Skip to content
Research Development, Science

Global research warns climate change is increasing groundwater temperatures

Charles Darwin University 3 mins read

A world first global groundwater temperature model projects that shallow groundwater will warm on average by between 2.1 and 3.5 degrees Celsius by the end of the century. 

Charles Darwin University (CDU) Outstanding Future Researcher Dr Dylan Irvine and University of Newcastle’s Dr Gabriel Rau collaborated with colleagues from Canada, Germany, and Austria to develop the model, which aims to reveal the long-term implications of on-going shallow water groundwater warming caused by climate change.

The model projects the highest warming rates will be in Central Russia, Northern China and parts of North America and the Amazon rainforest, with Australian groundwater temperatures also expected to rise.

Dr Irvine from CDU’s Research Institute for the Environment and Livelihoods said an increase in groundwater temperature can be a cause for concern.

“Groundwater is the water that is present beneath the Earth’s surface in pore spaces in rocks and soils. It is critical for life on earth,” Dr Irvine said.

“Groundwater temperature can influence a ecosystems, aquatic processes and water quality. If groundwater temperatures increase, then unfortunately many temperature sensitive groundwater dependent ecosystems may be threatened.

“A lot of focus on climate change has rightfully been to do with weather events and the availability of water, but we do need to think more broadly about the impact that climate change will have on groundwater.”

Unfortunately, for Australia the model projects that like other countries our groundwater temperatures are expected rise.

“Our groundwater here will warm but how much depends on whether or not humans can reduce greenhouse gas emissions to help mitigate climate change,” Dr Irvine said.

“These temperature increases can impact vital processes such as groundwater chemistry and metal leaching and microbiology which affects water quality.”

“If temperatures increase then we may see significant impacts to our local aquatic animals including their spawning processes which will impact industries and communities that are reliant on these ecosystems.”

Co-author and hydrogeology Lecturer from the University of Newcastle, Dr Gabriel Rau, warned that warming groundwater temperatures could adversely impact many ecosystems that rely on groundwater.

“Rivers rely on groundwater to keep flowing during dry times. Warm waters hold less dissolved oxygen. We’ve seen in the Murray Darling how low oxygen in water can contribute to fish deaths,” Dr Rau said.

According to the World Health Organisation, currently only 18 out of 125 countries have temperature guidelines for drinking water.

If groundwater continues to warm, it could also compromise the safety of drinking water.

“Our model estimates that by 2099, 59 to 588 million people worldwide will live in areas where groundwater exceeds the highest threshold for drinking water temperature guidelines set by any country,” Dr Rau said.

“As groundwater warms, there is increased risk of pathogen growth which impacts drinking water quality - potentially affecting the lives of many people.”

“This is especially concerning in areas where access to clean drinking water is already limited, and in areas where groundwater is consumed without treatment.”

Dr Rau also explained that rising groundwater temperatures also pose an economic risk.

“Many vital industries like agriculture, manufacturing, and energy production rely on groundwater for their operations. If the groundwater they depend on becomes too warm or more contaminated, it can disrupt their activities and potentially lead to economic losses,” Dr Rau said.

To illustrate the potential change in groundwater temperatures due to climate change, the research team, led by Dr Susanne Benz from the Karlsruhe Institute of Technology, has developed an interactive online application to show the projected temperature changes.

This Google Earth Engine app provides zoomable maps of annual mean, maximum and minimum groundwater temperatures at different depths and seasonal variability for selected years and climate scenarios, that the team hopes will facilitate further research.

The research paper titled ‘Global groundwater warming due to climate change can be found in the journal Nature Geoscience.


Contact details:

Emily Bostock
Media and Communications Officer

 

T: +61 8 8946 6529
M: 0432 417 518
E: 
media@cdu.edu.au

Media

More from this category

  • Engineering, Science
  • 05/12/2024
  • 09:45
UNSW Sydney

‘A million times better’: how frequency combs could provide a quantum leap for Satellite Network Synchronisation

Engineers at UNSW say exciting new developments in the way optical clocks can be synchronised has the potential to radically change global positioning systems – as well as fundamental cosmological theories. Satellites in space need to synchronise very precisely in order for communications to proceed efficiently. Synchronisation also allows the time taken for signals to be sent across a network to be calculated, which then allows positioning to be determined. Currently global positioning is accurate in most circumstances to within about 1 metre, but if the timing of signals is miscalculated by just 1 nanosecond the error would be a…

  • Energy, Science
  • 04/12/2024
  • 11:46
Charles Darwin University

CDU EXPERT: Ouch! Why do everyday objects keep zapping me?

4 DECEMBER, 2024 Who: AI expert and adjunct Associate Professor at Charles Darwin University in the Faculty of Science and Technology, and Associate Professor at Australian Catholic University Associate Professor Niusha Shafiabady. Associate Professor Shafiabady is an internationally recognised expert and developer of AI data analysis platform Ai-Labz. Topics: The discovery of static electricity, and how it works. How to avoid being zapped by static electricity. Contact details: Call +61 8 8946 6721 or email media@cdu.edu.au to arrange an interview. Quotes attributable to Associate Professor Shafiabady: “Static charge is inconvenient, but it is not dangerous except in places where we…

  • Energy, Science
  • 04/12/2024
  • 07:33
UNSW Sydney

Proton batteries: an innovative option for the future of energy storage

An eco-friendly, high-performance organic battery is being developed by scientists at UNSW Sydney. A team of scientists atUNSW Chemistryhave successfully developed an organic material that is able to store protons –and they have used it to create a rechargeable proton battery in the lab. By leveraging hydrogen ions – protons – instead of traditional lithium, these batteries hold promise for addressing some of the critical challenges in modern energy storage, including resource scarcity, environmental impact, safety and cost. The latest findings, recently published in the journalAngewandte Chemie, highlight the battery’s ability to store energy quickly, last longer, and perform well…

Media Outreach made fast, easy, simple.

Feature your press release on Medianet's News Hub every time you distribute with Medianet. Pay per release or save with a subscription.