Abstract
The Hindukush-Karakoram-Himalayan region is a crucial freshwater source for billions across South Asia, yet its climate remains poorly understood due to limited long-term records. Winter and spring precipitation govern snow accumulation and downstream water availability in dry months particularly across the Western Himalayas (WH), but recent decades show intensifying droughts with unclear long-term context. We have reconstructed a nearly four-century-long spring i.e. February to May (FMAM) precipitation for the Lahaul region of the (WH), an area dominated by the Western Disturbances. This record was developed using moisture-sensitive Cedrus deodara (Deodar) tree-rings from three high-elevation sites. A regional composite tree-ring-width chronology, developed through a Nested Principal Component Analysis and modeled with a nonlinear Generalized Additive Model (GAM) that explains 71 % of the variance during the calibration period. We identified the last two decades as the most precipitation deficit phase and the year 2022 showing the driest FMAM on record. The observed rise in the FMAM dry episodes post 1999 CE in our reconstruction, corresponds to the meteorological records. This recent drying is linked to a northward shift of the subtropical westerly jet and reduced moisture transport, both associated with unusual sea surface temperature patterns in the tropical Indian Ocean and the Western Pacific Ocean. Our results provide compelling evidence of long-term hydroclimatic instability in the WH and emphasize the value of tree-ring records in extending precipitation histories beyond the instrumental observations. Such reconstructions can be benchmarks to validate high-resolution climate models and formulate adaptation policies to mitigate future risks.
| Original language | English |
|---|---|
| Article number | 181315 |
| Journal | Science of the Total Environment |
| Volume | 1013 |
| DOIs | |
| State | Published - Jan 20 2026 |
Funding
The authors would like to express their gratitude to Prof. Mahesh G. Thakkar, Director, Birbal Sahni Institute of Palaeosciences, Lucknow, India, for providing official permission (BSIP/RDCC/ Publication No. 28/2025-26) and necessary facilities to carry out this work. PSR and MS acknowledge the BSIP In-house project 6. PP would also like to express gratitude to the University Grants Commission, India (UGC ID. 190510227925) for the fellowship support. AB, MS also acknowledge the National Mission of Himalayan Studies (NMHS), Ministry of Environment, Forest and Climate Change (Government of India), NMHS 2024-25/SC-XIII/MG/SL-16. PP is also grateful to Rinku, Ishtiaq (Central University of Punjab, Bhatinda), and Shreya Shri (Rajat PG College, Lucknow) for their help and support during sample collection and with the GIS methods. M.A is supported by the U.S. Air Force Numerical Weather Modeling Program and National Climate-Computing Research Center, located within the National Center for Computational Sciences at the ORNL, and supported under a Strategic Partnership Project 2316-T849-08 between DOE and NOAA. DL would like to express his gratitude toward the University Grants Commission (UGC) for financially supporting (UGC ID: 210510821563). PC acknowledges support from the Core Research Grant (CRG) no. CRG/2022/008280, funded by the Science and Engineering Research Board (SERB), Department of Science and Technology (GoI). The PCCF, DFO, and other forest officials of the Forest Departments of Himachal Pradesh are deeply acknowledged for their support and permission to collect samples.
Keywords
- Cedrus deodara
- Drought intensification
- General additive model
- Precipitation reconstruction
- Sea surface temperatures
- Subtropical westerly jet
- Tree-ring-width chronology
- Western disturbances