Coupled UV-exposure and microbial decomposition improves measures of organic matter degradation and light models in humic lake

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Coupled UV-exposure and microbial decomposition improves measures of organic matter degradation and light models in humic lake. / Madsen-Østerbye, Mikkel; Kragh, Theis; Pedersen, Ole; Sand-Jensen, Kaj.

In: Ecological Engineering, Vol. 118, 2018, p. 191-200.

Research output: Contribution to journalJournal articleResearchpeer-review

Harvard

Madsen-Østerbye, M, Kragh, T, Pedersen, O & Sand-Jensen, K 2018, 'Coupled UV-exposure and microbial decomposition improves measures of organic matter degradation and light models in humic lake', Ecological Engineering, vol. 118, pp. 191-200. https://doi.org/10.1016/j.ecoleng.2018.04.018

APA

Madsen-Østerbye, M., Kragh, T., Pedersen, O., & Sand-Jensen, K. (2018). Coupled UV-exposure and microbial decomposition improves measures of organic matter degradation and light models in humic lake. Ecological Engineering, 118, 191-200. https://doi.org/10.1016/j.ecoleng.2018.04.018

Vancouver

Madsen-Østerbye M, Kragh T, Pedersen O, Sand-Jensen K. Coupled UV-exposure and microbial decomposition improves measures of organic matter degradation and light models in humic lake. Ecological Engineering. 2018;118:191-200. https://doi.org/10.1016/j.ecoleng.2018.04.018

Author

Madsen-Østerbye, Mikkel ; Kragh, Theis ; Pedersen, Ole ; Sand-Jensen, Kaj. / Coupled UV-exposure and microbial decomposition improves measures of organic matter degradation and light models in humic lake. In: Ecological Engineering. 2018 ; Vol. 118. pp. 191-200.

Bibtex

@article{6420dd191f034a7ca7851a34da727224,
title = "Coupled UV-exposure and microbial decomposition improves measures of organic matter degradation and light models in humic lake",
abstract = "Increasing terrestrial input of colored dissolved organic matter (CDOM) to temperate softwater lakes has reduced transparency, distribution of pristine rosette plants and overall biodiversity in recent decades. We examined microbial and UV-induced reduction of absorption by CDOM and dissolved organic carbon pools (DOC) in humic water from a groundwater-fed softwater lake as well as groundwater received from surrounding heathland and coniferous forest. An experimental setup that mimics naturally coupled continuous UV-exposure and microbial degradation was introduced and compared with experiments applying a single initial or no UV-exposure. We found that decreases of CDOM and DOC concentrations were negligible in groundwater and very small in lake water over 30 days in the absence of UV-exposure. Initial UV-exposure increased degradation rates, but further degradation ceased after 20 days preventing determination of the natural time course of degradation. Coupled continuous UV-exposure and microbial degradation showed high and constant degradation of CDOM (340 nm) over 30 days removing 87% of the initial absorption in heathland groundwater, and 20% in forest groundwater and lake water. Declines in DOC concentrations over 30 days were 34%, 28% and 13% of the initial levels in heathland groundwater, forest groundwater and lake water, respectively. Model estimates showed that a shift in land use from a forest dominated to a heathland dominated catchment could increase lake transparency from 0.6 to 2.5 m. and expand plant-covered area from 3 to 35%. The main time delay to a new steady state of better light climate would be degradation of soil organic pools and exchange of groundwater magazines, while the delay in the lake water after a complete shift to inflow of CDOM-poorer groundwater would last only 1–2 years. Consequently, changes in CDOM levels in groundwater input should have relatively rapid and marked influence on light conditions and plant distribution in shallow softwater lakes.",
keywords = "Brownification, DOC, Groundwater, Lake restoration, Photo-bleaching, Plant recovery",
author = "Mikkel Madsen-{\O}sterbye and Theis Kragh and Ole Pedersen and Kaj Sand-Jensen",
year = "2018",
doi = "10.1016/j.ecoleng.2018.04.018",
language = "English",
volume = "118",
pages = "191--200",
journal = "Ecological Engineering",
issn = "0925-8574",
publisher = "Elsevier",

