about
Electron transfer and biofilm formation of Shewanella putrefaciens as function of anode potential.Utilizing the green alga Chlamydomonas reinhardtii for microbial electricity generation: a living solar cell.Microbial fuel cells: methodology and technology.Anodic electron transfer mechanisms in microbial fuel cells and their energy efficiency.Selectivity versus mobility: separation of anode and cathode in microbial bioelectrochemical systems.Reactor concepts for bioelectrochemical syntheses and energy conversion.Design and Evaluation of a Boron Dipyrrin (BODIPY) Electrophore for Redox Flow Batteries.Metal-Polymer Hybrid Architectures as Novel Anode Platform for Microbial Electrochemical Technologies.Cytometric fingerprints: evaluation of new tools for analyzing microbial community dynamics.Gaining electricity from in situ oxidation of hydrogen produced by fermentative cellulose degradation.The study of electrochemically active microbial biofilms on different carbon-based anode materials in microbial fuel cells.Evaluating the effects of scaling up on the performance of bioelectrochemical systems using a technical scale microbial electrolysis cell.Examining sludge production in bioelectrochemical systems treating domestic wastewater.From wastewater to hydrogen: biorefineries based on microbial fuel-cell technology.Electrochemistry for the Generation of Renewable Chemicals: One-Pot Electrochemical Deoxygenation of Xylose to δ-Valerolactone.Metabolic efficiency of Geobacter sulfurreducens growing on anodes with different redox potentials.Hydroxyacetone: A Glycerol-Based Platform for Electrocatalytic Hydrogenation and Hydrodeoxygenation Processes.Gold-modified indium tin oxide as a transparent window in optoelectronic diagnostics of electrochemically active biofilms.Electrochemistry for biofuel generation: transformation of fatty acids and triglycerides to diesel-like olefin/ether mixtures and olefins.Challenges and constraints of using oxygen cathodes in microbial fuel cells.Interfacing electrocatalysis and biocatalysis with tungsten carbide: a high-performance, noble-metal-free microbial fuel cell.In situ electrooxidation of photobiological hydrogen in a photobioelectrochemical fuel cell based on Rhodobacter sphaeroides.Modeling the ion transfer and polarization of ion exchange membranes in bioelectrochemical systems.From in vitro to in vivo--biofuel cells are maturing.Unraveling the interfacial electron transfer dynamics of electroactive microbial biofilms using surface-enhanced Raman spectroscopy.In situ spectroelectrochemical investigation of electrocatalytic microbial biofilms by surface-enhanced resonance Raman spectroscopy.Voltammetry of Electroactive Oil Droplets: Electrochemically-Induced Ion Insertion, Expulsion and Reaction Processes at Microdroplets ofN,N,N‘,N‘-Tetraalkyl-para- phenylenediamines (TRPD, R =n-Butyl,n-Hexyl,n-Heptyl andn-Nonyl)Mikroben unter StromElectroactive mixed culture derived biofilms in microbial bioelectrochemical systems: The role of pH on biofilm formation, performance and compositionA generation of microbial fuel cells with current outputs boosted by more than one order of magnitudeThe solid-state electrochemistry of metal octacyanomolybdates, octacyanotungstates, and hexacyanoferrates explained