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Registro Completo |
Biblioteca(s): |
Embrapa Pecuária Sudeste. |
Data corrente: |
20/11/2015 |
Data da última atualização: |
20/03/2023 |
Tipo da produção científica: |
Artigo em Periódico Indexado |
Autoria: |
PALHARES, J. C. P.; PEZZOPANE, J. R. M. |
Afiliação: |
JULIO CESAR PASCALE PALHARES, CPPSE; JOSE RICARDO MACEDO PEZZOPANE, CPPSE. |
Título: |
Water footprint accounting and scarcity indicators of conventional and organic dairy production systems. |
Ano de publicação: |
2015 |
Fonte/Imprenta: |
Journal of Cleaner Production, v. 93, p. 299-307, apr. 2015. |
DOI: |
10.1016/j.jclepro.2015.01.035 |
Idioma: |
Inglês |
Conteúdo: |
The amount of water that is used in animal agriculture influences society's view of its environmental sustainability. Estimates of how much water is consumed to produce one kg of milk remain scarce. Such information needs to be given to society and water resource managers. The aim of this study were to assess the water footprint of both a conventional and an organic dairy production system and identified the components and processes that have the greatest water use in terms of green, blue, gray water, and virtual water. Additionally, it analyzed the impact of element on gray water footprint, and utilized indicators to evaluate the water scarcity. These were done following a water footprint method compliant with Water Footprint Network. Green water footprint was the most significant contributor to the total footprint values for both systems. This situation can be understood as an opportunity to improve the agriculture water use efficiency and promote the integration between agriculture and livestock. Virtual water represents from 39% to 57% of footprint value for the conventional and from 32% to 59% for the organic. The consumption of water for irrigation accounted for the greatest percentage of blue water, 95% for conventional and 96% for organic. The element used to calculate gray water footprint has a significant impact on its values. Footprints calculated having phosphorus as element were 1.5 and 1.9 times higher for conventional and organic, respectively. Both conventional and organic farms showed an equal green water scarcity index (1.1) and despite the two farms are located in places with high rainfall, they suffered green water scarcity The blue water scarcity index was 0.11 for conventional and 0.13 for organic. Study concluded that a product with a lower water footprint could be more damaging to the environment than one with a higher water footprint depending on water availability. The water footprint approach evidenced that nutritional management is crucial to improve water use. Results cannot support the consequences in changing the conventional or the organic production system regarding the use of water. The more efficient water use depend on productions factors and water availabilities that are specific to each system. MenosThe amount of water that is used in animal agriculture influences society's view of its environmental sustainability. Estimates of how much water is consumed to produce one kg of milk remain scarce. Such information needs to be given to society and water resource managers. The aim of this study were to assess the water footprint of both a conventional and an organic dairy production system and identified the components and processes that have the greatest water use in terms of green, blue, gray water, and virtual water. Additionally, it analyzed the impact of element on gray water footprint, and utilized indicators to evaluate the water scarcity. These were done following a water footprint method compliant with Water Footprint Network. Green water footprint was the most significant contributor to the total footprint values for both systems. This situation can be understood as an opportunity to improve the agriculture water use efficiency and promote the integration between agriculture and livestock. Virtual water represents from 39% to 57% of footprint value for the conventional and from 32% to 59% for the organic. The consumption of water for irrigation accounted for the greatest percentage of blue water, 95% for conventional and 96% for organic. The element used to calculate gray water footprint has a significant impact on its values. Footprints calculated having phosphorus as element were 1.5 and 1.9 times higher for conventional and organic, respectively. Both convention... Mostrar Tudo |
