Mapping patterns of agricultural land-use intensity across Europe

Estel, Stephan

19 August 2016

Die weltweite Bevölkerungszunahme, sich ändernde Ernährungsgewohnheiten, und die Nachfrage nach Bioenergie erfordern eine Erhöhung der landwirtschaftlichen Produktion. Die Intensivierung bestehender landwirtschaftlicher Flächen ist hierbei eine mögliche Option. Allerdings verstehen wir nur wenig von den räumlichen Mustern der landwirtschaftlichen Nutzungsintensität, da adäquate Datensätze fehlen. Europa ist eine beispielhafte Region, in der eine Intensivierung als auch ein Rückgang der Landnutzung stattfindet. Ziel dieser Dissertation war es Methoden zu entwickeln, die MODIS NDVI Zeitreihen und statistische Daten kombinieren und eine europaweite Kartierung der landwirtschaftlichen Nutzungsintensität ermöglichen. Für eine Einschätzung der landwirtschaftlichen Nutzungsintensität wurden eine Reihe von Intensitätsindikatoren entwickelt und kartiert. Die resultierenden Karten zeigen eine hohe Landnutzungsintensität in West- und Zentraleuropa und dem Mittelmeerraum, gekennzeichnet durch Mehrfachernten und langen Anbauzeiten. Gebiete mit niedriger Intensität lagen in Osteuropa, in Gebirgsregionen sowie in der Extremadura in Spanien, wo Brachland und die Aufgabe von Agrarflächen häufig sind. Die Aufgabe von Agrarflächen ist ein aktueller Prozess der Landnutzungsveränderung in Osteuropa, während die gleichzeitige Rekultivierung ehemaliger Agrarflächen ebenfalls umfassend ist. Diese räumlichen Muster lassen sich mit unterschiedlichen Agrarumweltbedingungen begründen aber auch mit sozioökonomischen Veränderungen wie die Restrukturierung des osteuropäischen Agrarsektors nach 1989 oder die Marginalisierung landwirtschaftlicher Flächen insbesondere in Gebirgsregionen. Die entstandenen Karten belegen das Potential von MODIS NDVI Zeitreihen, komplexe Phänomene landwirtschaftlicher Nutzungsintensität zu erfassen. Diese könnten genutzt werden um Umweltfolgen der landwirtschaftlichen Produktion zu bewerten oder Zielregionen für eine nachhaltige Intensivierung zu identifizieren. / Global population growth, changing diets, and the demand of bioenergy require an increase in agricultural production. Intensifying agricultural production is one pathway to meet increasing demands. However, our understanding of spatial patterns of agricultural land use remains weak since adequate data sets are lacking. Europe is as a prime example for a region that is undergoing both, intensification as well as decreasing agricultural land use. The goal of this doctoral thesis was to develop methodologies that combine MODIS NDVI time series and agricultural statistics to map spatial patterns of land-use intensity across Europe. To assess land-use intensity, a wide range of intensity indicators were mapped. The resulting maps revealed high-intensity areas in Western and Central Europe and the Mediterranean region, characterized by multi-harvests and long crop duration. Low-intensity areas are mostly located in Eastern Europe, in mountain regions and the Extremadura in Spain, where fallow and abandonment land are widespread. Agricultural abandonment is an ongoing land-use change process in Eastern Europe. At the same time, recultivation of formerly abandoned land is widespread as well. These spatial patterns are the result of agro-environmental conditions but also of changes in socio-economic conditions such as the restructuring of the agricultural sector in eastern European countries after 1989, or the marginalization of farmland especially in mountain regions. The resulting maps show the potential of MODIS time series to assess the complex phenomenon of land-use intensity. They may form a basis to assess the environmental outcomes of agricultural production and to identify target regions for sustainable intensification.

