about
Biofunctionalized conductive polymers enable efficient CO2 electroreduction.Efficient and stable solution-processed planar perovskite solar cells via contact passivation.Combinatorial Probes for High-Throughput Electrochemical Analysis of Circulating Nucleic Acids in Patient Samples.Hydronium-Induced Switching between CO2 Electroreduction Pathways.Multibandgap quantum dot ensembles for solar-matched infrared energy harvestingProgrammable Metal/Semiconductor Nanostructures for mRNA-Modulated Molecular DeliveryThe quantum-confined Stark effect in layered hybrid perovskites mediated by orientational polarizability of confined dipolesCopper adparticle enabled selective electrosynthesis of n-propanolCopper-on-nitride enhances the stable electrosynthesis of multi-carbon products from CODipolar cations confer defect tolerance in wide-bandgap metal halide perovskitesChallenges for commercializing perovskite solar cellsColor-stable highly luminescent sky-blue perovskite light-emitting diodesPulsed axial epitaxy of colloidal quantum dots in nanowires enables facet-selective passivationPrismatic Deflection of Live Tumor Cells and Cell ClustersCompositional and orientational control in metal halide perovskites of reduced dimensionalityCurvature-Mediated Surface Accessibility Enables Ultrasensitive Electrochemical Human Methyltransferase AnalysisMetal–Organic Framework Thin Films on High-Curvature Nanostructures Toward Tandem ElectrocatalysisCO2electroreduction to ethylene via hydroxide-mediated copper catalysis at an abrupt interfaceAcid-Assisted Ligand Exchange Enhances Coupling in Colloidal Quantum Dot SolidsPrecise Control of Thermal and Redox Properties of Organic Hole-Transport MaterialsDopant-induced electron localization drives CO2 reduction to C2 hydrocarbonsMetal–Organic Frameworks Mediate Cu Coordination for Selective CO2 ElectroreductionContactless measurements of photocarrier transport properties in perovskite single crystalsNanostructured Back Reflectors for Efficient Colloidal Quantum-Dot Infrared Optoelectronics.Photochemically Cross-Linked Quantum Well Ligands for 2D/3D Perovskite Photovoltaics with Improved Photovoltage and StabilityMonolithic all-perovskite tandem solar cells with 24.8% efficiency exploiting comproportionation to suppress Sn(ii) oxidation in precursor inkCO2 electrolysis to multicarbon products at activities greater than 1 A cm−2Highly Efficient Visible Colloidal Lead-Halide Perovskite Nanocrystal Light-Emitting DiodesEngineering Directionality in Quantum Dot Shell Lasing Using Plasmonic LatticesCombining Efficiency and Stability in Mixed Tin-Lead Perovskite Solar Cells by Capping Grains with an Ultrathin 2D LayerMulti-cation perovskites prevent carrier reflection from grain surfacesQuantum Dot-Plasmon Lasing with Controlled Polarization PatternsPublisher Correction: Copper adparticle enabled selective electrosynthesis of n-propanolMolecular enhancement of heterogeneous CO2 reductionEnhanced Nitrate-to-Ammonia Activity on Copper-Nickel Alloys via Tuning of Intermediate AdsorptionEfficient tandem solar cells with solution-processed perovskite on textured crystalline siliconHalogen Vacancies Enable Ligand-Assisted Self-Assembly of Perovskite Quantum Dots into NanowiresChloride Insertion-Immobilization Enables Bright, Narrowband, and Stable Blue-Emitting Perovskite DiodesEnhanced optical path and electron diffusion length enable high-efficiency perovskite tandemsMachine Learning Accelerates Discovery of Optimal Colloidal Quantum Dot Synthesis
P50
Q41257419-7DF630AF-6AFF-44D1-A25E-E2C61DCAC0B2Q48282056-9641D607-0834-4EF9-99D5-640795E00CABQ49496967-9A76271C-005F-46AC-9596-749615D3D315Q51744460-BA4631C5-028C-4011-8217-30251BAB86EDQ57059920-601FE2AD-292E-443D-8A15-8A0B8A13B60AQ57285562-3E35F75B-1DFF-46C2-BDB9-4AF1847D49A0Q57476541-184A07E0-3DE6-4A1D-A182-471CB878A82AQ58611462-29E3896A-DB96-49A9-91C6-3B455938AD9CQ58712127-28D077D7-D486-4A44-82BB-663E71ADB59DQ58799574-1923D1C7-BDCB-4CC6-8357-3B1A8BC8C051Q58900359-763AF63B-074F-4287-B72A-2DA7F8FA3996Q58927082-A944AD0A-1481-4B7A-8E05-F014F686C159Q59335885-6A5A43BC-C3E9-48F2-A54B-819B019DDE10Q59714893-1B9EAE5B-C345-434D-8786-844FDF8FFB60Q59714900-2A11F5B7-C1A9-426A-8E80-72C8445C87AAQ59714902-EAB7D6C4-3FE0-4391-B3FA-DDB1909682D5Q59714905-4F0AE04F-41F4-4D38-9C8F-1AEE4FB21735Q61960144-63E34092-2F04-433F-9945-688C9FA0BCE7Q62112390-6815EE0F-6562-42F4-8547-16788076FBDFQ62245488-8F886DD5-8199-43FA-BC0E-BE32818B6BA4Q62712121-F25B34E4-302D-439E-A53B-D0D402E19F84Q62712127-1D4AC693-E42F-49BD-AB27-ABD696BE3B89Q64067687-DD6C6DCE-FF8B-4FCB-9F95-579AF533AAFDQ64903007-A4CE2734-38F9-4EE4-B679-9B1025C7BB57Q68687043-955D9B3C-F0D4-4B3D-AE19-8638D57DF713Q75720510-F680B967-1A99-4E94-A3C8-4F92FE0EB502Q85543114-C57EDE86-6B1B-4612-8C50-ADE32BE76FA7Q88243871-3D0DCF90-5BB4-4C94-90E0-7656A33C0D30Q89465903-F66AC18B-4D94-4BEE-9A28-12DDC2392002Q89588094-1839025F-BD8F-441E-93D8-EBED772C0833Q89637401-6E07EF99-FF33-4FF0-8E87-760CE438DCE8Q89676471-3AEA56F9-E997-4BCC-B31F-B394691738F2Q89810362-02CD1218-267D-418C-99BA-D77A75F068F0Q89882755-046D6C4C-C873-423A-AC9D-C3A0C46B2C3DQ89969010-32426272-DF85-442A-AF38-C27BC2DD5C2DQ90089989-0F51BB31-9F16-4319-929F-03E80760F361Q90142174-17392B7D-3925-4BCB-850E-612D0628EEDEQ90159150-59A5BB01-D9A2-4810-9BC3-D4D500E50F35Q90170562-97518B7C-F4D4-4453-A00F-8D800D566C73Q90191053-0B354C1D-3025-4BC1-92A6-960A5CA4D4BF
P50
description
Forscher
@de
chercheur
@fr
investigador
@es
researcher
@en
ricercatore
@it
wetenschapper
@nl
研究者
@zh
name
Edward H. Sargent
@ast
Edward H. Sargent
@en
Edward H. Sargent
@es
Edward H. Sargent
@nl
type
label
Edward H. Sargent
@ast
Edward H. Sargent
@en
Edward H. Sargent
@es
Edward H. Sargent
@nl
prefLabel
Edward H. Sargent
@ast
Edward H. Sargent
@en
Edward H. Sargent
@es
Edward H. Sargent
@nl
P31
P496
0000-0003-0396-6495