Details of Award

NERC Reference : NE/Z504142/1

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Implications of glacier retreat for aquatic biodiversity in the Himalayas

Grant Award

Principal Investigator:: Professor LE Brown, University of Leeds, Sch of Geography
Co-Investigator:: Dr T Maavara, University of Leeds, Sch of Geography
Co-Investigator:: Professor D Quincey, University of Leeds, Sch of Geography
Co-Investigator:: Professor AJ Dumbrell, University of Essex, Life Sciences
Grant held at:: University of Leeds, Sch of Geography

Science Area:: None
Overall Classification:: Unknown

ENRIs:: None
Science Topics:: None

Abstract:: Although glaciers cover only ~10% of Earth's surface, their meltwater rivers are used extensively for hydropower, irrigation and water supply by almost 2 billion people worldwide. Aquatic organisms in these rivers, such as micro-organisms, algae and invertebrates, maintain these critical services by efficiently transferring matter into aquatic and terrestrial food webs, moderating nutrient fluxes, and breaking down pollutants. Conversely, some aquatic organisms pose threats to human health if conditions enable their proliferation. However, glaciers are losing mass at accelerating rates worldwide and many will disappear by 2100, creating huge uncertainties about how these ecosystems will respond. Understanding of biodiversity and functional processes influencing river water quality, and how they change as glaciers are lost, is especially poor for the Himalayas yet this is where the demand for clean water is highest, and people are most vulnerable. This project will develop and implement a standardised, multi-organism research strategy for high-elevation rivers in Nepal, in which ecological understanding is integrated with modelled glacier retreat scenarios to predict how and where species distributions and water quality will change in future. The objectives are to (i) determine the biodiversity of these unique river ecosystems; (ii) discover the functional roles of micro-organisms and invertebrates influencing key water quality and carbon cycle processes; (iii) unravel the importance of physical, chemical and biotic processes alongside dispersal barriers for governing where species can live now and in future. In doing so, we will (iv) reveal how species, communities and ecosystem processes that are critical to maintaining high-quality water will respond as climate change drives high-elevation warming and glacier recession. The project will develop a new strategy for monitoring high-elevation rivers, leveraging expertise from academic and local sources, including DNA-based surveys and logistical support for expeditions in challenging mountain environments. The research will focus on three regions (Annapurna, Langtang, Sagarmatha (Everest)) with high biodiversity and varied river conditions, with an emphasis on Archaea, Bacteria, Fungi, Algae and Invertebrates. Repeat sampling in Sagarmatha will track seasonal dynamics to melt cycles and monsoon rainfall. The project consists of work packages focusing on (i) current population dynamics, (ii) community structure and functional processes influencing water quality, and (iii) modelling studies to determine the processes structuring these communities as well as predictions for how future glacier loss to 2100 will impact rivers. Key findings from these linked work packages will inform reports, scientific publications and data packages for a variety of users. The Himalayas are experiencing rapid warming and ice loss, posing a significant threat to their rich biodiversity. Therefore, this research will be a vital baseline for biodiversity and water quality monitoring to benefit conservation, government, and businesses. As glaciers recede, new land will be exposed attracting extractive industries and increasing dam construction, further endangering biodiversity and requiring sustainable solutions. Changing water sources may also expose communities to pathogens requiring upgrades to drinking water treatment. The project will benefit scientists by advancing wider understanding in ecology, in particular mechanisms of ecosystem resilience to climate change and disturbance, and trait-based approaches to predict ecosystem structure and processes. Students and the public will benefit via website and media dissemination. Open-access data will allow other researchers to compare findings and contribute to global comparative analyses. Through existing roles, the team will communicate findings to IPCC assessments ensuring the research informs global policymakers.

Period of Award:: 1 Mar 2025 - 29 Feb 2028
Value:: £840,117

(FY details)

Authorised funds only

NERC Reference:: NE/Z504142/1
Grant Stage:: Awaiting Authorisation
Scheme:: Research Grants
Grant Status:: Approved
Programme:: Pushing the Frontiers

This grant award has a total value of £840,117

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FDAB - Financial Details (Award breakdown by headings)

DI - Other Costs	Indirect - Indirect Costs	DA - Investigators	DI - Staff	DA - Estate Costs	DA - Other Directly Allocated	DI - T&S
£94,452	£301,952	£73,760	£190,866	£63,370	£34,418	£81,298

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