Europa

Landnutzungsintensität

MODIS Zeitreihen

Farmlandaufgabe

Farmlandrekultivierung

Landnutzungsänderung

Farmland abandonment

Europe

MODIS time series

Farmland recultivation

Land-use change

Land-management intensity

550 Geowissenschaften

31 Geowissenschaften

RC 10633

ddc:550

Mudanças nos estoques de carbono e nitrogênio do solo em função da conversão do uso da terra no Pará / Changes on soil carbon and nitrogen stocks due to the land use change in Pará State, Brazil

Durigan, Mariana Regina

23 April 2013

A atividade de mudança do uso da terra na Amazônia vem sendo apontada como principal fonte de CO2 para a atmosfera em função das emissões de C e N provenientes do solo. A prática de manejo adotada pode influenciar significativamente nos estoques de C e N do solo funcionando como dreno ou fonte de C e N para a atmosfera. Além disso, podem ser alterados: a fertilidade e a densidade do solo bem como as frações e a origem da MOS. Com o objetivo de avaliar o impacto das mudanças de uso da terra na região leste da Amazônia foram coletadas amostras de terra nos principais usos da terra na região de Santarém-PA, em três profundidades: 0-10, 10-20 e 20-30 cm. Através das amostras foi realizada a caracterização físico-química das áreas e foram determinados os teores de C e N do solo e os isótopos ? 13C e ? 15N com a finalidade de quantificar os estoques de C e N do solo e avaliar a dinâmica e origem da MOS. Para um subconjunto de amostras foi realizado o fracionamento físico da MOS e a determinação do C da biomassa microbiana para compreender como a mudança de uso da terra interferiu nessas frações. Somado a essas determinações foi realizada a estimativa dos fatores de emissão com base na metodologia descrita pelo IPCC. Através da caracterização físicoquímica as áreas de estudo são caracterizadas por solos argilosos a muito argilosos. Os maiores valores de pH, macronutrientes, CTC, SB e V% foram observados nas áreas de agricultura (AGR) sugerindo que a utilização de práticas como adubação e calagem, são capazes de alterar os padrões de fertilidade do solo na Amazônia, aumentando seus índices de fertilidade. Para os estoques de C e N pode-se dizer que a mudança de uso da terra na região estudada está contribuindo para as perdas de C e N do solo, principalmente quando a conversão é realizada para áreas de agricultura (AGR) e pastagem (PA) sendo que os estoques de C observados na camada de 0-30 cm nessas áreas foram 49,21 Mg C ha-1 (PA) e 48,60 Mg C ha-1 (AGR). O maior valor de ? 13C foi encontrado nas áreas de pastagens, -25,08?, sugerindo que para as áreas de PA existe diluição isotópica e que parte do C do solo ainda é remanescente da floresta. As frações da MOS apresentaram alterações na quantidade de C e na proporção das frações leve e oclusa, principalmente nos usos AGR e PA. A fração lábil da MOS (C da biomassa microbiana) também apresentou grande diferença entre os usos FLO e AGR (526,21 e 296,78 ?g g-1de solo seco), indicando que a AGR foi o uso que mais alterou os estoques de C e N do solo e também as frações da MOS. Os fatores de emissão calculados confirmam todos os resultados observados em relação a conversão de FLO para AGR, sendo que para esse uso o fator de emissão foi de 0,93 ± 0,033, sendo então o uso que mais emitiu C. Com base nos resultados conclui-se que a introdução de áreas agrícolas na região de Santarém, é a principal causa de perda de C e N do solo e consequentemente é o uso que mais contribui com as emissões de gases do efeito estufa. / The land use change in the Brazilian Amazon has been identified as the main source of CO2 to the atmosphere due to emissions of soil carbon and nitrogenl. The management practice adopted can strongly influence the soil C and N stocks and may works like a sink or source of C and N to the atmosphere. Furthermore, can be changed: the soil fertility and bulk density as well as the SOM fractions and C source of the SOM. With the objective of evaluate the impact of the land use change in eastern Amazonia soil samples were collected in the main land uses in Santarém region, Para State of Brazil, at three depths: 0-10, 10-20 and 20-30 cm. Through the samples was performed the physicochemical characterization of the areas and were determined the soil C and N contents as well the isotopes ? 13C and ? 15N in order to quantify the soil C and N stocks and understand the SOM dynamics and evaluate the SOM origin. For a subset of samples were performed the physical fractionation of SOM and the determination of microbial biomass C to understand how the land use change may interfere in these fractions. Added to these determinations were estimated the emission factors based on the methodology described by the IPCC. Through the physicochemical characterization study areas can be characterized as a clayey loamy soils. The highest values of pH, macronutrients, CEC , sum of bases and base saturation were observed in croplands (CP), suggesting that the use of practices such as fertilization and liming are able to change the soil fertility patterns in the Amazon, increasing their fertility. For C and N stocks can be said that the land use change in the study area is contributing to the loss of soil C and N, especially when the conversion is done for croplands (CP) and grasslands (GS) areas and the value observed for soil C stocks in the 0-30 cm layer in these areas were 49.21 Mg C ha-1 (GS) and 48.60 Mg C ha-1 (CP). The highest ? 13C value was found in GS, -25.08 ?, suggesting that for these areas is occurring an isotope dilution and that part of the soil C is still remaining from forest. The SOM fractions showed changes in the amount of C and in the proportion of light and occluded fractions, especially in the uses CP and GS. The labile SOM fractions (microbial biomass) also showed a large difference between the UF and CP uses (526.21 and 296.78 mg g-1 of dry soil), indicating that CP affects the soil C and N stocks and also the SOM fractions. The emission factors calculated confirm all results observed for the conversion of UF for CP, and for this use the emission factor was 0.93 ± 0.033, and then this was the use that emitted more C. Based on the results we conclude that the introduction of croplands in Santarem region is the main cause of soil C and N loss and consequently contributes more to the greenhouse gases emission.

