Tropical deforestation causes large reductions in observed precipitation

Smith, Callum; Baker, Jessica C. A.; Spracklen, Dominick V.

doi:10.1038/s41586-022-05690-1

Cited by 97 publications

(62 citation statements)

References 69 publications

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“…The loss of once‐abundant paleo‐Antarctic trees from Malesia's uplands is likely to have near‐term adverse effects on biodiversity, nutrient cycling, forest structure, floral composition, carbon stocks, rainfall patterns, watershed integrity, and heat islands (e.g. Zeng et al ., 2021; Smith et al ., 2023). If our hypotheses are correct, the extirpation of specialized PARLs such as the austral conifers, which may be involved in enhancing CO 2 consumption, will reduce the possibility of icehouse climates in the future, long after geologically anomalous emissions from human activities have ended.…”

Section: Discussionmentioning

confidence: 99%

Do Southeast Asia's paleo‐Antarctic trees cool the planet?

Wilf

Kooyman

2023

New Phytologist

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Summary Many tree genera in the Malesian uplands have Southern Hemisphere origins, often supported by austral fossil records. Weathering the vast bedrock exposures in the everwet Malesian tropics may have consumed sufficient atmospheric CO2 to contribute significantly to global cooling over the past 15 Myr. However, there has been no discussion of how the distinctive regional tree assemblages may have enhanced weathering and contributed to this process. We postulate that Gondwanan‐sourced tree lineages that can dominate higher‐elevation forests played an overlooked role in the Neogene CO2 drawdown that led to the Ice Ages and the current, now‐precarious climate state. Moreover, several historically abundant conifers in Araucariaceae and Podocarpaceae are likely to have made an outsized contribution through soil acidification that increases weathering. If the widespread destruction of Malesian lowland forests continues to spread into the uplands, the losses will threaten unique austral plant assemblages and, if our hypothesis is correct, a carbon sequestration engine that could contribute to cooler planetary conditions far into the future. Immediate effects include the spread of heat islands, significant losses of biomass carbon and forest‐dependent biodiversity, erosion of watershed values, and the destruction of tens of millions of years of evolutionary history.

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Section: Discussionmentioning

confidence: 99%

Do Southeast Asia's paleo‐Antarctic trees cool the planet?

Wilf

Kooyman

2023

New Phytologist

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“…Such differences are also found in the Amazon, although differences are smaller (at the mean annual scale, ρ for = 26%, ρ terr = 42%). Compared to the Amazon, the Congo rainforest is also projected to face greater future threats of forest loss and greater deforestation impacts on regional precipitation (Smith, Baker, & Spracklen, 2023).…”

Section: Potential Implications For Forest Governancementioning

confidence: 99%

Dry Periods Amplify the Amazon and Congo Forests' Rainfall Self-Reliance

Wang‐Erlandsson

Ent

Staal

et al. 2023

Preprint

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A substantial amount of the tropical forests of South America and Africa is generated through moisture recycling (i.e., forest rainfall self-reliance). Thus, deforestation that reduces evaporation and dampens the water cycle can further increase the risk of water-stress-induced forest loss in downwind areas, particularly during water scarce periods. However, few studies have investigated dry period forest rainfall self-reliance over longer records and consistently compared the rainforest moisture recycling in both continents. Here, we analyze dry-season anomalies of moisture recycling for mean-years and dry-years, in the South American (Amazon) and African (Congo) rainforests over the years 1980-2013. We find that, in the dry seasons, the reliance of forest rainfall on their own moisture supply (ρfor) increases by 7% (from a mean annual value of 26% to 28%) in the Amazon and up to 30% (from 28% to 36%) in the Congo. Dry years further amplify dry season ρfor in both regions by 4-5%. In both the Amazon and Congo, dry season amplification of ρfor is strongest in regions with a high mean annual ρfor. In the Amazon, forest rainfall self-reliance has declined over time. At the country scale, dry season ρfor can differ drastically from mean annual ρfor. In for example Bolivia and Gabon, mean annual ρfor is ~30% while dry season ρfor is ~50%. The dry period amplification of forest rainfall self-reliance further highlights the role of forests for sustaining their own resilience, and for maintaining downwind rainfall at both regional and national scales.

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“…Changes in one of these components are directly or indirectly communicated to the others via intricately linked processes and feedbacks occurring at their interfaces (e.g. Stocker et al, 2013;Nolan et al, 2018;Smith et al, 2023). The SMEAR stations together with the SMEAR concept were established before the various international environmental research infrastructures were established (Hari and Kulmala, 2005).…”

Section: Smear Conceptmentioning

confidence: 99%

Opinion: The strength of long-term comprehensive observations to meet multiple grand challenges at different environments and in the atmosphere

Kulmala

Lintunen

Lappalainen

et al. 2023

Preprint

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Abstract. To be able to meet global grand challenges (climate change; biodiversity loss; environmental pollution; scarcity of water, food and energy supplies; acidification; deforestation; chemicalization; pandemics), which all are closely interlinked with each other, we need comprehensive open data with proper metadata. The large data sets from ground-base in situ observations, ground and satellite remote sensing and multiscale modelling need to be utilized seamlessly. In this opinion paper, we describe the SMEAR (Station for Measuring Earth surface – Atmosphere Relations) concept. We also demonstrate its power via several examples, such as detection of new particle formation and their subsequent growth, quantifying atmosphere-ecosystem feedback loops, combining comprehensive observations with emergency science and services, as well as studying the effect of COVID restrictions on different air quality and climate variables. The future needs and the potential of comprehensive observations of the environment are summarized.

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Tropical deforestation causes large reductions in observed precipitation

Cited by 97 publications

References 69 publications

Do Southeast Asia's paleo‐Antarctic trees cool the planet?

Do Southeast Asia's paleo‐Antarctic trees cool the planet?

Dry Periods Amplify the Amazon and Congo Forests' Rainfall Self-Reliance

Opinion: The strength of long-term comprehensive observations to meet multiple grand challenges at different environments and in the atmosphere

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