Palavras-Chave: |
Blue; Effluent; Green; Nitrate. |
Thesaurus Nal: |
phosphorus. |
Categoria do assunto: |
-- |
Marc: |
LEADER 02893naa a2200205 a 4500 001 2029146 005 2023-03-20 008 2015 bl uuuu u00u1 u #d 024 7 $a10.1016/j.jclepro.2015.01.035$2DOI 100 1 $aPALHARES, J. C. P. 245 $aWater footprint accounting and scarcity indicators of conventional and organic dairy production systems.$h[electronic resource] 260 $c2015 520 $aThe amount of water that is used in animal agriculture influences society's view of its environmental sustainability. Estimates of how much water is consumed to produce one kg of milk remain scarce. Such information needs to be given to society and water resource managers. The aim of this study were to assess the water footprint of both a conventional and an organic dairy production system and identified the components and processes that have the greatest water use in terms of green, blue, gray water, and virtual water. Additionally, it analyzed the impact of element on gray water footprint, and utilized indicators to evaluate the water scarcity. These were done following a water footprint method compliant with Water Footprint Network. Green water footprint was the most significant contributor to the total footprint values for both systems. This situation can be understood as an opportunity to improve the agriculture water use efficiency and promote the integration between agriculture and livestock. Virtual water represents from 39% to 57% of footprint value for the conventional and from 32% to 59% for the organic. The consumption of water for irrigation accounted for the greatest percentage of blue water, 95% for conventional and 96% for organic. The element used to calculate gray water footprint has a significant impact on its values. Footprints calculated having phosphorus as element were 1.5 and 1.9 times higher for conventional and organic, respectively. Both conventional and organic farms showed an equal green water scarcity index (1.1) and despite the two farms are located in places with high rainfall, they suffered green water scarcity The blue water scarcity index was 0.11 for conventional and 0.13 for organic. Study concluded that a product with a lower water footprint could be more damaging to the environment than one with a higher water footprint depending on water availability. The water footprint approach evidenced that nutritional management is crucial to improve water use. Results cannot support the consequences in changing the conventional or the organic production system regarding the use of water. The more efficient water use depend on productions factors and water availabilities that are specific to each system. 650 $aphosphorus 653 $aBlue 653 $aEffluent 653 $aGreen 653 $aNitrate 700 1 $aPEZZOPANE, J. R. M. 773 $tJournal of Cleaner Production$gv. 93, p. 299-307, apr. 2015.
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| Acesso ao texto completo restrito à biblioteca da Embrapa Amazônia Ocidental. Para informações adicionais entre em contato com cpaa.biblioteca@embrapa.br. |
Registro Completo
Biblioteca(s): |
Embrapa Amazônia Ocidental; Embrapa Florestas. |
Data corrente: |
17/07/2023 |
Data da última atualização: |
17/07/2023 |
Tipo da produção científica: |
Artigo em Periódico Indexado |
Circulação/Nível: |
A - 1 |
Autoria: |
CONRADO, A. C.; DEMETRIO, W. C.; STANTON, D. W. G.; BARTZ, M. L. C.; JAMES, S. W.; SANTOS, A.; SILVA, E. da; FERREIRA, T.; ACIOLI, A. N. S.; FERREIRA, A. C.; MAIA, L. S.; SILVA, T. A. C.; LAVELLE, P.; VELASQUEZ, E.; TAPIA-CORAL, S. C.; MUNIZ, A. W.; SEGALLA, R. F.; DECAËNS, T.; NADOLNY, H. S.; PEÑA-VENEGAS, C.; PASINI, A.; OLIVEIRA JUNIOR, R. C. de; TPI NETWORK; KILLE, P.; BROWN, G. G.; CUNHA, L. |
Afiliação: |
