergylett.8B00164 |
0.344 |
|
| 2017 |
Jiang J, Huang Z, Xiang C, Poddar R, Lewerenz HJ, Papadantonakis KM, Lewis N, Brunschwig B. Nanoelectrical and Nanoelectrochemical Imaging of Pt/p-Si and Pt/p+-Si Electrodes. Chemsuschem. PMID 28636780 DOI: 10.1002/Cssc.201700893 |
0.497 |
|
| 2017 |
Nellist MR, Chen Y, Mark A, Gödrich S, Stelling C, Jiang J, Poddar R, Li C, Kumar R, Papastavrou G, Retsch M, Brunschwig BS, Huang Z, Xiang C, Boettcher SW. Atomic force microscopy with nanoelectrode tips for high resolution electrochemical, nanoadhesion and nanoelectrical imaging. Nanotechnology. 28: 095711. PMID 28139467 DOI: 10.1088/1361-6528/Aa5839 |
0.372 |
|
| 2017 |
Singh MR, Xiang C, Lewis NS. Evaluation of flow schemes for near-neutral pH electrolytes in solar-fuel generators Sustainable Energy & Fuels. 1: 458-466. DOI: 10.1039/C7Se00062F |
0.448 |
|
| 2016 |
Xiang C, Weber AZ, Ardo S, Berger A, Chen Y, Coridan R, Fountaine KT, Haussener S, Hu S, Liu R, Lewis NS, Modestino MA, Shaner MM, Singh MR, Stevens JC, et al. Modeling, Simulation, and Implementation of Solar-Driven Water-Splitting Devices. Angewandte Chemie (International Ed. in English). PMID 27460923 DOI: 10.1002/Anie.201510463 |
0.488 |
|
| 2016 |
Xiang C, Papadantonakis KM, Lewis NS. Principles and implementations of electrolysis systems for water splitting Materials Horizons. 3: 169-173. DOI: 10.1039/C6Mh00016A |
0.437 |
|
| 2016 |
Chen Y, Lewis NS, Xiang C. Modeling and Simulation of the Spatial and Light-Intensity Dependence of Product Distributions in an Integrated Photoelectrochemical CO2 Reduction System Acs Energy Letters. 1: 273-280. DOI: 10.1021/Acsenergylett.6B00134 |
0.491 |
|
| 2016 |
Huang Z, De Wolf P, Poddar R, Li C, Mark A, Nellist MR, Chen Y, Jiang J, Papastavrou G, Boettcher SW, Xiang C, Brunschwig BS. PeakForce Scanning Electrochemical Microscopy with Nanoelectrode Probes Microscopy Today. 24: 18-25. DOI: 10.1017/S1551929516000882 |
0.31 |
|
| 2016 |
Xiang C, Weber AZ, Ardo S, Berger A, Chen Y, Coridan R, Fountaine KT, Haussener S, Hu S, Liu R, Lewis NS, Modestino MA, Shaner MM, Singh MR, Stevens JC, et al. Modellierung, Simulation und Implementierung von Zellen für die solargetriebene Wasserspaltung Angewandte Chemie. 128: 13168-13183. DOI: 10.1002/Ange.201510463 |
0.386 |
|
| 2016 |
Sun K, Liu R, Chen Y, Verlage E, Lewis NS, Xiang C. Solar-Driven Water Splitting: A Stabilized, Intrinsically Safe, 10% Efficient, Solar-Driven Water-Splitting Cell Incorporating Earth-Abundant Electrocatalysts with Steady-State pH Gradients and Product Separation Enabled by a Bipolar Membrane (Adv. Energy Mater. 13/2016) Advanced Energy Materials. 6. DOI: 10.1002/Aenm.201670077 |
0.463 |
|
| 2016 |
Sun K, Liu R, Chen Y, Verlage E, Lewis NS, Xiang C. A Stabilized, Intrinsically Safe, 10% Efficient, Solar-Driven Water-Splitting Cell Incorporating Earth-Abundant Electrocatalysts with Steady-State pH Gradients and Product Separation Enabled by a Bipolar Membrane Advanced Energy Materials. 6. DOI: 10.1002/Aenm.201600379 |
0.49 |
|
| 2015 |
Walczak K, Chen Y, Karp C, Beeman JW, Shaner M, Spurgeon J, Sharp ID, Amashukeli X, West W, Jin J, Lewis NS, Xiang C. Modeling, simulation, and fabrication of a fully integrated, acid-stable, scalable solar-driven water-splitting system. Chemsuschem. 8: 544-51. PMID 25581231 DOI: 10.1002/Cssc.201402896 |
0.532 |
|
| 2015 |
Jones RJ, Shinde A, Guevarra D, Xiang C, Haber JA, Jin J, Gregoire JM. Parallel electrochemical treatment system and application for identifying acid-stable oxygen evolution electrocatalysts. Acs Combinatorial Science. 17: 71-5. PMID 25561243 DOI: 10.1021/Co500148P |
0.343 |
|
| 2015 |
Chen Y, Lewis NS, Xiang C. Operational constraints and strategies for systems to effect the sustainable, solar-driven reduction of atmospheric CO2 Energy and Environmental Science. 8: 3663-3674. DOI: 10.1039/C5Ee02908B |
0.479 |
|
| 2015 |