}

RIS

TY - JOUR

T1 - Coupled UV-exposure and microbial decomposition improves measures of organic matter degradation and light models in humic lake

AU - Madsen-Østerbye, Mikkel

AU - Kragh, Theis

AU - Pedersen, Ole

AU - Sand-Jensen, Kaj

PY - 2018

Y1 - 2018

N2 - Increasing terrestrial input of colored dissolved organic matter (CDOM) to temperate softwater lakes has reduced transparency, distribution of pristine rosette plants and overall biodiversity in recent decades. We examined microbial and UV-induced reduction of absorption by CDOM and dissolved organic carbon pools (DOC) in humic water from a groundwater-fed softwater lake as well as groundwater received from surrounding heathland and coniferous forest. An experimental setup that mimics naturally coupled continuous UV-exposure and microbial degradation was introduced and compared with experiments applying a single initial or no UV-exposure. We found that decreases of CDOM and DOC concentrations were negligible in groundwater and very small in lake water over 30 days in the absence of UV-exposure. Initial UV-exposure increased degradation rates, but further degradation ceased after 20 days preventing determination of the natural time course of degradation. Coupled continuous UV-exposure and microbial degradation showed high and constant degradation of CDOM (340 nm) over 30 days removing 87% of the initial absorption in heathland groundwater, and 20% in forest groundwater and lake water. Declines in DOC concentrations over 30 days were 34%, 28% and 13% of the initial levels in heathland groundwater, forest groundwater and lake water, respectively. Model estimates showed that a shift in land use from a forest dominated to a heathland dominated catchment could increase lake transparency from 0.6 to 2.5 m. and expand plant-covered area from 3 to 35%. The main time delay to a new steady state of better light climate would be degradation of soil organic pools and exchange of groundwater magazines, while the delay in the lake water after a complete shift to inflow of CDOM-poorer groundwater would last only 1–2 years. Consequently, changes in CDOM levels in groundwater input should have relatively rapid and marked influence on light conditions and plant distribution in shallow softwater lakes.

AB - Increasing terrestrial input of colored dissolved organic matter (CDOM) to temperate softwater lakes has reduced transparency, distribution of pristine rosette plants and overall biodiversity in recent decades. We examined microbial and UV-induced reduction of absorption by CDOM and dissolved organic carbon pools (DOC) in humic water from a groundwater-fed softwater lake as well as groundwater received from surrounding heathland and coniferous forest. An experimental setup that mimics naturally coupled continuous UV-exposure and microbial degradation was introduced and compared with experiments applying a single initial or no UV-exposure. We found that decreases of CDOM and DOC concentrations were negligible in groundwater and very small in lake water over 30 days in the absence of UV-exposure. Initial UV-exposure increased degradation rates, but further degradation ceased after 20 days preventing determination of the natural time course of degradation. Coupled continuous UV-exposure and microbial degradation showed high and constant degradation of CDOM (340 nm) over 30 days removing 87% of the initial absorption in heathland groundwater, and 20% in forest groundwater and lake water. Declines in DOC concentrations over 30 days were 34%, 28% and 13% of the initial levels in heathland groundwater, forest groundwater and lake water, respectively. Model estimates showed that a shift in land use from a forest dominated to a heathland dominated catchment could increase lake transparency from 0.6 to 2.5 m. and expand plant-covered area from 3 to 35%. The main time delay to a new steady state of better light climate would be degradation of soil organic pools and exchange of groundwater magazines, while the delay in the lake water after a complete shift to inflow of CDOM-poorer groundwater would last only 1–2 years. Consequently, changes in CDOM levels in groundwater input should have relatively rapid and marked influence on light conditions and plant distribution in shallow softwater lakes.

KW - Brownification

KW - DOC

KW - Groundwater

KW - Lake restoration

KW - Photo-bleaching

KW - Plant recovery

U2 - 10.1016/j.ecoleng.2018.04.018

DO - 10.1016/j.ecoleng.2018.04.018

M3 - Journal article

AN - SCOPUS:85046801415

VL - 118

SP - 191

EP - 200

JO - Ecological Engineering

JF - Ecological Engineering

SN - 0925-8574

ER -

ID: 196713987