logo
#

Latest news with #ClimateLeafAnalysisMultivariateProgram

Growing Pir Panjal ranges contributed to Kashmir's present-day Mediterranean weather: Study
Growing Pir Panjal ranges contributed to Kashmir's present-day Mediterranean weather: Study

Indian Express

time3 days ago

  • Science
  • Indian Express

Growing Pir Panjal ranges contributed to Kashmir's present-day Mediterranean weather: Study

The natural upliftment of the Pir Panjal ranges which occurred some four million years ago contributed in altering the weather over the Kashmir valley to its present-day Mediterranean-type climate, a new study has revealed. Nicknamed as the Switzerland of the East, today's Kashmir experiences mild summers and harsh, wet winters. The main source of groundwater and waterbody replenishment in the Valley occurs by the snow or rainfall during the winter associated with the passing streams of western disturbances. Winter in the Valley peaks between mid-December – January. ' The uplift of the Pir Panjal range, also known as the Lesser Himalayas, created an orographic barrier that impeded moisture-laden summer monsoon winds from reaching the Valley. Gradually, it led to the establishment of a Mediterranean-type climate,' the latest study published in the journal of Palaeogeography, Palaeoclimatology, Palaeoecology, suggested. A group of researchers from the Birbal Sahni Institute of Palaeosciences (BSIP) and the University of Kashmir's Department of Earth Sciences used leaf sediments from the Karewa formations in the Valley to recreate the palaeoclimatic past. Over the past four million years, this basin has been fed with fluvial-glacial-lacustrine sediments which have been studied by the research group. The study teams deployed the Climate Leaf Analysis Multivariate Program and the Coexistence approach in this work. The Kashmir Valley is estimated to have formed about 4 million years ago due to natural upliftment of the Pir Panjal mountain ranges, also known as the Lesser Himalayas. The Kashmir Basin is an oval, bowl-shaped depression, with a relatively flat basin floor. It measures approximately 140 km in length and 40 km in width and covers an area of about 5000 sq. km in the northwestern region of the Himalayas. In the process of upliftment, it blocked the ancient Himalayan drainage system and led to the formation of a vast lake. With the continued uplift of the Pir Panjal Range, the lake gradually shrank and shifted toward the Greater Himalayas. The study detailed that there once existed strong seasonality in the Valley until 1.95 million years ago. The accelerated rise of the Pir Panjal thereafter prevented the southwest monsoon winds from reaching the Valley. The monthly rainfall extremes ranged from 10mm to 220mm with the annual mean to be around 1230mm. The group calculated the Valley's mean annual temperature ranged at about 18.1 degrees Celsius and the cold month mean temperature was 11.1 degrees Celsius. Other recent studies of the Kashmir regions' rainfall variability in recent decades showed that about 72 per cent of the annual precipitation came from the western disturbances whereas the remaining 28 per cent was contributed by the Indian Summer Monsoon. Moreover, the influence of the summer monsoon was higher towards south Kashmir, while north Kashmir was mostly influenced by western disturbances.

Kashmir's cool climate was once a subtropical paradise, study reveals
Kashmir's cool climate was once a subtropical paradise, study reveals

United News of India

time11-07-2025

  • Science
  • United News of India

Kashmir's cool climate was once a subtropical paradise, study reveals

New Delhi, July 10 (UNI) While Kashmir's cool, temperate climate is widely relished today, you will be surprised to know that it was once a warm, humid subtropical haven, as has been revealed by a recent study. This stark transformation, now buried in the past, has been uncovered through the analysis of fossilized leaves and tectonic processes that reshaped the region's environment, said the research led by experts from the Birbal Sahni Institute of Palaeosciences (BSIP), Lucknow under the autonomous institute of the Department of Science and Technology (DST). The experts uncovered the rich collection of fossilized leaves from the Karewa sediments of Kashmir, which were curated by the late Prof. Birbal Sahni and Dr. GS Puri. These specimens, remarkably well-preserved, exhibit a striking resemblance to subtropical plants no longer found in the valley's current temperate ecosystem. Intrigued by this stark contrast between past and present vegetation, a team of palaeobotanists, including Dr Harshita Bhatia, Dr. Reyaz Ahmad Dar, and Dr Gaurav Srivastava, delved deeper into the region's climatic and tectonic evolution. Their research points to the tectonic uplift of the Pir Panjal Range, a sub-Himalayan mountain range, as the key factor behind this drastic transformation. The gradual rise of the Pir Panjal Range is believed to have blocked the Indian summer monsoon, cutting off the water supply to the valley. Over millennia, this tectonic event shifted the region from a subtropical paradise to a Mediterranean-type climate, drying up its lush forests and altering the very fabric of its ecosystem. The scientists employed advanced methodologies, such as CLAMP (Climate Leaf Analysis Multivariate Program), to analyze the shape, size, and margins of the fossilized leaves. This enabled them to reconstruct temperature and rainfall patterns from millions of years ago and cross-check these with modern-day plant relatives. The results provided a vivid picture of a warm, rain-soaked Kashmir, which gradually became more arid as the mountain range rose, as per a statement from the DST. Published in the journal Palaeogeography, Palaeoclimatology, Palaeoecology, the study is not just a glimpse into Kashmir's climatic past but also a crucial tool for understanding the potential impact of ongoing climate change. As global temperatures continue to rise and alter rainfall patterns, this research offers valuable insights into how mountain ecosystems, like the Himalayas, might adapt—or struggle—in response to environmental shifts. The findings also highlight the importance of preserving fragile mountain regions, which are particularly vulnerable to the effects of climate change. By studying how ancient tectonic shifts influenced climate, scientists can develop better models to predict future environmental changes and their impact on ecosystems, said the statement. UNI AJ PRS

DOWNLOAD THE APP

Get Started Now: Download the App

Ready to dive into a world of global content with local flavor? Download Daily8 app today from your preferred app store and start exploring.
app-storeplay-store