Amazon

Amazônia

Biomassa microbiana

Carbon

Carbono

Emission factors

Estoques de C e N do solo

Fatores de emissão

Fracionamento físico da MOS

Isotopes

Isótopos

Land use change

Microbial biomass

Mudança no uso da terra

Nitrogen

Nitrogênio

Soil C and N stocks

SOM physical fractionation

The species and functional composition of bird communities in regenerating tropical forests

Mayhew, Rebekah Jane Watts

January 2017

The widespread threat of species extinctions caused by the destruction and degradation of tropical primary forest (PF) could potentially be mitigated by the expansion of regenerating secondary forest (SF). However, the conservation value of SF remains controversial, and is dependent on many site- and landscape-scale factors, such as habitat age and isolation. The aim of this thesis was to assess the role that SF can play in conserving forest bird communities in central Panama. We study a chronosequence of SF aged 20 – 120-years-old, with sites either isolated from or connected to extensive PF. Our results suggest that SF supports high levels of avian species diversity, and similar community composition to PF. Whilst forest age plays a small role in determining compositional similarity to PF, connectivity to extensive PF was the main determinant of community composition. However, despite high species richness and complex community composition, some specialist PF bird species were consistently absent from SF, and isolated PF. The functional diversity of bird communities did not vary substantially across the forest age and isolation gradient, although we did find some inter-guild differences; with distinct responses in communities of avian insectivores and frugivores. Isolation caused shifts in the trophic traits of insectivores, but resulted in alterations in the dispersal traits of frugivores. The response of bird and tree community composition to forest age and isolation was similar, although isolation had a stronger impact on bird communities. Bird diversity and composition tracked changes in forest structure over succession. When examining the role of birds in seed-dispersal networks, we found bird gape width was the key predictor of seed size consumed. Large-gaped birds consume a wider variety of seed-sizes than small-gaped birds, and small-seeded trees attract a greater number of bird species than large-seeded trees. These results imply high levels of redundancy among small-gaped avian frugivores and small-seeded plant species, but low levels of redundancy among large-seeded plant species and their avian dispersers. This suggests that large-seeded plants may be most at risk of dispersal failure following any change in avian frugivore assemblages. Together, these results suggest that SF can play a key role in sustaining most tropical biodiversity, and in maintaining ecosystem services. Our findings emphasise the importance of integrating SF into conservation strategies to support and buffer tropical PF habitats.

C and N stocks in Brazilian woodland savanna (Cerradão) under different land uses, and their dynamicas in the soil / Estoques de C e N em Cerradão sob diferentes usos e suas dinâmicas no solo

