Differential ion transport and biomass charges create strong electric fields in anammox granules

Matteo Tucci; Federico Aulenta; Mie Mai Corneliussen; Luis F M Rosa; Cristian Picioreanu; Ugo Marzocchi

doi:10.1016/j.watres.2025.123663

Differential ion transport and biomass charges create strong electric fields in anammox granules

Matteo Tucci, Federico Aulenta, Mie Mai Corneliussen, Luis F M Rosa, Cristian Picioreanu, Ugo Marzocchi

Publikation: Bidrag til tidsskrift/Konferencebidrag i tidsskrift /Bidrag til avis › Tidsskriftartikel › Forskning › peer review

Abstract

Quantifying mass transport of substrates and products within biofilms is crucial for the identification of limiting factors and thereby for the optimization of bioprocess. Current models assume that concentration gradients (i.e., molecular diffusion) control the transport of solutes within biofilms. Here, we document for the first time the presence of electric fields within anammox granules. The measured intensity of these electric potential fields was unprecedented (up to 360 V/m) compared to other biological systems. Mathematical modeling indicates that biomass behaves as a weak ion exchanger towards NH 4 +, thereby inducing a diffusion potential. These electric fields, in turn, support the migration of ions, and the contribution of ionic migration to the total transport of NO 2 -, NH 4 + and NO 3 - matches the magnitude of molecular diffusion. Our data indicates that neglecting ionic migration could result in significant error in estimating mass transport and therefore limiting reactants and reaction rates within anammox granules and, potentially, in a broader range of natural and artificial biofilms.

Originalsprog	Engelsk
Artikelnummer	123663
Tidsskrift	Water Research
Vol/bind	281
Antal sider	7
ISSN	0043-1354
DOI	https://doi.org/10.1016/j.watres.2025.123663
Status	E-pub / Early view - 16 apr. 2025

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10.1016/j.watres.2025.123663Licens: CC BY-NC

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title = "Differential ion transport and biomass charges create strong electric fields in anammox granules",

abstract = "Quantifying mass transport of substrates and products within biofilms is crucial for the identification of limiting factors and thereby for the optimization of bioprocess. Current models assume that concentration gradients (i.e., molecular diffusion) control the transport of solutes within biofilms. Here, we document for the first time the presence of electric fields within anammox granules. The measured intensity of these electric potential fields was unprecedented (up to 360 V/m) compared to other biological systems. Mathematical modeling indicates that biomass behaves as a weak ion exchanger towards NH 4 +, thereby inducing a diffusion potential. These electric fields, in turn, support the migration of ions, and the contribution of ionic migration to the total transport of NO 2 -, NH 4 + and NO 3 - matches the magnitude of molecular diffusion. Our data indicates that neglecting ionic migration could result in significant error in estimating mass transport and therefore limiting reactants and reaction rates within anammox granules and, potentially, in a broader range of natural and artificial biofilms. ",

keywords = "Wastewater treatment, Ionic migration, Nutrient gradients, Anammox, Electric fields",

author = "Matteo Tucci and Federico Aulenta and Corneliussen, {Mie Mai} and Rosa, {Luis F M} and Cristian Picioreanu and Ugo Marzocchi",

note = "Copyright {\textcopyright} 2025. Published by Elsevier Ltd.",

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doi = "10.1016/j.watres.2025.123663",

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T1 - Differential ion transport and biomass charges create strong electric fields in anammox granules

AU - Tucci, Matteo

AU - Aulenta, Federico

AU - Corneliussen, Mie Mai

AU - Rosa, Luis F M

AU - Picioreanu, Cristian

AU - Marzocchi, Ugo

PY - 2025/4/16

Y1 - 2025/4/16

N2 - Quantifying mass transport of substrates and products within biofilms is crucial for the identification of limiting factors and thereby for the optimization of bioprocess. Current models assume that concentration gradients (i.e., molecular diffusion) control the transport of solutes within biofilms. Here, we document for the first time the presence of electric fields within anammox granules. The measured intensity of these electric potential fields was unprecedented (up to 360 V/m) compared to other biological systems. Mathematical modeling indicates that biomass behaves as a weak ion exchanger towards NH 4 +, thereby inducing a diffusion potential. These electric fields, in turn, support the migration of ions, and the contribution of ionic migration to the total transport of NO 2 -, NH 4 + and NO 3 - matches the magnitude of molecular diffusion. Our data indicates that neglecting ionic migration could result in significant error in estimating mass transport and therefore limiting reactants and reaction rates within anammox granules and, potentially, in a broader range of natural and artificial biofilms.

AB - Quantifying mass transport of substrates and products within biofilms is crucial for the identification of limiting factors and thereby for the optimization of bioprocess. Current models assume that concentration gradients (i.e., molecular diffusion) control the transport of solutes within biofilms. Here, we document for the first time the presence of electric fields within anammox granules. The measured intensity of these electric potential fields was unprecedented (up to 360 V/m) compared to other biological systems. Mathematical modeling indicates that biomass behaves as a weak ion exchanger towards NH 4 +, thereby inducing a diffusion potential. These electric fields, in turn, support the migration of ions, and the contribution of ionic migration to the total transport of NO 2 -, NH 4 + and NO 3 - matches the magnitude of molecular diffusion. Our data indicates that neglecting ionic migration could result in significant error in estimating mass transport and therefore limiting reactants and reaction rates within anammox granules and, potentially, in a broader range of natural and artificial biofilms.

KW - Wastewater treatment

KW - Ionic migration

KW - Nutrient gradients

KW - Anammox

KW - Electric fields

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U2 - 10.1016/j.watres.2025.123663

DO - 10.1016/j.watres.2025.123663

M3 - Journal article

C2 - 40300366

SN - 0043-1354

VL - 281

JO - Water Research

JF - Water Research

M1 - 123663

ER -

Differential ion transport and biomass charges create strong electric fields in anammox granules

Abstract

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