Benjamin Erable

Overview

Explore the profile of Benjamin Erable including associated specialties, affiliations and a list of published articles.

Snapshot

Articles 37

Citations 332

Followers 0

Related Specialties

Biochemistry

Biophysics

Environmental Health

Top 10 Co-Authors

Alain Bergel

Luc Etcheverry

Alexandra Bertron

Carlo Santoro

Mickael Rimboud

Theodore Bouchez

Isabelle Goubet

Thierry Maugard

Plamen Atanassov

Achim Albrecht

Published In

Bioresour Technol

Bioelectrochemistry

J Environ Manage

ChemSusChem

Biotechnol Bioeng

Affiliations

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Recent Articles

11.

Adaptation of neutrophilic Paracoccus denitrificans to denitrification at highly alkaline pH

Albina P, Durban N, Bertron A, Schiettekatte M, Albrecht A, Robinet J, et al.

Environ Sci Pollut Res Int . 2020 Apr; 27(17):22112-22119. PMID: 32285397

Bacterial denitrification is widely documented at neutral pH in order to improve the removal of nitrate in wastewater treatment processes. However, certain industrial contexts generate alkaline waste and effluent containing...

12.

Influence of Hydrogen Electron Donor, Alkaline pH, and High Nitrate Concentrations on Microbial Denitrification: A Review

Albina P, Durban N, Bertron A, Albrecht A, Robinet J, Erable B

Int J Mol Sci . 2019 Oct; 20(20). PMID: 31635215

Bacterial respiration of nitrate is a natural process of nitrate reduction, which has been industrialized to treat anthropic nitrate pollution. This process, also known as "microbial denitrification", is widely documented...

13.

Effect of pore size on the current produced by 3-dimensional porous microbial anodes: A critical review

Chong P, Erable B, Bergel A

Bioresour Technol . 2019 Jul; 289:121641. PMID: 31300306

Microbial anodes are the cornerstone of most electro-microbial processes. Designing 3-dimensional porous electrodes to increase the surface area of the electroactive biofilm they support is a key challenge in order...

14.

Understanding the cumulative effects of salinity, temperature and inoculation size for the design of optimal halothermotolerant bioanodes from hypersaline sediments

Askri R, Erable B, Neifar M, Etcheverry L, Slaheddine Masmoudi A, Cherif A, et al.

Bioelectrochemistry . 2019 Jun; 129:179-188. PMID: 31195329

The main objective of this study was to understand the interaction between salinity, temperature and inoculum size and how it could lead to the formation of efficient halothermotolerant bioanodes from...

15.

Evaluation of microbial proliferation on cementitious materials exposed to biogas systems

Voegel C, Durban N, Bertron A, Landon Y, Erable B

Environ Technol . 2019 Jan; 41(19):2439-2449. PMID: 30624151

Understanding the interactions between biofilm and cementitious materials in biogas production systems is an essential step toward the development of durable concrete for this expanding sector. Although the action of...

16.

Iron-Nicarbazin derived platinum group metal-free electrocatalyst in scalable-size air-breathing cathodes for microbial fuel cells

Erable B, Oliot M, Lacroix R, Bergel A, Serov A, Kodali M, et al.

Electrochim Acta . 2018 Jul; 277:127-135. PMID: 29970929

In this work, a platinum group metal-free (PGM-free) catalyst based on iron as transitional metal and Nicarbazin (NCB) as low cost organic precursor was synthesized using Sacrificial Support Method (SSM)....

17.

Microbial fuel cells: From fundamentals to applications. A review

Santoro C, Arbizzani C, Erable B, Ieropoulos I

J Power Sources . 2017 Jul; 356:225-244. PMID: 28717261

In the past 10-15 years, the microbial fuel cell (MFC) technology has captured the attention of the scientific community for the possibility of transforming organic waste directly into electricity through...

18.

Different methods used to form oxygen reducing biocathodes lead to different biomass quantities, bacterial communities, and electrochemical kinetics

Rimboud M, Barakat M, Bergel A, Erable B

Bioelectrochemistry . 2017 Apr; 116:24-32. PMID: 28364576

Six biocathodes catalyzing oxygen reduction were designed from the same environmental inoculum but using three different methods. Two were formed freely at open circuit potential, two using conventional aerobic polarization...

19.

Biocathodes reducing oxygen at high potential select biofilms dominated by Ectothiorhodospiraceae populations harboring a specific association of genes

Quemener E, Rimboud M, Bridier A, Madigou C, Erable B, Bergel A, et al.

Bioresour Technol . 2016 Apr; 214:55-62. PMID: 27126080

Biocathodes polarized at high potential are promising for enhancing Microbial Fuel Cell performances but the microbes and genes involved remain poorly documented. Here, two sets of five oxygen-reducing biocathodes were...

20.

Multiple electron transfer systems in oxygen reducing biocathodes revealed by different conditions of aeration/agitation

Rimboud M, Bergel A, Erable B

Bioelectrochemistry . 2016 Apr; 110:46-51. PMID: 27035588

Oxygen reducing biocathodes were formed at -0.2V/SCE (+0.04V/SHE) from compost leachate. Depending on whether aeration was implemented or not, two different redox systems responsible for the electrocatalysis of oxygen reduction...