{"id":1283,"date":"2025-02-07T12:51:00","date_gmt":"2025-02-07T12:51:00","guid":{"rendered":"https:\/\/research.reading.ac.uk\/palaeoclimate\/?p=1283"},"modified":"2025-02-07T12:51:00","modified_gmt":"2025-02-07T12:51:00","slug":"understanding-past-climate-to-predict-future-vegetation-changes","status":"publish","type":"post","link":"https:\/\/research.reading.ac.uk\/palaeoclimate\/understanding-past-climate-to-predict-future-vegetation-changes\/","title":{"rendered":"Understanding Past Climate to Predict Future Vegetation Changes"},"content":{"rendered":"

Research assistant in the SPECIAL group, Jierong Zhao, and SPECIAL group PI, Sandy Harrison, have recently released a pre-print that investigates the importance of CO\u2082 and climate in influencing changes in GPP over the Quaternary. Here we summarise of the key highlights but you can access the full pre-print below for all of the details of this new and exciting study!<\/p>\n

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Eco-evolutionary Modelling of Global Vegetation Dynamics and the Impact of CO2 during the late Quaternary: Insights from Contrasting Periods<\/a><\/p>\n

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Why Study Global Greening?<\/strong><\/p>\n

Predicting how terrestrial vegetation will respond to future climate scenarios is crucial for understanding global greening. While climate is a key driver of vegetation change, carbon dioxide (CO\u2082) levels also play a fundam\u00a0ental role by influencing plant productivity and the balance between C3<\/sub> and C4<\/sub> plants.<\/p>\n

However, disentangling the relative importance of climate and CO\u2082 is challenging, especially since modern climate change is largely CO\u2082-driven. Studying past climate shifts\u2014where climate was altered by natural orbital cycles rather than rising CO\u2082\u2014offers a unique opportunity to isolate these effects.<\/p>\n

To do this, researchers use a counterfactual experiment, where climate and CO\u2082 are manipulated separately in models to see which factor has a bigger impact and where those effects are strongest. This approach allows us to understand how vegetation responded to past changes and, in turn, improve predictions for the future.<\/p>\n

The Key Takeaways<\/strong><\/p>\n

To model the effects of climate and CO\u2082 on gross primary production (GPP) (a measure of plant productivity), the study used:<\/p>\n