THERMOS:Thermal Safety Margins of Earth's Tropical Forests
Lead Research Organisation:
University of Leeds
Department Name: Sch of Geography
Abstract
Earth's tropical forests provide an array of ecosystem services, housing over 50% of global biodiversity, taking up 8-13% of annual anthropogenic CO2 emissions, recycling rainfall at continental scales and directly providing livelihoods to millions of people. The biological and ecological processes that sustain these services (e.g. photosynthesis and transpiration) are strongly climate-sensitive, such that the future large-scale functioning of tropical forests depends on keeping their climate space within safe operating limits. Currently we do not know what the safe operating temperature limits for tropical forests are nor how close they are to upper limits of temperature function. There are three main reasons for this:
1) different plant processes are subject to different temperature thresholds - e.g. there are optimal temperatures for photosynthesis and also temperatures at which the photosynthetic apparatus begin to break down, but large data gaps prevent us from understanding how these limits vary across tropical forests and species
2) even for species where we do know the temperature thresholds for key physiological functions (e.g. breakdown of photosynthesis machinery), we usually do not have the leaf temperature records that allow us to gauge how close tropical trees are to these thresholds. The distinction between leaf and air temperature is key here - leaf temperatures are the physiologically meaningful measure of temperature and can be substantially different to air temperatures
3) we do not know what leaf-level metrics of temperature tolerance mean for the performance of the whole plant in terms of growth and mortality. It is unclear whether leaf traits can predict risk of heat-induced mortality. Temperature can affect plant performance directly (e.g. by reducing photosynthetic rate) but also indirectly by increasing the vapour pressure difference between the air and leaves (leaf-to-air vapour pressure deficit). Higher VPD increases plant water losses due to greater atmospheric demand for water but also results in reduced stomatal conductance and carbon assimilation rates. Recent studies have suggested that increasing tree mortality patterns observed in some temperate and tropical zones may be driven by increasing VPD. However, no study to date has sought to isolate the role of direct temperature effects vs. indirect VPD effects in inducing heat stress-driven mortality.
THERMOS will address each of these current bottlenecks to deliver unprecedented large-scale insights into the thermal risk of tropical forests. To do this, a diverse set of complementary methodologies will be used including: 1) extensive field data collection in tropical forests in four continents to determine the high temperature thresholds of key plant processes, 2) drone-based thermal imaging to determine maximum leaf temperatures reached in different sites, 3) new extreme heating greenhouse experiments to test the ability of leaf thermal traits to predict mortality and to evaluate the importance of direct vs. indirect VPD effects in driving mortality, 4) remote sensing to determine how thermally 'safe' forests are across the Tropics and 5) analysis of forest dynamics records to evaluate the role of increasing temperature and VPD in driving increased mortality across tropical forests.
1) different plant processes are subject to different temperature thresholds - e.g. there are optimal temperatures for photosynthesis and also temperatures at which the photosynthetic apparatus begin to break down, but large data gaps prevent us from understanding how these limits vary across tropical forests and species
2) even for species where we do know the temperature thresholds for key physiological functions (e.g. breakdown of photosynthesis machinery), we usually do not have the leaf temperature records that allow us to gauge how close tropical trees are to these thresholds. The distinction between leaf and air temperature is key here - leaf temperatures are the physiologically meaningful measure of temperature and can be substantially different to air temperatures
3) we do not know what leaf-level metrics of temperature tolerance mean for the performance of the whole plant in terms of growth and mortality. It is unclear whether leaf traits can predict risk of heat-induced mortality. Temperature can affect plant performance directly (e.g. by reducing photosynthetic rate) but also indirectly by increasing the vapour pressure difference between the air and leaves (leaf-to-air vapour pressure deficit). Higher VPD increases plant water losses due to greater atmospheric demand for water but also results in reduced stomatal conductance and carbon assimilation rates. Recent studies have suggested that increasing tree mortality patterns observed in some temperate and tropical zones may be driven by increasing VPD. However, no study to date has sought to isolate the role of direct temperature effects vs. indirect VPD effects in inducing heat stress-driven mortality.
