Recurrent summer drought temporarily stimulates fine root growth but enhances winter root losses in alpine grassland

Lancaster Environment Centre

Text available via DOI:

https://doi.org/10.3389/fpls.2025.1625076
Final published version
Available under license: CC BY: Creative Commons Attribution 4.0 International License

Keywords

root phenology, winter, machine learning, climate change, rhizotron, neural network, leaf length, snowmelt

View graph of relations

Research output: Contribution to Journal/Magazine › Journal article › peer-review

Published

Standard

Recurrent summer drought temporarily stimulates fine root growth but enhances winter root losses in alpine grassland. / Möhl, Patrick; Hiltbrunner, Erika.
In: Frontiers in Plant Science, Vol. 16, 30.07.2025.

Research output: Contribution to Journal/Magazine › Journal article › peer-review

Bibtex

@article{77422d0be6c5473dabca365b635c830b,

title = "Recurrent summer drought temporarily stimulates fine root growth but enhances winter root losses in alpine grassland",

abstract = "By the end of the 21st century, frequent droughts and substantial shifts in snowmelt are expected to massively impact the biomass production of alpine grasslands. While the biomass of alpine plants consists to >80% of roots, little is known about the root growth dynamics in these ecosystems. To fill this gap, we capitalized on a longer-term experiment in the Swiss Alps with annually recurring treatments imposing advanced and delayed snowmelt and summer drought lasting 5 and 10 weeks. Over 3–4 growing seasons (2019–2022), we weekly quantified total root length of the plant community at two different soil depths (0–10 cm and 10–20 cm) using 90 minirhizotrons in 45 plots. We jointly assessed leaf elongation (of six abundant plant species) as proxies for the dynamics of biomass production. Increases in root length during summer continued beyond canopy development, with the duration of net root growth roughly double that of leaf expansion. Earlier and later snowmelt did not affect the proxies for total growth of leaves or roots but simply shifted their growing phases. Drought reduced leaf elongation across plant species whereas root length was stimulated by the 5-wk (not the 10-wk) drought in two seasons (+19% on average, 2020–2021). Natural rewetting after drought increased root growth by 38–77% compared to controls, but only in the 2020 growing season. Total root length in the topsoil declined by 7–15% during the last two winters, amounting to about one fourth of the previous seasons{\textquoteright} increase in root length. These root losses were 1.5 times higher following the 10-wk drought treatment. Our results highlight that earlier snowmelt alone will not stimulate productivity in alpine grassland. Root growth responses to drought depend on its duration and the long winter periods contribute to root losses, particularly in combination with severe drought in the preceding growing season.",

keywords = "root phenology, winter, machine learning, climate change, rhizotron, neural network, leaf length, snowmelt",

author = "Patrick M{\"o}hl and Erika Hiltbrunner",

year = "2025",

month = jul,

day = "30",

doi = "10.3389/fpls.2025.1625076",

language = "English",

volume = "16",

journal = "Frontiers in Plant Science",

issn = "1664-462X",

publisher = "Frontiers Media S.A.",

}

RIS

TY - JOUR

T1 - Recurrent summer drought temporarily stimulates fine root growth but enhances winter root losses in alpine grassland

AU - Möhl, Patrick

AU - Hiltbrunner, Erika

PY - 2025/7/30

Y1 - 2025/7/30

N2 - By the end of the 21st century, frequent droughts and substantial shifts in snowmelt are expected to massively impact the biomass production of alpine grasslands. While the biomass of alpine plants consists to >80% of roots, little is known about the root growth dynamics in these ecosystems. To fill this gap, we capitalized on a longer-term experiment in the Swiss Alps with annually recurring treatments imposing advanced and delayed snowmelt and summer drought lasting 5 and 10 weeks. Over 3–4 growing seasons (2019–2022), we weekly quantified total root length of the plant community at two different soil depths (0–10 cm and 10–20 cm) using 90 minirhizotrons in 45 plots. We jointly assessed leaf elongation (of six abundant plant species) as proxies for the dynamics of biomass production. Increases in root length during summer continued beyond canopy development, with the duration of net root growth roughly double that of leaf expansion. Earlier and later snowmelt did not affect the proxies for total growth of leaves or roots but simply shifted their growing phases. Drought reduced leaf elongation across plant species whereas root length was stimulated by the 5-wk (not the 10-wk) drought in two seasons (+19% on average, 2020–2021). Natural rewetting after drought increased root growth by 38–77% compared to controls, but only in the 2020 growing season. Total root length in the topsoil declined by 7–15% during the last two winters, amounting to about one fourth of the previous seasons’ increase in root length. These root losses were 1.5 times higher following the 10-wk drought treatment. Our results highlight that earlier snowmelt alone will not stimulate productivity in alpine grassland. Root growth responses to drought depend on its duration and the long winter periods contribute to root losses, particularly in combination with severe drought in the preceding growing season.

AB - By the end of the 21st century, frequent droughts and substantial shifts in snowmelt are expected to massively impact the biomass production of alpine grasslands. While the biomass of alpine plants consists to >80% of roots, little is known about the root growth dynamics in these ecosystems. To fill this gap, we capitalized on a longer-term experiment in the Swiss Alps with annually recurring treatments imposing advanced and delayed snowmelt and summer drought lasting 5 and 10 weeks. Over 3–4 growing seasons (2019–2022), we weekly quantified total root length of the plant community at two different soil depths (0–10 cm and 10–20 cm) using 90 minirhizotrons in 45 plots. We jointly assessed leaf elongation (of six abundant plant species) as proxies for the dynamics of biomass production. Increases in root length during summer continued beyond canopy development, with the duration of net root growth roughly double that of leaf expansion. Earlier and later snowmelt did not affect the proxies for total growth of leaves or roots but simply shifted their growing phases. Drought reduced leaf elongation across plant species whereas root length was stimulated by the 5-wk (not the 10-wk) drought in two seasons (+19% on average, 2020–2021). Natural rewetting after drought increased root growth by 38–77% compared to controls, but only in the 2020 growing season. Total root length in the topsoil declined by 7–15% during the last two winters, amounting to about one fourth of the previous seasons’ increase in root length. These root losses were 1.5 times higher following the 10-wk drought treatment. Our results highlight that earlier snowmelt alone will not stimulate productivity in alpine grassland. Root growth responses to drought depend on its duration and the long winter periods contribute to root losses, particularly in combination with severe drought in the preceding growing season.

KW - root phenology

KW - winter

KW - machine learning

KW - climate change

KW - rhizotron

KW - neural network

KW - leaf length

KW - snowmelt

U2 - 10.3389/fpls.2025.1625076

DO - 10.3389/fpls.2025.1625076

M3 - Journal article

VL - 16

JO - Frontiers in Plant Science

JF - Frontiers in Plant Science

SN - 1664-462X

ER -

Research

Links

Text available via DOI:

Keywords