ANA C. CONRADO, UNIVERSIDADE FEDERAL DO PARANÁ; WILIAN C. DEMETRIO, UNIVERSIDADE FEDERAL DO PARANÁ; DAVID W. G. STANTON, CARDIFF UNIVERSITY; MARIE L. C. BARTZ, UNIVERSITY OF COIMBRA; SAMUEL W. JAMES, MAHARISHI INTERNATIONAL UNIVERSITY; ALESSANDRA SANTOS, UNIVERSIDADE FEDERAL DO PARANÁ; ELODIE DA SILVA, Bolsista CNPF; TALITA FERREIRA, UNIVERSIDADE FEDERAL DO PARANÁ; AGNO N. S. ACIOLI, UNIVERSIDADE FEDERAL DO AMAZONAS; ALEXANDRE C. FERREIRA, UNIVERSIDADE FEDERAL DO PARANÁ; LILIANNE S. MAIA, UNIVERSIDADE FEDERAL DO PARANÁ; TELMA A. C. SILVA, INSTITUTO NACIONAL DE PESQUISAS DA AMAZÔNIA; PATRICK LAVELLE, INSTITUT DE RECHERCHE POUR LE DÉVELOPPEMENT; ELENA VELASQUEZ, UNIVERSIDAD NACIONAL DE COLOMBIA; SANDRA C. TAPIA-CORAL, SERVIÇO NACIONAL DE APRENDIZAGEM, SENA REGIONAL AMAZONAS; ALEKSANDER WESTPHAL MUNIZ, CPAA; RODRIGO F. SEGALLA, UNIVERSIDADE FEDERAL DO PARANÁ; THIBAUD DECAËNS, CEFE, UNIV MONTPELLIER; HERLON S. NADOLNY, UNIVERSIDADE FEDERAL DO PARANÁ; CLARA P. PEÑA-VENEGAS, INSTITUTO AMAZÓNICO DE INVESTIGACIONES CIENTÍFICAS SINCHI; AMARILDO PASINI, UNIVERSIDADE ESTADUAL DE LONDRINA; RAIMUNDO COSME DE OLIVEIRA JUNIOR, CPATU; PETER KILLE, CARDIFF UNIVERSITY; GEORGE GARDNER BROWN, CNPF; LUÍS CUNHA, UNIVERSITY OF COIMBRA. |
Título: |
Amazonian earthworm biodiversity is heavily impacted by ancient and recent human disturbance. |
Ano de publicação: |
2023 |
Fonte/Imprenta: |
Science of the Total Environment, v. 895, art. 165087, 2023. |
DOI: |
http://dx.doi.org/10.1016/j.scitotenv.2023.165087 |
Idioma: |
Inglês |
Conteúdo: |
Despite the importance of earthworms for soil formation, more is needed to know about how Pre-Columbian modifications to soils and the landscape. Gaining a deeper understanding is essential for comprehending the historical drivers of earthworm communities and the development of effective conservation strategies in the Amazon rainforest. Human disturbance can significantly impact earthworm diversity, especially in rainforest soils, and in the particular case of the Amazonian rainforest, both recent and ancient anthropic practices may be important. Amazonian Dark Earths (ADEs) are fertile soils found throughout the Amazon Basin, created by sedentary habits and intensification patterns of pre-Colombian societies primarily developed in the second part of the Holocene period. We have sampled earthworm com-munities in three Brazilian Amazonian (ADEs) and adjacent reference soils (REF) under old and young forests and monocultures. To better assess taxonomic richness, we used morphology and the barcode region of the COI gene to identify juveniles and cocoons and delimit Molecular Operational Taxonomic Units (MOTUs). Here we suggest using Integrated Operational Taxonomical units (IOTUs) which combine both morphological and molecular data and provide a more comprehensive assessment of diversity, while MOTUs only rely on molecular data. A total of 970 individuals were collected, resulting in 51 taxonomic units (IOTUs, MOTUs, and morphospecies combined). From this total, 24 taxonomic units were unique to REF soils, 17 to ADEs, and ten were shared between both soils. The highest richness was found in old forest sites for ADEs (12 taxonomic units) and REFs (21 taxonomic units). The beta-diversity calculations reveal a high species turnover between ADEs and REF soils, providing evidence that ADEs and REFs possess distinct soil biota. Furthermore, results suggest that ADE sites, formed by Pre-Columbian human activities, conserve a high number of native species in the landscape and maintain a high abundance, despite their long-term nature. MenosDespite the importance of earthworms for soil formation, more is needed to know about how Pre-Columbian modifications to soils and the landscape. Gaining a deeper understanding is essential for comprehending the historical drivers of earthworm communities and the development of effective conservation strategies in the Amazon rainforest. Human disturbance can significantly impact earthworm diversity, especially in rainforest soils, and in the particular case of the Amazonian rainforest, both recent and ancient anthropic practices may be important. Amazonian Dark Earths (ADEs) are fertile soils found throughout the Amazon Basin, created by sedentary habits and intensification patterns of pre-Colombian societies primarily developed in the second part of the Holocene period. We have sampled earthworm