THERMOS will address each of these current bottlenecks to deliver unprecedented large-scale insights into the thermal risk of tropical forests. To do this, a diverse set of complementary methodologies will be used including: 1) extensive field data collection in tropical forests in four continents to determine the high temperature thresholds of key plant processes, 2) drone-based thermal imaging to determine maximum leaf temperatures reached in different sites, 3) new extreme heating greenhouse experiments to test the ability of leaf thermal traits to predict mortality and to evaluate the importance of direct vs. indirect VPD effects in driving mortality, 4) remote sensing to determine how thermally 'safe' forests are across the Tropics and 5) analysis of forest dynamics records to evaluate the role of increasing temperature and VPD in driving increased mortality across tropical forests.
Organisations
- University of Leeds (Lead Research Organisation)
- Forestry Research Institute of Ghana (Collaboration, Project Partner)
- IISER Pune (Collaboration)
- UNEMAT - Nova Xavantina (Collaboration)
- University of Ghent (Collaboration)
- James Cook University (Collaboration, Project Partner)
- Mato Grosso State University (Unemat) (Project Partner)
- Ghent University (Project Partner)
- Kerala Forest Research Inst (KFRI) (Project Partner)
- University of Lincoln (Project Partner)
- Northern Arizona University (Project Partner)
- IISER, Pune (Indian Inst Sci Edu & Res) (Project Partner)
- University of Edinburgh (Project Partner)
- Sabah Forestry Department (Project Partner)
| Title | UAV-based Thermography method for determination of Thermal Safety Margins |
| Description | For THERMOS, we have developed a UAV-based method that allows us to evaluate the crown temperature of individual trees in the field. This has required the development of new protocols and workflows for undertaking thermal drone flights, on-the ground mapping to relate trees in tropical forest plots to drone images and analysis/processing of thermal imagery. |
| Type Of Material | Physiological assessment or outcome measure |
| Year Produced | 2024 |
| Provided To Others? | No |
| Impact | The development of this protocol now allows us to relate crown-level temperature data to tree performance metrics and functional trait attributes in the field. It provides new insights into which trees face greatest thermal risk. |
| Description | THERMOS Collaboration at CongoFlux site |
| Organisation | University of Ghent |
| Country | Belgium |
| Sector | Academic/University |
| PI Contribution | THERMOS proposes to evaluate the Thermal Safety Margins of Earth's tropical forests at a pan-tropical scale. The CongoFlux site in Yangambi, Democratic Republic of Congo, is an important site in this regard as it is located in the planet's second largest tropical forest region (the Congo Basin). THERMOS PDRA Emma Docherty will work with partners in UGhent to lead thermal trait data collection in Yangambi. |
| Collaborator Contribution | UGhent has been undertaking research in the Congo Flux site for many years and their expertise is critical for successful execution of the THERMOS field campaigns in DRC. The UGhent research team (Thomas Sibret, Marc Peaucelle, Hans Verbeeck) will work closely with the University of Leeds THERMOS team (David Galbraith, Emma Docherty, Calil Torres) in data collection and analysis. |
| Impact | No concrete outputs yet as the fieldwork in the DRC is due to take place in 2026. |
| Start Year | 2024 |
| Description | THERMOS Collaboration in Australia |
| Organisation | James Cook University |
| Country | Australia |
| Sector | Academic/University |
| PI Contribution | THERMOS proposes to evaluate the Thermal Safety Margins of Earth's tropical forests at a pan-tropical scale. As part of this effort, we will collect thermal trait and crown temperature data in two Australian rainforests (Daintree and Iron Range). THERMOS PDRA Emma Docherty will lead data collection in those sites. |
| Collaborator Contribution | In THERMOS, we are collaborating with Prof. Susan Laurance at James Cook University. Prof. Laurance has a very long history of working in Australian tropical forests and her local expertise is absolutely critical for the success execution of the planned fieldwork. Prof. Laurance also runs the Daintree through fall exclusion experiment. Daintree will be one of the core THERMOS sites. |