on the basis of dissolution and reprecipitation reactions, lattice structures, and crystallinitiesThe suitability of monopolar and bipolar ion exchange membranes as separators for biological fuel cellsStainless steel mesh supported nitrogen-doped carbon nanofibers for binder-free cathode in microbial fuel cellsA three-dimensionally ordered macroporous carbon derived from a natural resource as anode for microbial bioelectrochemical systemsMicrobial fuel cells and microbial electrochemistry: into the next century!Electroactive mixed culture biofilms in microbial bioelectrochemical systems: the role of temperature for biofilm formation and performanceEffect of fiber diameter on the behavior of biofilm and anodic performance of fiber electrodes in microbial fuel cellsSelf-assembling enzyme networks--a new path towards multistep bioelectrocatalytic systemsThe Limits of Three-Dimensionality: Systematic Assessment of Effective Anode Macrostructure Dimensions for Mixed-Culture Electroactive Biofilms
P50
Q34289772-0BB6E79F-989A-4F75-9DC6-DD2260EF09BDQ34391856-5F0BA7C6-A1E2-4E15-87D8-DB3697CBAC39Q36602950-774E1072-6CA5-48FA-8BBA-E1817B53A4D7Q36879049-56934EC3-7498-4CA8-A263-D2FA5CB539B4Q37605706-553CADE6-1317-4885-ABF0-B31BA07F89E5Q38279921-BF74FEB3-D5C5-47A0-85F0-E585246CB155Q38603573-465421E6-BF71-408A-8CC6-25ED27C2B3CCQ38829332-E392B5AD-5299-4A03-8FE0-74AC75EA602BQ40278293-D4EF3B6F-9AB4-4654-9084-0F72155CD239Q43017999-8C3A3DAE-373E-44EC-ACD4-F730927AA65AQ43314661-5A7FF910-7E0B-4853-BE82-CFA32A3AAAB2Q43317363-47CAF9A9-1068-47A2-8D5D-CF2B8609C8DFQ43339546-B18BEB03-E4A5-43EF-B7A0-F2DB82B2FBA9Q43362323-63C550EC-54B7-4E42-BD1B-8395B8C27E81Q46889517-F914ED0F-50DC-4CF8-B234-7AA962B77001Q46929645-C31162C7-6AAF-4535-AD77-6ABBD5555BA2Q47992090-B78C0E37-E6E1-4FEE-94E4-C848E91198BAQ50206598-1523E19B-490E-4980-B3C2-28C5292C3472Q50440381-B7BBE4DE-31E3-4F38-8DB1-DEED0A23B2CAQ51129186-0711D8E2-1D28-45E0-ADFB-2DEB5AECF8C4Q51133539-BCCCA4BA-E0D5-4526-BDCC-6293BF59C766Q51352420-5E5E63B5-AB3C-4A77-BE3D-BC5202FC0852Q51846865-BB4755AF-6363-4D3A-A660-AE5AE780BE17Q52738726-1A9B9E21-6E6E-40D7-AFEF-2E5E707415C3Q52885015-275D2E95-4696-4D07-A297-CA36A4248272Q52897644-7FB10A2F-A7AF-49AE-BAB1-E61FD6A8773BQ57757130-A53247F9-1309-4CA4-9E9C-C02E1549CD64Q60191430-5781E032-1567-42FB-B362-30887FCDFF4EQ60260753-9DB2BC06-D07D-40C4-9968-8146F4EA966BQ73589422-B13898E3-96E6-4390-A4FD-2C8AB93CD17CQ78788225-3EF99BA6-7309-4FF8-BDF4-FC5AC09B1FD6Q81166297-82008650-BA07-4A17-9921-C5807100EF67Q83452443-86AFA6BE-2B3C-45A8-B6B8-FC656026ECE3Q83786994-B8EED34E-B9C4-4857-A78C-136A8B69C678Q84314544-E7C102C7-AF24-4F09-AE14-85111008E82AQ84568440-D5584BF5-BB80-4EB9-9202-D52E30B9124CQ84980314-6387A5B0-9270-43D9-8D35-1DEDE8707E5FQ86104224-E5BCE847-8CCD-4FC1-9D81-4DDCD3E3A3F1Q91339804-77DE1F96-2800-4B0B-9ACE-AB331206DD2E
P50
description
onderzoeker
@nl
researcher
@en
հետազոտող
@hy
name
Uwe Schröder
@ast
Uwe Schröder
@en
Uwe Schröder
@es
Uwe Schröder
@nl
Uwe Schröder
@sl
乌韦·施罗德
@zh
烏維・施羅德
@zh-hant
type
label
Uwe Schröder
@ast
Uwe Schröder
@en
Uwe Schröder
@es
Uwe Schröder
@nl
Uwe Schröder
@sl
乌韦·施罗德
@zh
烏維・施羅德
@zh-hant
prefLabel
Uwe Schröder
@ast
Uwe Schröder
@en
Uwe Schröder
@es
Uwe Schröder
@nl
Uwe Schröder
@sl
乌韦·施罗德
@zh
烏維・施羅德
@zh-hant
P106
P1153
55545861847
P2798
P31
P496
0000-0002-8144-0328