Artigo

Airborne observations reveal elevational gradient in tropical forest isoprene emissions

Isoprene dominates global non-methane volatile organic compound emissions, and impacts tropospheric chemistry by influencing oxidants and aerosols. Isoprene emission rates vary over several orders of magnitude for different plants, and characterizing this immense biological chemodiversity is a chall...

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Autor principal: Gu, Dasa
Outros Autores: Guenther, Alex B., Shilling, John E., Yu, Haofei, Huang, Maoyi, Zhao, Chun, Yang, Qing, Martin, Scot T., Artaxo, Paulo, Kim, Saewung, Seco, Roger, Stavrakou, Trissevgeni, Longo, Karla Maria, Tóta, Júlio, Souza, Rodrigo Augusto Ferreira de, Vega, Oscar B., Liu, Ying, Shrivastava, Manish K., Alves, Eliane Gomes, Santos, Fernando C., Leng, Guoyong, Hu, Zhiyuan
Grau: Artigo
Idioma: English
Publicado em: Nature Communications 2020
Assuntos:
Isoprene
Air Quality
Airborne Survey
Eddy Covariance
Elevation
Isoprene
Satellite Altimetry
Tropical Forest
Volatile Organic Compound
Air Pollution
Air Quality
Airborne Paircraft
Amazonas
Boundary Layer
Carbon Footprint
Climate Change
Eddy Covariance
Environmental Impact
Global Climate
Land Use
Mass Spectrometry
Measurement
Photooxidation
Pollution Monitoring
Prediction
Proton Transport
Species Distribution
Tropical Rain Forest
Wavelet Analysis
Amazonia
Acesso em linha: https://repositorio.inpa.gov.br/handle/1/15734
Resumo:
Isoprene dominates global non-methane volatile organic compound emissions, and impacts tropospheric chemistry by influencing oxidants and aerosols. Isoprene emission rates vary over several orders of magnitude for different plants, and characterizing this immense biological chemodiversity is a challenge for estimating isoprene emission from tropical forests. Here we present the isoprene emission estimates from aircraft eddy covariance measurements over the Amazonian forest. We report isoprene emission rates that are three times higher than satellite top-down estimates and 35% higher than model predictions. The results reveal strong correlations between observed isoprene emission rates and terrain elevations, which are confirmed by similar correlations between satellite-derived isoprene emissions and terrain elevations. We propose that the elevational gradient in the Amazonian forest isoprene emission capacity is determined by plant species distributions and can substantially explain isoprene emission variability in tropical forests, and use a model to demonstrate the resulting impacts on regional air quality. © The Author(s) 2017.

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