Verlage E, Hu S, Liu R, Jones RJR, Sun K, Xiang C, Lewis NS, Atwater HA. A monolithically integrated, intrinsically safe, 10% efficient, solar-driven water-splitting system based on active, stable earth-abundant electrocatalysts in conjunction with tandem III-V light absorbers protected by amorphous TiO2 films Energy and Environmental Science. 8: 3166-3172. DOI: 10.1039/C5Ee01786F |
0.513 |
|
| 2015 |
Singh MR, Papadantonakis K, Xiang C, Lewis NS. An electrochemical engineering assessment of the operational conditions and constraints for solar-driven water-splitting systems at near-neutral pH Energy and Environmental Science. 8: 2760-2767. DOI: 10.1039/C5Ee01721A |
0.491 |
|
| 2015 |
Chen Y, Sun K, Audesirk H, Xiang C, Lewis NS. A quantitative analysis of the efficiency of solar-driven water-splitting device designs based on tandem photoabsorbers patterned with islands of metallic electrocatalysts Energy and Environmental Science. 8: 1736-1747. DOI: 10.1039/C5Ee00311C |
0.538 |
|
| 2015 |
Chen Y, Hu S, Xiang C, Lewis NS. A sensitivity analysis to assess the relative importance of improvements in electrocatalysts, light absorbers, and system geometry on the efficiency of solar-fuels generators Energy and Environmental Science. 8: 876-886. DOI: 10.1039/C4Ee02314E |
0.48 |
|
| 2014 |
Xiang C, Haber J, Marcin M, Mitrovic S, Jin J, Gregoire JM. Mapping quantum yield for (Fe-Zn-Sn-Ti)Ox photoabsorbers using a high throughput photoelectrochemical screening system. Acs Combinatorial Science. 16: 120-7. PMID 24471712 DOI: 10.1021/Co400081W |
0.357 |
|
| 2014 |
Gregoire JM, Haber JA, Mitrovic S, Xiang C, Suram S, Newhouse PF, Soedarmadji E, Marcin M, Kan K, Guevarra D, Jones R, Becerra N, Cornell EW, Jin J. Enabling solar fuels technology with high throughput experimentation Materials Research Society Symposium Proceedings. 1654. DOI: 10.1557/Opl.2014.29 |
0.32 |
|
| 2014 |
Chen Y, Xiang C, Hu S, Lewis NS. Modeling the performance of an integrated photoelectrolysis system with 10× solar concentrators Journal of the Electrochemical Society. 161: F1101-F1110. DOI: 10.1149/2.0751410Jes |
0.522 |
|
| 2014 |
Jin J, Walczak K, Singh MR, Karp C, Lewis NS, Xiang C. An experimental and modeling/simulation-based evaluation of the efficiency and operational performance characteristics of an integrated, membrane-free, neutral pH solar-driven water-splitting system Energy and Environmental Science. 7: 3371-3380. DOI: 10.1039/C4Ee01824A |
0.526 |
|
| 2014 |
Huang Z, Xiang C, Lewerenz HJ, Lewis NS. Two stories from the ISACS 12 conference: Solar-fuel devices and catalyst identification Energy and Environmental Science. 7: 1207-1211. DOI: 10.1039/C3Ee90043F |
0.453 |
|
| 2014 |
Haber JA, Cai Y, Jung S, Xiang C, Mitrovic S, Jin J, Bell AT, Gregoire JM. Discovering Ce-rich oxygen evolution catalysts, from high throughput screening to water electrolysis Energy and Environmental Science. 7: 682-688. DOI: 10.1039/C3Ee43683G |
0.308 |
|
| 2014 |
Huang Z, McKone JR, Xiang C, Grimm RL, Warren EL, Spurgeon JM, Lewerenz HJ, Brunschwig BS, Lewis NS. Comparison between the measured and modeled hydrogen-evolution activity of Ni- or Pt-coated silicon photocathodes International Journal of Hydrogen Energy. 39: 16220-16226. DOI: 10.1016/J.Ijhydene.2013.12.162 |
0.505 |
|
| 2013 |
Gregoire JM, Xiang C, Liu X, Marcin M, Jin J. Scanning droplet cell for high throughput electrochemical and photoelectrochemical measurements. The Review of Scientific Instruments. 84: 024102. PMID 23464227 DOI: 10.1063/1.4790419 |
0.335 |
|
| 2013 |
Gregoire JM, Xiang C, Mitrovic S, Liu X, Marcin M, Cornell EW, Fan J, Jin J. Combined catalysis and optical screening for high throughput discovery of solar fuels catalysts Journal of the Electrochemical Society. 160: F337-F342. DOI: 10.1149/2.035304Jes |
0.318 |
|
| 2013 |
Xiang C, Chen Y, Lewis NS. Modeling an integrated photoelectrolysis system sustained by water vapor Energy and Environmental Science. 6: 3713-3721. DOI: 10.1039/C3Ee42143K |
0.489 |
|
| 2013 |