com-munities in three Brazilian Amazonian (ADEs) and adjacent reference soils (REF) under old and young forests and monocultures. To better assess taxonomic richness, we used morphology and the barcode region of the COI gene to identify juveniles and cocoons and delimit Molecular Operational Taxonomic Units (MOTUs). Here we suggest using Integrated Operational Taxonomical units (IOTUs) which combine both morphological and molecular data and provide a more comprehensive assessment of diversity, while MOTUs only rely on molecular data. A total of 970 individuals were collected, resulting in 51 taxonomic units (IOTUs, MOTUs, and morphospecies combined). From this total, 24 taxonomic un... Mostrar Tudo |
Palavras-Chave: |
Amazonian Dark Earths; Crassiclitellata; Land-use change. |
Thesagro: |
Agricultura; Minhoca; Uso da Terra. |
Thesaurus NAL: |
Agriculture; DNA barcoding; Terra preta. |
Categoria do assunto: |
-- P Recursos Naturais, Ciências Ambientais e da Terra |
Marc: |
LEADER 03562naa a2200541 a 4500 001 2154962 005 2023-07-17 008 2023 bl uuuu u00u1 u #d 024 7 $ahttp://dx.doi.org/10.1016/j.scitotenv.2023.165087$2DOI 100 1 $aCONRADO, A. C. 245 $aAmazonian earthworm biodiversity is heavily impacted by ancient and recent human disturbance.$h[electronic resource] 260 $c2023 520 $aDespite the importance of earthworms for soil formation, more is needed to know about how Pre-Columbian modifications to soils and the landscape. Gaining a deeper understanding is essential for comprehending the historical drivers of earthworm communities and the development of effective conservation strategies in the Amazon rainforest. Human disturbance can significantly impact earthworm diversity, especially in rainforest soils, and in the particular case of the Amazonian rainforest, both recent and ancient anthropic practices may be important. Amazonian Dark Earths (ADEs) are fertile soils found throughout the Amazon Basin, created by sedentary habits and intensification patterns of pre-Colombian societies primarily developed in the second part of the Holocene period. We have sampled earthworm com-munities in three Brazilian Amazonian (ADEs) and adjacent reference soils (REF) under old and young forests and monocultures. To better assess taxonomic richness, we used morphology and the barcode region of the COI gene to identify juveniles and cocoons and delimit Molecular Operational Taxonomic Units (MOTUs). Here we suggest using Integrated Operational Taxonomical units (IOTUs) which combine both morphological and molecular data and provide a more comprehensive assessment of diversity, while MOTUs only rely on molecular data. A total of 970 individuals were collected, resulting in 51 taxonomic units (IOTUs, MOTUs, and morphospecies combined). From this total, 24 taxonomic units were unique to REF soils, 17 to ADEs, and ten were shared between both soils. The highest richness was found in old forest sites for ADEs (12 taxonomic units) and REFs (21 taxonomic units). The beta-diversity calculations reveal a high species turnover between ADEs and REF soils, providing evidence that ADEs and REFs possess distinct soil biota. Furthermore, results suggest that ADE sites, formed by Pre-Columbian human activities, conserve a high number of native species in the landscape and maintain a high abundance, despite their long-term nature. 650 $aAgriculture 650 $aDNA barcoding 650 $aTerra preta 650 $aAgricultura 650 $aMinhoca 650 $aUso da Terra 653 $aAmazonian Dark Earths 653 $aCrassiclitellata 653 $aLand-use change 700 1 $aDEMETRIO, W. C. 700 1 $aSTANTON, D. W. G. 700 1 $aBARTZ, M. L. C. 700 1 $aJAMES, S. W. 700 1 $aSANTOS, A. 700 1 $aSILVA, E. da 700 1 $aFERREIRA, T. 700 1 $aACIOLI, A. N. S. 700 1 $aFERREIRA, A. C. 700 1 $aMAIA, L. S. 700 1 $aSILVA, T. A. C. 700 1 $aLAVELLE, P. 700 1 $aVELASQUEZ, E. 700 1 $aTAPIA-CORAL, S. C. 700 1 $aMUNIZ, A. W. 700 1 $aSEGALLA, R. F. 700 1 $aDECAËNS, T. 700 1 $aNADOLNY, H. S. 700 1 $aPEÑA-VENEGAS, C. 700 1 $aPASINI, A. 700 1 $aOLIVEIRA JUNIOR, R. C. de 700 1 $aTPI NETWORK 700 1 $aKILLE, P. 700 1 $aBROWN, G. G. 700 1 $aCUNHA, L. 773 $tScience of the Total Environment$gv. 895, art. 165087, 2023.
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