| Impact | Fieldwork planned to take place in 2025. Research outputs/outcomes to follow from field data collection campaigns. |
| Start Year | 2024 |
| Description | THERMOS Collaboration in Ghana |
| Organisation | Forestry Research Institute of Ghana |
| Country | Ghana |
| Sector | Public |
| PI Contribution | THERMOS proposes to evaluate the Thermal Safety Margins of Earth's tropical forests at a pan-tropical scale. Work in Ghana spans two THERMOS components: 1) maintenance of long-term canopy temperature data collection and 2) thermal trait data collection in two plots in Ghana maintained by FORIG partners (Dr. Shalom Addo-Danso) and by University of Plymouth partner Dr. Sophie Fauset. THERMOS PDRA Emma Docherty will work with partners in FORIG and Plymouth to lead the thermal trait data collection efforts in Ghana. |
| Collaborator Contribution | Dr. Sophie Fauset (Plymouth) and Dr. Addo-Danso (FORIG) jointly maintain a thermal camera operating system in Bobiri, Ghana. These long-term records are incredibly useful for understanding current thermal safety margins of tropical trees. Researchers in FORIG and Plymouth will jointly plan data collection in Ghana and jointly analyse the data. |
| Impact | Field data collection in Ghana planned for 2026. Outputs/outcomes will follow after successful completion of fieldwork. |
| Start Year | 2024 |
| Description | THERMOS Collaboration with UNEMAT |
| Organisation | UNEMAT - Nova Xavantina |
| Country | Brazil |
| Sector | Academic/University |
| PI Contribution | The THERMOS collaboration between researchers at the University of Leeds and UNEMAT is centred on joint research undertaken in project greenhouses set up on the UNEMAT campus in Nova Xavantina, Mato Grosso. The greenhouses were constructed with funds from the 'ARBOLES' NERC grant and are currently maintained with funds from THERMOS. THERMOS funds two full-time greenhouse staff based in Nova Xavantina. The research undertaken in the greenhouses focuses on experiments to elucidate the resilience of Amazon tree species to elevated temperatures and water stress. Planning of activities in the greenhouse is undertaken jointly between the University of Leeds team (Galbraith, Gloor) and collaborators in UNEMAT (Prof. Ben Hur and Beatriz Marimon). |
| Collaborator Contribution | Partners in UNEMAT contribute directly to collaboration by co-directing the work in the greenhouses (Prof. Beatriz and Ben Hur Marimon) and co-managing the greenhouse team. Post-graduate students in UNEMAT utilise the greenhouses for research purposes. Current work focuses on understanding the sensitivity of tropical tree species to high VPD and to understanding the mechanistic basis of drought-induced tree mortality. Post-graduate students undertaking their dissertations/theses in the greenhouses are funded externally to the main THERMOS grant. |
| Impact | As THERMOS has just started, there are as yet no specific THERMOS academic outputs from the greenhouse work. Work related to previous research cycles funded in ARBOLES is currently being finalised for submission. A workshop in Nova Xavantina was carried out in April 2024 to train students in an array of ecophysiological approaches used within THERMOS and associated projects. |
| Start Year | 2024 |
| Description | THERMOS collaboration with IISER Pune |
| Organisation | IISER Pune |
| Country | India |
| Sector | Public |
| PI Contribution | The University of Leeds (Prof. Emanuel Gloor, David Galbraith) and IISER Pune (Dr. Deepak Barua) are collaborating within THERMOS in two project components: 1) continuous measurements of leaf temperature in Sirsi, Karnataka and 2) plant thermal trait and thermal safety margin measurements in Karnataka and Sirsi. |
| Collaborator Contribution | Dr. Barua has long-standing expertise in leaf ecophysiology and co-leads the Indian component of THERMOS. |
| Impact | Although the collaboration within THERMOS started this year, Prof. Gloor and Prof. Galbraith have been working together for several years through NERC grant NE/R005079/1, led by Prof. Emanuel Gloor. As the collaboration with IISER Pune through THERMOS is still very new, there are no concrete outputs yet. However, the longer-term collaboration with Prof. Barua has resulted in publications (e.g. https://onlinelibrary.wiley.com/doi/10.1111/gcb.70069), joint postgraduate supervision and training workshops delivered in India. |
| Start Year | 2024 |