Sustainable management of Fucus beds – testing of UAV-assisted biomass mapping and evaluation of re-growth after harvest at individual and population level

Jørgen Ulrik Graudal Levinsen; Mette Møller Nielsen; Peter Søndergaard Schmedes; Aris Thomasberger; Michael Bo Rasmussen; Sigrid Elgaard Mikkelsen; Morten Foldager Pedersen; Jens Jørgen Sloth; Jens Søndergaard; Anna Sauermilch Sørensen; Teis Boderskov; Annette Bruhn

doi:10.1007/s10811-025-03459-3

Sustainable management of Fucus beds – testing of UAV-assisted biomass mapping and evaluation of re-growth after harvest at individual and population level

Jørgen Ulrik Graudal Levinsen, Mette Møller Nielsen, Peter Søndergaard Schmedes, Aris Thomasberger, Michael Bo Rasmussen, Sigrid Elgaard Mikkelsen, Morten Foldager Pedersen, Jens Jørgen Sloth, Jens Søndergaard, Anna Sauermilch Sørensen, Teis Boderskov, Annette Bruhn^*

^*Corresponding author for this work

Research output: Contribution to journal/Conference contribution in journal/Contribution to newspaper › Journal article › Research › peer-review

Abstract

Experimental harvests of Fucus beds were conducted at three sites in central Denmark applying four harvest treatments: apical tip harvest, full harvest, thinning harvest (full harvest of one third), and control (no harvest) to 1) determine correlations between Fucus areal cover and biomass harvest potential, and 2) examine effects of harvest treatment on biomass yield and recovery capacity. The study examined recovery capacity at individual algae scale through the capacity for generating new shoots and/or biomass regrowth, and at population scale using unoccupied aerial vehicles (UAVs) to estimate areal cover recovery. The results indicated significant variability in harvest yields and recovery responses, where full harvest provided the highest but variable yields, ranging from 0.33 to 5.85 kg FW m^-2. The full harvest also had the highest impact on individual algae biomass and population scale areal cover with observable slower recovery capacity compared to other harvest treatments. For the full harvest treatment, UAV-based assessments showed areal cover recovery six months post-harvest, whereas individual algae had not fully recovered one year after full harvest. The use of UAVs proved useful for monitoring the areal cover of Fucus beds, but less reliable in estimating the standing stock biomass. Future studies should focus on refining UAV-based methodologies to enhance accuracy and reliability in estimating areal cover and standing stock, and on large scale, long-term harvest impacts.

Original language	English
Journal	Journal of Applied Phycology
Volume	37
Issue	2
Pages (from-to)	1493-1508
Number of pages	16
ISSN	0921-8971
DOIs	https://doi.org/10.1007/s10811-025-03459-3
Publication status	Published - Apr 2025

Keywords

Biomass composition
Fucus spp
Heavy metals
Phaeophyceae
Sustainable resource management
UAV imaging

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10.1007/s10811-025-03459-3

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Levinsen, J. U. G., Nielsen, M. M., Schmedes, P. S., Thomasberger, A., Rasmussen, M. B., Mikkelsen, S. E., Pedersen, M. F., Sloth, J. J., Søndergaard, J., Sørensen, A. S., Boderskov, T., & Bruhn, A. (2025). Sustainable management of Fucus beds – testing of UAV-assisted biomass mapping and evaluation of re-growth after harvest at individual and population level. Journal of Applied Phycology, 37(2), 1493-1508. https://doi.org/10.1007/s10811-025-03459-3

@article{8b7460f11c414d5ca75283e436a4ce25,

title = "Sustainable management of Fucus beds – testing of UAV-assisted biomass mapping and evaluation of re-growth after harvest at individual and population level",

abstract = "Experimental harvests of Fucus beds were conducted at three sites in central Denmark applying four harvest treatments: apical tip harvest, full harvest, thinning harvest (full harvest of one third), and control (no harvest) to 1) determine correlations between Fucus areal cover and biomass harvest potential, and 2) examine effects of harvest treatment on biomass yield and recovery capacity. The study examined recovery capacity at individual algae scale through the capacity for generating new shoots and/or biomass regrowth, and at population scale using unoccupied aerial vehicles (UAVs) to estimate areal cover recovery. The results indicated significant variability in harvest yields and recovery responses, where full harvest provided the highest but variable yields, ranging from 0.33 to 5.85 kg FW m-2. The full harvest also had the highest impact on individual algae biomass and population scale areal cover with observable slower recovery capacity compared to other harvest treatments. For the full harvest treatment, UAV-based assessments showed areal cover recovery six months post-harvest, whereas individual algae had not fully recovered one year after full harvest. The use of UAVs proved useful for monitoring the areal cover of Fucus beds, but less reliable in estimating the standing stock biomass. Future studies should focus on refining UAV-based methodologies to enhance accuracy and reliability in estimating areal cover and standing stock, and on large scale, long-term harvest impacts.",

keywords = "Biomass composition, Fucus spp, Heavy metals, Phaeophyceae, Sustainable resource management, UAV imaging",

author = "Levinsen, {J{\o}rgen Ulrik Graudal} and Nielsen, {Mette M{\o}ller} and Schmedes, {Peter S{\o}ndergaard} and Aris Thomasberger and Rasmussen, {Michael Bo} and Mikkelsen, {Sigrid Elgaard} and Pedersen, {Morten Foldager} and Sloth, {Jens J{\o}rgen} and Jens S{\o}ndergaard and S{\o}rensen, {Anna Sauermilch} and Teis Boderskov and Annette Bruhn",

