Shimla, Dec 10 (IANS) Deodhar trees in Batseri, a scenic village in Sangla valley on the Baspa river in Himachal Pradesh, have revealed a story of shift from wetter spring conditions during the Little Ice Age to the progressively drier conditions since 1757 CE, with increased spring drought years in recent decades, buried in their rings, says a study.

The study analyses the factors responsible for the geohazard activities, enabling better prediction of future hazard events to support early warning systems.

The increasing frequency of extreme climatic events, such as droughts and floods, and their strong association with geohazards like landslides, glacial lake outburst floods, rockfalls and snow avalanches, especially in the Himalayan region, underscored the need for robust reconstructions of past hydroclimatic variability and related geohazard episodes.

Tree-rings, which are layers of new wood that form each year, providing a record of the tree’s age and past environmental conditions, act as natural archives to such climatic and geohazard events, offering the potential to bridge this knowledge gap.

The idea was further motivated by the absence of long-term high-resolution records and the need to understand the interactions between moisture variability and geohazard dynamics from the Himalayan region.

A rockfall episode in July 2021 near Batseri village in Kinnaur district led the Birbal Sahni Institute of Palaeosciences (BSIP), an autonomous institute of the Department of Science and Technology (DST), to explore past climates using dating of annual growth layers in trees (dendroclimatology and dendrogeomorphology).

They integrated dendroclimatology and dendrogeomorphology for future risk assessments and mitigation strategies.

Tree-ring analysis of deodar (Cedrus deodara) trees helped reconstruct a 378-year (1558-2021 CE) spring months’ moisture history and a 168-year (1853-2021 CE) rockfall activity record at Batseri in the western Himalayas.

The study showed that tree growth is highly sensitive to spring months’ (February to April) moisture, primarily influenced by winter precipitation derived through western disturbances.

A total of 53 rockfall events, including eight of high intensity, were linked to dry spring conditions, especially after the year 1960, indicating climate-induced ground instability.

The spring drought conditions led to slopes with poor vegetation cover, exposing them to vulnerability when the dry conditions are followed by the intense summer monsoon rainfalls.

The findings highlight the critical role of climate variability, driven by regional and global factors, in triggering the geohazards, underscoring the need for forest management, monitoring, and early warning systems.

The study published in the journal Catena enhanced understanding by providing insights on how climate variability, especially the spring and pre-monsoon summer droughts, trigger geohazards in the vulnerable Himalayan regions.

Such findings help local communities and policymakers in planning sustainable land-use, improving forest and water resource management and implementing slope stability measures.

This approach can reduce damage to infrastructure, protect livelihoods, and enhance disaster preparedness.

Moreover, such an approach empowers communities to adapt to climate change and mitigate its impacts on their environment and economy.

–IANS

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