Brito, Gisele Silveira de

18 December 2018

The replacement of the native vegetation by pastures and silviculture can result in clear changes on the carbon and nitrogen pools, stocks and dynamics. We aimed to assess the impact of the woodland cerrado (cerradão) conversion into pastures and Eucalyptus plantations on the soil organic carbon (SOC) labile pools and dynamics, on the concentrations of N variables and on the potential for nitrogen mineralization (PMN) in the first 200 cm of the soil profile. We also assessed the seasonal variation on the overall variability in soil C and N pools and dynamics. Finally, we investigated the C and N stocks belowground (up to 50 cm depth) and C stocks aboveground. We had three sampling sites in a region originally covered by cerradão physiognomy. Each sampling included a control area (Cerrado) and two land uses (Pasture, Eucalyptus). Soil samples were taken at 0-10, 10-30, 30-50, 50-100 and 100-200 cm depths during the dry and wet climate seasons, from which we used the first three depths for stocks calculation. We also collected litter and herbs+shrubs biomass, and measured the tree biomass for C stocks calculation. Our results showed ~50% reduction of the microbial biomass (MBC) and MBC:SOC for pastures and Eucalyptus plantations, indicating lower SOC stability. Reduction in the dissolved organic carbon (DOC) and DOC:SOC, and increment on the metabolic quotient were also registered for both land uses along the soil profile up to 30 or 50 cm depth. Higher SBR and qCO2 rates are associated to a microbial community under stress. Land use effect on SOC labile pools and dynamics was more marked in the dry season. The inorganic forms of nitrogen (NH4-N and NO3-N) and PMN were significantly affected by land use conversion, with decreases in both land uses compared to native Cerrado, with lower values found in Eucalyptus. Urease activity also decreased with land conversion. The N variables all decreased with depth from 10 to 50 cm depth. Land conversion also resulted in C and N stock losses, and in redistribution among the system compartments. Pastures showed 53% less overall C stock, and Eucalyptus plantations had 20% more. Carbon was mostly stored belowground in pastures, and aboveground in Eucalyptus, as the native Cerrado showed a balanced distribution. Aboveground, C was 94% reduced in pastures compared to Cerrado, and 80% increased in Eucalyptus plantations; belowground, pastures had 19% and 25% reductions in the overall C and N stocks respectively, with significant decreases for the stocks of arboreal C, MBC, coarse root C and N, NO3-N and PMN. Eucalyptus plantations had 23% decrease in C and 19% in N stocks, with significant reductions in the stocks of herbs+shrubs C, MBC, fine and coarse root C, fine root N, NH4-N and PMN. Both land uses had similar overall losses of C and N belowground, which were evident until 50 cm depth, but higher at the 10-30 cm layer. Our results show negative impacts on carbon and nitrogen pools, cycling processes and stocks due to Cerrado conversion to pastures and Eucalyptus plantations / A substituição da vegetação nativa por pastagem e silvicultura pode resultar em mudanças nas concentrações, estoques e dinâmica do carbono e nitrogênio. O objetivo do trabalho foi analisar o impacto da conversão de cerradão em pastagens de braquiária e plantações de eucalipto na dinâmica e na concentração de variáveis da fração lábil do carbono orgânico do solo (SOC), nas concentrações das variáveis de nitrogênio e no seu potencial de mineralização (PMN), para