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4. | | COLLICCHIO, E.; ROCHA, H. R. da; VICTORIA, D. de C.; ANDRADE, A. de M. Cenários prospectivos de mudanças climáticas para o estado do Tocantins. In: COLLICCHIO, E.; ROCHA, H. R. da (org.). Agricultura e mudanças do clima no estado do Tocantins: vulnerabilidades, projeções e desenvolvimento. Palmas, TO: EdUFT, 2022. pt. II, cap. 6, p. 133-163. Biblioteca(s): Embrapa Agricultura Digital. |
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9. | | ROCHA, H. R. da; CABRAL, O. M. R.; DIAS, M. A. F. da S.; BARBOSA, V.; CARVALHO, R. S. Fluxos turbulentos de calor, H2O e CO2, sobre cana-de-açúcar em Sertãozinho, SP. In: CONGRESSO BRASILEIRO DE AGROMETEOROLOGIA, 10., 1997, Piracicaba. Agrometeorologia, monitoramento ambiental e agricultura sustentável: anais. Piracicaba: SBA / 544- Biblioteca(s): Embrapa Meio Ambiente. |
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10. | | CABRAL, O. M. R.; ROCHA, H. R. da; LIGO, M. A. V.; BRUNINI, O.; DIAS, M. A. F. S. Fluxos turbulentos de calor sensível, vapor de água e CO2 sobre plantação de cana-de-açucar (Saccharum sp.) em Sertãozinho-SP. Revista Brasileira de Meteorologia, Rio de Janeiro, v. 18, n. 1, p. 61-70, 2003. Biblioteca(s): Embrapa Meio Ambiente. |
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11. | | COLLICCHIO, E.; ROCHA, H. R. da; VICTORIA, D. de C.; ANDRADE, A. de M.; TOLEDO, A. M. A. Potenciais efeitos dos cenários futuros do clima na aptidão agroclimática da cana-de-açúcar no estado do Tocantins. In: COLLICCHIO, E.; ROCHA, H. R. da (org.). Agricultura e mudanças do clima no estado do Tocantins: vulnerabilidades, projeções e desenvolvimento. Palmas, TO: EdUFT, 2022. pt. III, cap, 9, p. 201-222. Biblioteca(s): Embrapa Agricultura Digital. |
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12. | | FLACK-PRAIN, S.; SHI, L.; ZHU, P.; ROCHA, H. R. da; CABRAL, O. M. R.; HU, S.; WILLIAMS, M. The impact of climate change and climate extremes on sugarcane production. Global Change Biology Bioenergy, v. 13. n. 3, p. 408-424, 2021. Biblioteca(s): Embrapa Meio Ambiente. |
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13. | | COLLICCHIO, E.; ROCHA, H. R. DA; VICTORIA, D. de C.; BALLESTER, M. V. R.; TOLEDO, A. M. A. Implicações das mudanças do clima no zoneamento agroclimático da cana-de-açúcar no estado do Tocantins, considerando o modelo GFDL. Revista Brasileira de Geografia Física, Recife, v. 08, n. 06, p. 1730-1747, 2015. Biblioteca(s): Embrapa Territorial. |
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14. | | OGASAWARA, M.; OTTO, M.; MATTOS, E. J. de; ROCHA, H. R. da; FIGUEIREDO, R. de O.; FERRAZ, S. Effects of climate change on water yield and water quality of forested watersheds in Southeastern Brazil. Pesquisa Florestal Brasileira, v. 39, e201902043, p. 649, 2019. Special issue. Abstracts of the XXV IUFRO World Congress, 2019. p. 649 Biblioteca(s): Embrapa Meio Ambiente. |
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15. | | CABRAL, O. M. R.; ROCHA, H. R. da; GASH, J. H. C.; FREITAS, H. C. de; LIGO, M. A. V. Water and energy fluxes from a woodland savanna (cerrado) in southeast Brazil. Journal of Hydrology: Regional Studies, Amsterdam, v. 4, part. B, p. 22-40, 2015. Biblioteca(s): Embrapa Meio Ambiente. |
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16. | | TATSCH, J. D.; ROCHA, H. R. da; FREITAS, H. C. de; CABRAL, O. M. R.; TANNUS, R. N.; ACOSTA, R. Variações dos fluxos de energia na conversão de Cerrado por cana-de-açúcar. In: WORKSHOP BRASILEIRO DE MICROMETEOROLOGIA, 4., 2005, Santa Maria. Revista Ciência e Natura, Edição Especial, p. 111-114, dez. 2005. Biblioteca(s): Embrapa Meio Ambiente. |
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17. | | CABRAL, O. M. R.; GASH, J. H. C.; ROCHA, H. R. da; MARSDEN, C.; LIGO, M. A. V.; FREITAS, H. C. de; TATSCH, J. D.; GOMES, E. Fluxes of CO2 above a plantation of Eucalyptus in southeast Brazil. Agricultural and Forest Meteorology, v. 151, p. 49?59, 2011. Biblioteca(s): Embrapa Meio Ambiente. |
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18. | | CABRAL, O. M. R.; ROCHA, H. R. da; GASH, J. H.; LIGO, M. A. V.; RAMOS, N. P.; PACKER, A. P.; BATISTA, E. R. Fluxes of CO2 above a sugarcane plantation in Brazil. Agricultural and Forest Meteorology, Amsterdam, v. 182-183, p. 54-66, 2013. Biblioteca(s): Embrapa Meio Ambiente. |
