Adriaan W Jeremiasse
Overview
Explore the profile of Adriaan W Jeremiasse including associated specialties, affiliations and a list of published articles.
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15
Citations
207
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Recent Articles
1.
Vos J, Bhardwaj A, Jeremiasse A, Esposito D, Koper M
J Phys Chem C Nanomater Interfaces
. 2022 Dec;
126(48):20314-20325.
PMID: 36523487
Seawater electrolysis offers significant logistical advantages over freshwater electrolysis but suffers from a fundamental selectivity problem at the anode. To prevent the evolution of toxic chlorine alongside the evolution of...
2.
Saha P, Wang J, Zhou Y, Carlucci L, Jeremiasse A, Rijnaarts H, et al.
Environ Res
. 2022 Mar;
211:113057.
PMID: 35271837
Electrochemical oxidation is an effective technique for treating persistent organic pollutants, which are hardly removed in conventional wastewater treatment plants. Sulfate and chloride salts commonly used and present in natural...
3.
Bruninghoff R, van Duijne A, Braakhuis L, Saha P, Jeremiasse A, Mei B, et al.
Environ Sci Technol
. 2019 Jul;
53(15):8725-8735.
PMID: 31282148
We evaluated electrochemical degradation (ECD) and photocatalytic degradation (PCD) technologies for saline water purification, with a focus on rate comparison and formation and degradation of chlorinated aromatic intermediates using the...
4.
Ntagia E, Fiset E, da Silva Lima L, Pikaar I, Zhang X, Jeremiasse A, et al.
Water Res
. 2018 Nov;
149:111-119.
PMID: 30423502
Electrochemical sulfide removal can be attractive as a zero-chemical-input approach for treatment of waste streams such as spent caustics coupled to caustic recovery. A key concern is possible decline in...
5.
Vos J, Wezendonk T, Jeremiasse A, Koper M
J Am Chem Soc
. 2018 Jul;
140(32):10270-10281.
PMID: 30024752
The oxygen evolution reaction (OER) and chlorine evolution reaction (CER) are electrochemical processes with high relevance to water splitting for (solar) energy conversion and industrial production of commodity chemicals, respectively....
6.
Lin H, Cejudo-Marin R, Jeremiasse A, Rabaey K, Yuan Z, Pikaar I
Sci Rep
. 2016 Feb;
6:20494.
PMID: 26848031
Hydrochloric acid (HCl) and caustic (NaOH) are among the most widely used chemicals by the water industry. Direct anodic electrochemical HCl production by water electrolysis has not been successful as...
7.
Croese E, Jeremiasse A, Marshall I, Spormann A, Euverink G, Geelhoed J, et al.
Enzyme Microb Technol
. 2014 Jun;
61-62:67-75.
PMID: 24910339
The microbial electrolysis cell (MEC) biocathode has shown great potential as alternative for expensive metals as catalyst for H2 synthesis. Here, the bacterial communities at the biocathode of five hydrogen...
8.
Butkovskyi A, Jeremiasse A, Hernandez Leal L, van der Zande T, Rijnaarts H, Zeeman G
Environ Sci Technol
. 2013 Dec;
48(3):1893-901.
PMID: 24364736
Electrochemical conversion of micropollutants in real gray water effluent was studied for the first time. Six compounds that are frequently found in personal care and household products, namely methylparaben, propylparaben,...
9.
Jeremiasse A, Hamelers H, Croese E, Buisman C
Biotechnol Bioeng
. 2011 Oct;
109(3):657-64.
PMID: 22012403
H(2) can be produced from organic matter with a microbial electrolysis cell (MEC). To decrease MEC capital costs, a cathode is needed that is made of low-cost material and produces...
10.
Kleijn J, Lhuillier Q, Jeremiasse A
Bioelectrochemistry
. 2010 May;
79(2):272-5.
PMID: 20494628
In this paper we explored the use of an electrochemical quartz crystal microbalance (QCM) to follow the development of electrochemically active biofilms on electrodes. With this technique it should be...