os primeiros 200 cm de profundidade do solo. Foi ainda avaliada a variação sazonal na variabilidade das concentrações e dinâmicas de C e N no solo. Além disso, investigamos os estoques de C e N abaixo do solo (até 50 cm de profundidade) e os estoques de C acima do solo. Nossas amostragens foram realizadas em três áreas de pesquisa, numa região originalmente coberta por cerradão. Cada área de pesquisa era constituída por um sítio controle (Cerrado) e dois usos das terras (pastagem, eucalipto). Amostras de solo foram coletadas nas profundidades de 0-10, 10-30, 30-50, 50-100 e 100-200 cm durante as estações seca e chuvosa, para as análises das frações de C e N; para o cálculo dos estoques de C e N, foram utilizadas somente as três primeiras profundidades. Também coletamos serapilheira e biomassa de herbáceas + arbustos, assim como tiramos medidas das árvores para o cálculo do estoque de C acima do solo. Nossos resultados mostraram uma redução de aproximadamente 50% da biomassa microbiana (MBC) e da taxa MBC:SOC para pastagens e plantios de eucalipto, indicando menor estabilidade do carbono orgânico do solo. Também foram registrados decréscimos para o carbono orgânico dissolvido (DOC) e para as taxas DOC:SOC, além de aumentos para o quociente metabólico em ambos os usos, ao longo do perfil do solo até 30 ou 50 cm de profundidade. Taxas mais altas de respiração edáfica e do quociente metabólico estão associadas a uma comunidade microbiana sob estresse. O efeito do uso das terras nas concentrações e na dinâmica das variáveis lábeis do C orgânico do solo foi mais acentuado na estação seca. As formas inorgânicas de nitrogênio (NH4-N e NO3-N) e PMN foram significativamente afetados pela conversão do uso da terra, com decréscimos em ambos os usos em comparação ao Cerrado nativo, sendo menores os valores encontrados no Eucalipto. A atividade da urese também decresceu com a mudança de uso. Todas as variáveis de N diminuíram com a profundidade de 10 a 50 cm. A conversão de uso também resultou em perdas nos estoques de C e N e em sua redistribuição entre os compartimentos acima e abaixo do solo. O estoque total de C em pastagens reduziu em 53% e nas plantações de eucalipto ocorreu aumento de 20%. O carbono foi armazenado principalmente abaixo do solo em pastagens e acima do solo nos plantios de eucaliptos, enquanto que o Cerrado nativo apresentou uma distribuição equilibrada entre esses dois grandes compartimentos. Na pastagem, foi registrada uma redução de 94% no estoque da biomassa aérea, em comparação com o Cerrado, enquanto que as plantações de eucalipto apresentaram um aumento de 80%; abaixo do solo, as pastagens tiveram reduções de 19% e 25% nos estoques totais de C e N, respectivamente, com decréscimos significativos para o estoque C de árvores, de MBC, de C e N de raizes grossas, de NO3-N e de PMN. As plantações de eucalipto tiveram redução de 23% para o estoque total de C abaixo do solo e de 19% para o estoque de N (abaixo do solo), com reduções significativas para estoque C da biomassa de ervas + arbustos, de MBC, de C de raízes finas e grossas, bem como para os estoque de N de raízes finas, de NH4-N e de PMN. Ambos os usos da terra tiveram perdas totais semelhantes para os estoques de C e N abaixo do solo, que ficaram evidentes até 50 cm de profundidade, porém, mais significativos na camada de 10-30 cm. Nossos resultados demonstraram impactos negativos da conversão do cerrado em pastagens e plantações de eucalipto para as concentrações de carbono e nitrogênio, assim como em seus processos de ciclagem e estoques

