Estimating the response of Himalayan old-growth mountain forests to decreased monsoon precipitation

https://doi.org/10.1016/j.agrformet.2023.109471Get rights and content
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Highlights

  • Throughfall exclusion did not impose tree mortality, but reduced stem increment.

  • Reduced soil moisture sharply decreased soil CO2 efflux.

  • Fine root biomass remained largely unaffected.

  • Himalayan mountain forests showed overall high resistance to throughfall exclusion.

Abstract

Forests in the Himalayas are a major carbon store, but are under threat due to changes in precipitation regime. To simulate a precipitation decline, throughfall-exclusion (TFE) shelters were applied during three consecutive monsoon seasons in an oak forest (2.650 m a.s.l.) and a conifer-dominated forest (3.260 m a.s.l.) in central Bhutan. Leaf water potentials, tree mortality, stem increment, soil CO2 efflux, litterfall and fine root dynamics were assessed. TFE significantly and consistently decreased topsoil (0–30 cm) moisture and leaf water potentials of Quercus lanata and Quercus griffithii (lower elevation), and to a lesser extend those of Tsuga dumosa and Quercus semecarpifolia, (higher elevation). TFE did not impose tree mortality. Stem increment remained unaffected until the second TFE year, but showed reductions during the third year with Tsuga dumosa being most severely affected (-60%). Standing fine root biomass stocks were hardly affected by TFE. Increased root necromass and faster fine root growth in the lower elevation forest suggest that the oak trees increased C allocation below ground. Soil CO2 efflux sharply declined during all three TFE years in both forests. Above ground litter input was unaffected by TFE until the second treatment year. Overall, both forest ecosystems appeared highly resistant to the imposed soil drying, with no signs of tree mortality and stable living root biomass stocks.

KEYWORDS

Forest carbon
Monsoon failure
Drought
Soil CO2 efflux
Fine roots biomass
Fine root production
Fine root decomposition
Water potential
Stem diameter growth

Data availability

  • Data will be made available on request.

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Contributed equally to the publication