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Affinity of microbial fuel cell biofilm for the anodic potential.Sequential solid entrapment and in situ electrolytic alkaline hydrolysis facilitated reagent-free bioelectrochemical treatment of particulate-rich municipal wastewater.Bioelectrochemical enhancement of anaerobic digestion: Comparing single- and two-chamber reactor configurations at thermophilic conditions.Bioelectrohydrogenesis and inhibition of methanogenic activity in microbial electrolysis cells - A review.Bioelectrochemical oxidation of organics by alkali-halotolerant anodophilic biofilm under nitrogen-deficient, alkaline and saline conditions.Anodophilic biofilm catalyzes cathodic oxygen reduction.Enrichment of anodophilic nitrogen fixing bacteria in a bioelectrochemical system.Simultaneous phosphorus uptake and denitrification by EBPR-r biofilm under aerobic conditions: effect of dissolved oxygen.A bio-anodic filter facilitated entrapment, decomposition and in situ oxidation of algal biomass in wastewater effluent.Assessing the suitability of sediment-type bioelectrochemical systems for organic matter removal from municipal wastewater: a column study.Ammonia recycling enables sustainable operation of bioelectrochemical systems.Bioelectricity production from food waste leachate using microbial fuel cells: effect of NaCl and pH.Effects of pig manure compost and nonionic-surfactant Tween 80 on phenanthrene and pyrene removal from soil vegetated with Agropyron elongatum.New method for characterizing electron mediators in microbial systems using a thin-layer twin-working electrode cell.A new approach for in situ cyclic voltammetry of a microbial fuel cell biofilm without using a potentiostat.Rapid start-up of a bioelectrochemical system under alkaline and saline conditions for efficient oxalate removal.Multistage leaching of metals from spent lithium ion battery waste using electrochemically generated acidic lixiviant.Influence of ionic conductivity in bioelectricity production from saline domestic sewage sludge in microbial fuel cells.A novel post denitrification configuration for phosphorus recovery using polyphosphate accumulating organisms.Application of Microbial Fuel Cells to Power Sensor Networks for Ecological MonitoringImprovement of carbon usage for phosphorus recovery in EBPR-r and the shift in microbial communityAmmonium-oxidizing bacteria facilitate aerobic degradation of sulfanilic acid in activated sludgeSequential in situ hydrotalcite precipitation and biological denitrification for the treatment of high-nitrate industrial effluentBiological phosphorus and nitrogen removal in sequencing batch reactors: effects of cycle length, dissolved oxygen concentration and influent particulate matterAerobic degradation of sulfanilic acid using activated sludgeEvidence for fungi and gold redox interaction under Earth surface conditionsEffect of synthetic surfactants on the solubilization and distribution of PAHs in water/soil-water systemsAmmonium as a sustainable proton shuttle in bioelectrochemical systemsSimultaneous nitrification, denitrification and phosphorus recovery (SNDPr) - An opportunity to facilitate full-scale recovery of phosphorus from municipal wastewaterA new method for ranking potential hazards and risks from wastes
P50
Q29038595-9587D890-BF03-48E4-9536-32970CC34B66Q38371762-ECADF657-707C-41AA-9799-B415EF6D5BF1Q38634210-94BB29F4-4B7F-49A3-A5F3-D9BE7A5B7EE2Q38678367-8F728E5D-C25A-4B30-8724-6D3C55E2C843Q43032537-00FFE7C8-F1E5-4032-ACE1-CADA98D7EBCEQ43232103-7F2FD0BC-A018-46AA-BB68-B5E0367A943AQ43320369-0D4ED07A-63E9-41AF-893D-618E749690ACQ43338910-1ED79212-B761-43BF-91B3-87A41F412426Q43350267-8E9BD1C6-7963-4960-85D7-91BAE2AB0194Q43353332-4ECF5F6B-2907-4CC1-9A93-00EA63411E43Q43360037-4ADD46DB-B9E1-4D97-8CC1-12C88643F013Q45207523-A97D21A9-A1BF-4930-A265-7BC6A3D1EEFFQ46451142-FE10C261-80EC-4FDF-95E1-465BE697182EQ46492143-675E37A8-73D1-4C08-BFB7-9CD73D08CD65Q47227807-2B7BA1AD-DF43-4291-A8EC-05467B4CB7A7Q47310626-CCD9BC08-655C-4068-A4BF-8ECE9FF587EAQ47724200-10CBB591-DEF5-4BD1-B676-71FCB08FEF7EQ51635735-6CE94807-5AAA-46FA-9177-240985AF7931Q51783900-C2F63DF9-097C-41D2-AD62-C818DC15A96DQ56002358-D2A44F33-419C-4279-ABBE-3CE4FF952E6BQ61293884-777B9DC9-F938-4293-AFE4-8B3BCBB4BE58Q61294041-A21894F9-BAFC-4693-80F2-52776475545AQ61294174-56824930-C2A7-453D-AB5A-3762D12E023CQ61294225-F328EE03-1EE7-45A8-A333-BCFA2BE00652Q61294312-145BECDA-FADB-420D-B93F-048A4A253E75Q64281369-04841DAF-0266-434F-8060-D0EE99DCE7F5Q80260934-442DEF1D-8CD3-466F-9AAD-84F68EAA17C9Q84818173-6AC5AD09-CB10-40DA-8D28-4B44D4FB5252Q92193469-B636BBBD-6FF7-498A-BFF6-FCFC591AF3C5Q93374419-E411B453-F1AE-4470-8967-C6EEB2FE9F8C
P50
description
onderzoeker
@nl
researcher
@en
հետազոտող
@hy
name
Ka Yu Cheng
@ast
Ka Yu Cheng
@en
Ka Yu Cheng
@es
Ka Yu Cheng
@nl
Ka Yu Cheng
@sl
type
label
Ka Yu Cheng
@ast
Ka Yu Cheng
@en
Ka Yu Cheng
@es
Ka Yu Cheng
@nl
Ka Yu Cheng
@sl
prefLabel
Ka Yu Cheng
@ast
Ka Yu Cheng
@en
Ka Yu Cheng
@es
Ka Yu Cheng
@nl
Ka Yu Cheng
@sl
P1053
A-3928-2012
P106
P31
P3829
P496
0000-0003-1672-2588