Carbon cycling

Carbon stock

Cerrado

Cerrado

Ciclo do carbono

Ciclo do nitrogênio

Estoque de carbono

Estoque de nitrogênio

Eucalyptus plantation

Land use change

Mudança do uso da terra

Nitrogen cycling

Nitrogen stock

Pastagem de Urochloa

Silvicultura de eucalipto

Urochloa pasture

Soil microbiota related to carbon, nitrogen and greenhouse gas cycles across different land uses in Southwestern Amazonia / Microbiota do solo relacionada aos ciclos do carbono, nitrogênio e gases de efeito estufa em diferentes usos da terra no Sudoeste da Amazônia

Daniel Renato Lammel

16 December 2011

Sustainability is one of the biggest goals of humankind in the new millennium. An increasing global demand on agricultural products stimulates agricultural expansion in Brazil, especially in the Southwestern Amazon, namely in the Cerrado and Amazon biomes. A better understanding of biogeochemical cycles and their influence on natural and agricultural systems is key to achieve environmental sustainability and improve agricultural efficiency. These biogeochemical cycles are driven by microbes, and the aim of this thesis was to correlate microbial functional group abundances with differences in carbon, nitrogen, and greenhouse gas cycles in response to land use changes in Southwestern Amazon soils. This work was performed at the University of São Paulo, Brazil, and at the University of Massachusetts Amherst, USA, while the candidate was enrolled in Ph.D. programs at both universities. The thesis is composed of five studies. The first study shows that land use change from Cerrado and forest to agriculture (soybean, Glycine max (L. Merrill), in succession with other crops) or pasture (Brachiaria brizantha (Hochst. ex A. Rich.) did not reduce soil microbial diversity but changed microbial structure. The second study, a physicochemical background for this land use conversion, describes the alteration of C and N stocks, soil chemical parameters, and microbiological parameters such as biomass, biological C stocks, and changes in the abundance of prokaryotes and fungi. In the third and fourth studies microcosm experiments depict how the agricultural change to soybean and Brachiaria alter the original microbial structure found in forest or cerrado. These studies focused on abundances of key biogeochemical genes (amoA, nirK, nirS, norB, nosZ, mcrA, and pmoA) and correlated gene copy abundances with C, N, and GHG measurements. In the fifth study, in situ soil surveys and GHG samplings were used to characterize the changes from forest to pasture (B. brizantha, 25 years) or soybean crop system (for 2 years or 25 years in succession). We found correlations between genes and processes, indicating that gene abundances provide important microbial information for the understanding of the targeted biogeochemical cycles. Land use, rather than plant species, promotes alterations in microbial gene abundances and processes. During the survey period, forest exhibited higher microbial activity, resulting in higher nitrate availability and N2O emissions. These processes were correlated with higher abundances of process related genes. Nitrate and N2O emissions were lower in agricultural and pasture soils. CO2 emission was higher in the two-year-old soybean plot. The forest and two-year-old soybean plots acted as a sink for CH4, while the pasture plots represented a source of it. The results validated the use of gene abundance determination as a valuable tool to better understand C, N, and GHG processes. The genes nirK, nosZ, and 16S rRNA presented the best correlations with the processes. A larger temporal and spatial analysis is needed to infer statements on the processes dynamics due to land use change. For the first time gene abundance measurements were used to integrate the C, N and GHG cycles, giving insights into land use changes in Southwestern Amazon / Sustentabilidade é um dos maiores objetivos da humanidade no novo milênio. Uma demanda crescente por produtos agrícolas tem estimulado a expansão agrícola no Brasil, especialmente no Sudoeste da Amazônia, nos biomas Cerrado e Amazônia. Um melhor entendimento dos ciclos biogeoquímicos e suas influências em sistemas naturais e agrícolas é chave para se alcançar sustentabilidade ambiental e aumentar eficiência agrícola. Esses ciclos biogeoquímicos são guiados por microrganismos, e o objetivo dessa tese foi correlacionar abundância de grupos funcionais de microrganismos com carbono, nitrogênio e gases de efeito estufa (GEE) em resposta a mudança do uso da terra em solos do sudoeste da Amazônia. Esse trabalho foi realizado na Universidade de São Paulo e na Universidade de Massachusetts Amherst enquanto o doutorando esteve matriculado nas duas universidades. A tese é composta de cinco estudos. O primeiro estudo mostra que a mudança no uso da terra de Cerrado e floresta para agricultura (soja, Glycine max (L. Merrill), em sucessão com outros cultivos) ou pastagem (Brachiaria brizantha (Hochst. ex A. Rich.) não reduz diversidade microbiana, mas muda sua estrutura. O segundo estudo descreve as alterações nos estoques de C, N, parâmetros químicos e microbiológicos da conversão de Cerrado para agricultura e pastagem. No terceiro e no quarto estudos, microcosmos foram usados para avaliar a influência de soja e braquiária na microbiota dos solos. Genes chaves dos processos biogeoquímicos (amoA, nirK, nirS, norB, nosZ, mcrA, e pmoA) foram quantificados e correlacionados com C, N e GEE. No quinto estudo, coletas in situ de solo e gases foram usadss para caracterizar a mudança do uso da terra de floresta para pastagem (braquiária, 25 anos) e para agricultura (soja, segundo ano, e soja, 25 anos, em sucessão com outras culturas). Correlações entre genes e processos foram encontradas, indicando que abundância gênica fornece importantes informações para o entendimento dos ciclos biogeoquímicos. Mudança no uso da terra como um todo, mais do que a mudança de vegetação, promove as alterações na abundância gênica e processos do solo. Durante o período de coleta, floresta exibiu maior atividade microbiana, resultando em maior disponibilidade de nitrato e emissão de N2O. Esses processos correlacionam com maior abundância dos genes relacionados aos processos. Quantidades de nitrato e N2O foram menores em agricultura e pastagem. As emissões de CO2 foram maiores na área de soja de segundo ano. Os solos de floresta e soja de segundo ano se mostraram como drenos de metano, enquanto que a pastagem foi uma fonte de emissão. Os resultados validam o uso de abundância gênica como uma técnica valiosa para um melhor entendimento dos ciclos do C, N e GEE. Os genes nirK, nosZ, e 16S rRNA apresentaram as melhores correlações com os processos. Uma análise temporal e espacial mais abrangente é necessária para generalizações sobre a dinâmica dos processos na região estudada. Pela primeira vez abundância gênica foi usada para integrar os ciclos do C, N e GEE, colaborando para um melhor entendimento dos processos relacionados à mudança no uso da terra no sudoeste da Amazônia