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19. | | GIONGO, P. R.; MOURA, G. B. de A.; SILVA, B. B.; ROCHA, H. R. da; MEDEIROS, S. R. R. de; NAZARENO, A. C. Albedo à superfície a partir de imagens Landsat 5 em áreas de cana-de-açúcar e cerrado. Revista Brasileira de Engenharia Agrícola e Ambiental, v.14, n.3, p.279–287, mar., 2010. Biblioteca(s): Embrapa Algodão. |
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20. | | SAAD, S. I.; SILVA, J. M. da; SILVA, M. L. N.; GUIMARAES, J. L. B.; SOUSA JUNIOR, W. C.; FIGUEIREDO, R. de O.; ROCHA, H. R. da. Analyzing ecological restoration strategies for water and soil conservation. Plos One, v. 13, n. 2, e0192325, 2018. Biblioteca(s): Embrapa Meio Ambiente. |
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Registro Completo
Biblioteca(s): |
Embrapa Meio Ambiente. |
Data corrente: |
28/12/2021 |
Data da última atualização: |
15/03/2022 |
Tipo da produção científica: |
Artigo em Periódico Indexado |
Circulação/Nível: |
A - 1 |
Autoria: |
FLACK-PRAIN, S.; SHI, L.; ZHU, P.; ROCHA, H. R. da; CABRAL, O. M. R.; HU, S.; WILLIAMS, M. |
Afiliação: |
SOPHIE FLACK-PRAIN, University of Edinburgh; LIANGSHENG SHI, Wuhan University; PENGHUI ZHU, Wuhan University; HUMBERTO RIBEIRO DA ROCHA, IAG-USP; OSVALDO MACHADO RODRIGUES CABRAL, CNPMA; SHUN HU, Wuhan University; MATHEW WILLIAMS, University of Edinburgh. |
Título: |
The impact of climate change and climate extremes on sugarcane production. |
Ano de publicação: |
2021 |
Fonte/Imprenta: |
Global Change Biology Bioenergy, v. 13. n. 3, p. 408-424, 2021. |
DOI: |
https://doi.org/10.1111/gcbb.12797 |
Idioma: |
Inglês |
Conteúdo: |
Abstract: Sugarcane production supports the livelihoods of millions of small-scale farmers in developing countries, and the bioenergy needs of millions of consumers. Yet, future sugarcane yields remain uncertain due to differences in climate projections, and because the sensitivity of sugarcane ecophysiology to individual climate drivers (i.e. temperature, precipitation, shortwave radiation, VPD and CO2) and their interactions is largely unresolved. Here we ask: how sensitive is sugarcane yield to future climate change, including climate extremes, and what are its key climate drivers? We combine the Soil-Plant-Atmosphere model with detailed time-series measurements from experimental plots in Guangxi, China, and Sao Paulo State, Brazil. We first calibrated and validated modelled carbon and water cycling against field flux and biometric data. Second, we simulated sugarcane growth under the historical climate (1980-2018), and six future climate projections (2015-2100). We computed the 'yield-effect' of each climate driver by generating synthetic climate forcings in which the driver time series was alternated to that of the historical median. In Guangxi, median yield and yield lows (i.e. lower decile) were relatively insensitive to forecast climate change. In Sao Paulo, median yield and yield lows decreased under all future climates projections (x over bar = -4% and -12% respectively). At Guangxi, where moisture stress was low, radiation was the principal driver of yield variability (yield-effect x over bar = -1.2%). Conversely, high moisture stress at Sao Paulo raised yield sensitivity to temperature (yield-effect x over bar = -7.9%). In contrast, a number of other modelling studies report a positive effect of increased temperatures on sugarcane yield. We ascribe the disparity between model predictions to the representation of key phenological processes, including the link between leaf ageing and thermal time, and the role of ageing in driving leaf senescence. We highlight climate sensitivity of phenological processes as a key focus for future research efforts. MenosAbstract: Sugarcane production supports the livelihoods of millions of small-scale farmers in developing countries, and the bioenergy needs of millions of consumers. Yet, future sugarcane yields remain uncertain due to differences in climate projections, and because the sensitivity of sugarcane ecophysiology to individual climate drivers (i.e. temperature, precipitation, shortwave radiation, VPD and CO2) and their interactions is largely unresolved. Here we ask: how sensitive is sugarcane yield to future climate change, including climate extremes, and what are its key climate drivers? We combine the Soil-Plant-Atmosphere model with detailed time-series measurements from experimental plots in Guangxi, China, and Sao Paulo State, Brazil. We first calibrated and validated modelled carbon and water cycling against field flux and biometric data. Second, we simulated sugarcane growth under the historical climate (1980-2018), and six future climate projections (2015-2100). We computed the 'yield-effect' of each climate driver by generating synthetic climate forcings in which the driver time series was alternated to that of the historical median. In Guangxi, median yield and yield lows (i.e. lower decile) were relatively insensitive to forecast climate change. In Sao Paulo, median yield and yield lows decreased under all future climates projections (x over bar = -4% and -12% respectively). At Guangxi, where moisture stress was low, radiation was the principal driver of yield variabi... Mostrar Tudo |
Palavras-Chave: |
Climate sensitivity. |
Thesagro: |
Cana de Açúcar; Clima; Mudança Climática; Produtividade. |
Thesaurus NAL: |
C4 plants; Climate change; Climate models; Crop yield; Sugarcane. |
Categoria do assunto: |
P Recursos Naturais, Ciências Ambientais e da Terra |
Marc: |
LEADER 02999naa a2200325 a 4500 001 2138503 005 2022-03-15 008 2021 bl uuuu u00u1 u #d 024 7 $ahttps://doi.org/10.1111/gcbb.12797$2DOI 100 1 $aFLACK-PRAIN, S. 245 $aThe impact of climate change and climate extremes on sugarcane production.$h[electronic resource] 260 $c2021 520 $aAbstract: Sugarcane production supports the livelihoods of millions of small-scale farmers in developing countries, and the bioenergy needs of millions of consumers. Yet, future sugarcane yields remain uncertain due to differences in climate projections, and because the sensitivity of sugarcane ecophysiology to individual climate drivers (i.e. temperature, precipitation, shortwave radiation, VPD and CO2) and their interactions is largely unresolved. Here we ask: how sensitive is sugarcane yield to future climate change, including climate extremes, and what are its key climate drivers? We combine the Soil-Plant-Atmosphere model with detailed time-series measurements from experimental plots in Guangxi, China, and Sao Paulo State, Brazil. We first calibrated and validated modelled carbon and water cycling against field flux and biometric data. Second, we simulated sugarcane growth under the historical climate (1980-2018), and six future climate projections (2015-2100). We computed the 'yield-effect' of each climate driver by generating synthetic climate forcings in which the driver time series was alternated to that of the historical median. In Guangxi, median yield and yield lows (i.e. lower decile) were relatively insensitive to forecast climate change. In Sao Paulo, median yield and yield lows decreased under all future climates projections (x over bar = -4% and -12% respectively). At Guangxi, where moisture stress was low, radiation was the principal driver of yield variability (yield-effect x over bar = -1.2%). Conversely, high moisture stress at Sao Paulo raised yield sensitivity to temperature (yield-effect x over bar = -7.9%). In contrast, a number of other modelling studies report a positive effect of increased temperatures on sugarcane yield. We ascribe the disparity between model predictions to the representation of key phenological processes, including the link between leaf ageing and thermal time, and the role of ageing in driving leaf senescence. We highlight climate sensitivity of phenological processes as a key focus for future research efforts. 650 $aC4 plants 650 $aClimate change 650 $aClimate models 650 $aCrop yield 650 $aSugarcane 650 $aCana de Açúcar 650 $aClima 650 $aMudança Climática 650 $aProdutividade 653 $aClimate sensitivity 700 1 $aSHI, L. 700 1 $aZHU, P. 700 1 $aROCHA, H. R. da 700 1 $aCABRAL, O. M. R. 700 1 $aHU, S. 700 1 $aWILLIAMS, M. 773 $tGlobal Change Biology Bioenergy$gv. 13. n. 3, p. 408-424, 2021.
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