note = "Publisher Copyright: {\textcopyright} The Author(s) 2025.",

year = "2025",

month = apr,

doi = "10.1007/s10811-025-03459-3",

language = "English",

volume = "37",

pages = "1493--1508",

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Levinsen, JUG, Nielsen, MM, Schmedes, PS, Thomasberger, A, Rasmussen, MB, Mikkelsen, SE, Pedersen, MF, Sloth, JJ, Søndergaard, J, Sørensen, AS, Boderskov, T & Bruhn, A 2025, 'Sustainable management of Fucus beds – testing of UAV-assisted biomass mapping and evaluation of re-growth after harvest at individual and population level', Journal of Applied Phycology, vol. 37, no. 2, pp. 1493-1508. https://doi.org/10.1007/s10811-025-03459-3

Sustainable management of Fucus beds – testing of UAV-assisted biomass mapping and evaluation of re-growth after harvest at individual and population level. / Levinsen, Jørgen Ulrik Graudal; Nielsen, Mette Møller; Schmedes, Peter Søndergaard et al.
In: Journal of Applied Phycology, Vol. 37, No. 2, 04.2025, p. 1493-1508.

Research output: Contribution to journal/Conference contribution in journal/Contribution to newspaper › Journal article › Research › peer-review

TY - JOUR

T1 - Sustainable management of Fucus beds – testing of UAV-assisted biomass mapping and evaluation of re-growth after harvest at individual and population level

AU - Levinsen, Jørgen Ulrik Graudal

AU - Nielsen, Mette Møller

AU - Schmedes, Peter Søndergaard

AU - Thomasberger, Aris

AU - Rasmussen, Michael Bo

AU - Mikkelsen, Sigrid Elgaard

AU - Pedersen, Morten Foldager

AU - Sloth, Jens Jørgen

AU - Søndergaard, Jens

AU - Sørensen, Anna Sauermilch

AU - Boderskov, Teis

AU - Bruhn, Annette

N1 - Publisher Copyright: © The Author(s) 2025.

PY - 2025/4

Y1 - 2025/4

N2 - Experimental harvests of Fucus beds were conducted at three sites in central Denmark applying four harvest treatments: apical tip harvest, full harvest, thinning harvest (full harvest of one third), and control (no harvest) to 1) determine correlations between Fucus areal cover and biomass harvest potential, and 2) examine effects of harvest treatment on biomass yield and recovery capacity. The study examined recovery capacity at individual algae scale through the capacity for generating new shoots and/or biomass regrowth, and at population scale using unoccupied aerial vehicles (UAVs) to estimate areal cover recovery. The results indicated significant variability in harvest yields and recovery responses, where full harvest provided the highest but variable yields, ranging from 0.33 to 5.85 kg FW m-2. The full harvest also had the highest impact on individual algae biomass and population scale areal cover with observable slower recovery capacity compared to other harvest treatments. For the full harvest treatment, UAV-based assessments showed areal cover recovery six months post-harvest, whereas individual algae had not fully recovered one year after full harvest. The use of UAVs proved useful for monitoring the areal cover of Fucus beds, but less reliable in estimating the standing stock biomass. Future studies should focus on refining UAV-based methodologies to enhance accuracy and reliability in estimating areal cover and standing stock, and on large scale, long-term harvest impacts.

AB - Experimental harvests of Fucus beds were conducted at three sites in central Denmark applying four harvest treatments: apical tip harvest, full harvest, thinning harvest (full harvest of one third), and control (no harvest) to 1) determine correlations between Fucus areal cover and biomass harvest potential, and 2) examine effects of harvest treatment on biomass yield and recovery capacity. The study examined recovery capacity at individual algae scale through the capacity for generating new shoots and/or biomass regrowth, and at population scale using unoccupied aerial vehicles (UAVs) to estimate areal cover recovery. The results indicated significant variability in harvest yields and recovery responses, where full harvest provided the highest but variable yields, ranging from 0.33 to 5.85 kg FW m-2. The full harvest also had the highest impact on individual algae biomass and population scale areal cover with observable slower recovery capacity compared to other harvest treatments. For the full harvest treatment, UAV-based assessments showed areal cover recovery six months post-harvest, whereas individual algae had not fully recovered one year after full harvest. The use of UAVs proved useful for monitoring the areal cover of Fucus beds, but less reliable in estimating the standing stock biomass. Future studies should focus on refining UAV-based methodologies to enhance accuracy and reliability in estimating areal cover and standing stock, and on large scale, long-term harvest impacts.

KW - Biomass composition

KW - Fucus spp

KW - Heavy metals

KW - Phaeophyceae

KW - Sustainable resource management

KW - UAV imaging

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DO - 10.1007/s10811-025-03459-3

M3 - Journal article

AN - SCOPUS:86000751503

SN - 0921-8971

VL - 37

SP - 1493

EP - 1508

JO - Journal of Applied Phycology

JF - Journal of Applied Phycology

IS - 2

ER -

Sustainable management of Fucus beds – testing of UAV-assisted biomass mapping and evaluation of re-growth after harvest at individual and population level

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Keywords

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