Abundância gênica

Amazônia

Cerrado

Ciclos biogeoquímicos

Gases de efeito estufa

Mudança no uso da terra

Pastagem

qPCR

Soja

Agricultural land use change

Amazonia

Biogeochemical cycles

Cerrado Gene abundance

Greenhouse gas

Pasture

qPCR

Soybean

Atributos químicos, microbiológicos e emissões de CO2, CH4 e N2O do solo em experimento de corte e queima controlada na Amazônia Ocidental / Chemical and microbiological attributes and CO2, CH4 and N2O emissions of the soil in controlled slash and burn in the western Amazon

Elizio Ferreira Frade Junior

19 October 2017

Nas últimas décadas as mudanças climáticas foram evidenciadas pelo aumento da temperatura global, diminuição dos estoques de carbono terrestres, associados ao aumento nas emissões de gases de efeito estufa (GEE). A floresta Amazônica é o maior bioma tropical do mundo e desenvolve serviços ambientais estratégicos no planeta. Entretanto, há mais de duas décadas que o desmatamento na Amazônia impulsiona as emissões globais de GEE, diminuindo o armazenamento de carbono do solo com alterações na dinâmica nas populações microbianas e nos ciclos biogeoquimicos pela mudança de uso da terra. O objetivo desse estudo foi avaliar as alterações temporais dos atributos químicos do solo, quantificar as emissões de CO2, CH4 e N2O e verificar as alterações na estrutura bacteriana do solo após o corte e queima de vegetação nativa na Amazônia. O estudo foi desenvolvido em área de vegetação nativa no norte do estado de Rondônia, região sul da Amazônia no Brasil. A área de estudo consistiu-se de quatro hectares, onde foi realizado o corte e queima em 2,25 hectares. Foram realizadas amostragens para avaliação da fertilidade do solo e estoques de carbono (C) e nitrogenio (N) nas profundidades de 0-5, 5-10, 10-15, 15-20, 20-30, 30-40, 40-50, 50-60, 60-80 e 80-100 cm. As coletas foram realizadas em vegetação nativa e aos 2, 30, 60, 90, 120, 240 e 365 dias após corte e queima. Foram determinados os atributos pH, Al, H+Al, Ca, Mg, K, P, C, N e calculados os valores de soma de bases, CTC, V % e m %. As coletas para quantificar as emissões dos GEE foram realizadas simultaneamente na área de vegetação nativa e no hectare central da área de corte e queima aos 19, 31, 48, 61 e 81 dias após corte e 2 , 4, 6, 8, 15, 31, 45, 61, 88, 122, 153, 180, 240 e 350 dias após queima, com amostragens aos 0, 20, 40 e 60 minutos. Os atributos microbiológicos do solo foram avaliados pela técnica de T-RFLP com amostragens realizadas simultaneas nas duas áreas, aos 32 e 62 dias após o corte e aos 2, 15, 30, 45, 60, 90, 120, e 360 dias após queima da biomassa vegetal. Foi verificado rápido aumento da fertilidade do solo e diminuição da acidez e teores de Al+3 após a queima, entretanto esse efeito foi pouco persistente, retornando ao status inicial do solo após um ano. Houve redução de 30 % nos estoques de C e N do solo no final do estudo, evidenciando os efeitos deletérios da mudança do uso da terra nos atributos químicos do solo. Foi registrado redução de 50 % das emissões de CO2 equivalente após o corte, comparada à vegetação nativa e reduções nas emissões de GEE de 35 % após um ano de estudo. Verificou-se na camada superficial, alterações significativas na estrutura da comunidade bacateriana do solo em decorrência do impacto do fogo e das alterações nos atributos químicos em função da deposição superficial de cinzas no solo, entretanto não foi verificada alterações significativa nas camadas abaixo de 5 cm. Este estudo forneceu importantes informações para o entendimento dos impactos e as alterações causadas pelo processo de conversão florestal tropical pelo corte e queima de vegetação nativa na Amazônia. / In recent decades, climate change has been evidenced by the increase in global temperature and the decrease in terrestrial carbon stocks, associated with an increase in greenhouse gas (GHG) emissions. The Amazon rainforest is the largest tropical biome in the world and develops strategic environmental services on the planet. However, for more than two decades, deforestation in Amazon has driven global GHG emissions, reducing soil carbon storage with changes in microbial populations dynamics and in biogeochemical cycles due to land use change. The objective of this study was to evaluate the temporal alterations of soil chemical attributes, quantify CO2, CH4 and N2O emissions and verify changes in soil bacterial structure, due to the slash and burn of the native vegetation in Amazon. The study was developed in an area of native vegetation in the north of Rondônia state, southern region of Amazon in Brazil. The study area consisted of 4 hectares, where it was cut and burned in 2.25 hectares. Samples were collected to evaluate soil fertility and carbon (C) and nitrogen (N) stocks at the depths of 0-5, 5-10, 10-15, 15-20, 20-30, 30-40, 40- 50, 50-60, 60-80 and 80-100 cm. These samples were collected in native vegetation at 2, 30, 60, 90, 120, 240 and 365 days after cutting and burning. The attributes pH, Al, H + Al, Ca, Mg, K, P, C, N were determined and the values of base sum, CEC, base saturation and aluminum saturation were calculated. The samples to quantify GHG emissions were carried out simultaneously in the native vegetation area and in the central hectare of the cutting and burning area at 19, 31, 48, 61 and 81 days after cutting and 2, 4, 6, 8, 15, 31, 45, 61, 88, 122, 153, 180, 240 and 350 days after burning, with samples at 0, 20, 40 and 60 minutes. The microbiological attributes of the soil were evaluated by T-RFLP technique with simultaneous samplings in the two areas, at 32 and 62 days after cutting and at 2, 15, 30, 45, 60, 90, 120, and 360 days after plant biomass burning. A rapid increase in soil fertility and a decrease in acidity and Al+3 contents after burning were verified, however this effect was not persistent, returning to the initial soil status after one year. There was a 30 % reduction in soil C and N stocks at the end of the study, evidencing the deleterious effects of land use change on soil chemical attributes. Also, a 50 % reduction in CO2 emissions after cutting, compared to native vegetation and, a 35 % reduction in GHG emissions after one year of study, were observed. We verified in the surface layer, significant alterations in the soil bacteria structure due to the fire impact and the changes in the chemical attributes, such as surface deposition of ashes. However, we did not verified significant changes in the layers lower than 5 cm. Our study provided important information for understanding the impacts and changes of the tropical forest conversion process by slash and burning native vegetation in Amazon.