Haussener S, Hu S, Xiang C, Weber AZ, Lewis NS. Simulations of the irradiation and temperature dependence of the efficiency of tandem photoelectrochemical water-splitting systems Energy and Environmental Science. 6: 3605-3618. DOI: 10.1039/C3Ee41302K |
0.509 |
|
| 2013 |
Hu S, Xiang C, Haussener S, Berger AD, Lewis NS. An analysis of the optimal band gaps of light absorbers in integrated tandem photoelectrochemical water-splitting systems Energy and Environmental Science. 6: 2984-2993. DOI: 10.1039/C3Ee40453F |
0.504 |
|
| 2012 |
Xiang C, Meng AC, Lewis NS. Evaluation and optimization of mass transport of redox species in silicon microwire-array photoelectrodes. Proceedings of the National Academy of Sciences of the United States of America. 109: 15622-7. PMID 22904185 DOI: 10.1073/Pnas.1118338109 |
0.537 |
|
| 2012 |
Wilson SS, Xiang C, Tolstova Y, Lewis NS, Atwater HA. Thin, free-standing Cu2O substrates via thermal oxidation for photovoltaic devices Conference Record of the Ieee Photovoltaic Specialists Conference. 3191-3194. DOI: 10.1109/PVSC.2012.6318256 |
0.378 |
|
| 2012 |
Haussener S, Xiang C, Spurgeon JM, Ardo S, Lewis NS, Weber AZ. Modeling, simulation, and design criteria for photoelectrochemical water-splitting systems Energy and Environmental Science. 5: 9922-9935. DOI: 10.1039/C2Ee23187E |
0.484 |
|
| 2011 |
Xiang C, Kimball GM, Grimm RL, Brunschwig BS, Atwater HA, Lewis NS. 820 mV open-circuit voltages from Cu2O/CH3CN junctions Energy and Environmental Science. 4: 1311-1318. DOI: 10.1039/C0Ee00554A |
0.512 |
|
| 2009 |
Yang Y, Taggart DK, Brown MA, Xiang C, Kung SC, Yang F, Hemminger JC, Penner RM. Wafer-scale patterning of lead telluride nanowires: structure, characterization, and electrical properties. Acs Nano. 3: 4144-54. PMID 19950888 DOI: 10.1021/Nn901173P |
0.765 |
|
| 2009 |
Halpern AR, Nishi N, Wen J, Yang F, Xiang C, Penner RM, Corn RM. Characterization of electrodeposited gold and palladium nanowire gratings with optical diffraction measurements. Analytical Chemistry. 81: 5585-92. PMID 19537714 DOI: 10.1021/Ac900938T |
0.637 |
|
| 2009 |
Xiang C, Kim JY, Penner RM. Reconnectable sub-5 nm nanogaps in ultralong gold nanowires. Nano Letters. 9: 2133-8. PMID 19366192 DOI: 10.1021/Nl900698S |
0.607 |
|
| 2009 |
Xiang C, Yang Y, Penner RM. Cheating the diffraction limit: electrodeposited nanowires patterned by photolithography. Chemical Communications (Cambridge, England). 859-73. PMID 19214304 DOI: 10.1039/B815603D |
0.631 |
|
| 2008 |
Xiang C, Kung SC, Taggart DK, Yang F, Thompson MA, Güell AG, Yang Y, Penner RM. Lithographically patterned nanowire electrodeposition: a method for patterning electrically continuous metal nanowires on dielectrics. Acs Nano. 2: 1939-49. PMID 19206435 DOI: 10.1021/Nn800394K |
0.757 |
|
| 2008 |
Xiang C, Güell AG, Brown MA, Kim JY, Hemminger JC, Penner RM. Coupled electrooxidation and electrical conduction in a single gold nanowire. Nano Letters. 8: 3017-22. PMID 18712931 DOI: 10.1021/Nl8021175 |
0.571 |
|
| 2008 |
Kim H, Taggart DK, Xiang C, Penner RM, Potma EO. Spatial control of coherent anti-stokes emission with height-modulated gold zig-zag nanowires. Nano Letters. 8: 2373-7. PMID 18662040 DOI: 10.1021/Nl801207A |
0.686 |
|
| 2008 |
Yang Y, Kung SC, Taggart DK, Xiang C, Yang F, Brown MA, Güell AG, Kruse TJ, Hemminger JC, Penner RM. Synthesis of PbTe nanowire arrays using lithographically patterned nanowire electrodeposition. Nano Letters. 8: 2447-51. PMID 18624390 DOI: 10.1021/Nl801442C |
0.763 |
|
| 2008 |
Kim H, Xiang C, Güell AG, Penner RM, Potma EO. Tunable two-photon excited luminescence in single gold nanowires fabricated by lithographically patterned nanowire electrodeposition Journal of Physical Chemistry C. 112: 12721-12727. DOI: 10.1021/Jp8032758 |
0.596 |
|
| 2006 |
Menke EJ, Thompson MA, Xiang C, Yang LC, Penner RM. Lithographically patterned nanowire electrodeposition. Nature Materials. 5: 914-9. PMID 17057701 DOI: 10.1002/Pssc.200779406 |
0.756 |
|
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