Desmatamento tropical

Emissão de gases de efeito estufa

Estoques de C no solo

Estrutura microbiana

Mudança do uso da terra

Bacterial structure

Greenhouse gases

Land use change

Soil fertility

Soil organic matter

Tropical deforestation

The effect of forest to pasture conversion on soil biological diversity and function

Lloyd, Davidson A.

January 2008

Recent declines in returns from primary forest products in New Zealand and projected increases in world food prices have led to the land-use conversion from plantation forest to pastoral farming in many lowland areas. After decades of forest cover the soils are in many cases less than adequate for pastoral farming, as they are acidic, with toxic levels of exchangeable aluminum, and contain low levels of available nitrogen (N), very high carbon (C):N ratio, and are devoid of earthworms and structural integrity. Overcoming the major site limitations of low soil pH and available N was a major priority and a field experiment was established in April 2005 to determine the impact of various rates of lime and N in relation to pasture establishment and production. Concerns about the short and long-term effects of these inputs on biological soil quality gave rise to the present study. The effects of land-use change and establishment inputs were assessed by comparison of selected treatment plots with two adjacent reference sites (long-term pasture and a 60–year Pinus radiata forest) on the same soil type. The effects of lime and N on soil biological quality were investigated under field and controlled environment conditions by determination of: microbial community structure (phospholipid fatty acids - PLFA), microbial biomass (total PLFA), and microbial activity (dehydrogenase activity). Soil physical (percentage water-stable aggregates) and chemical (pH, and total C and N) properties were also determined. Similarly, the effects of earthworm addition on soil biological properties were explored in a short-term glasshouse pot experiment. The role of earthworms as indicators of soil biological quality in the field was assumed by nematodes and these were assessed in field trial plots and the reference sites mentioned above. Land-use change and applications of lime and N contributed to changing the microbial community structure determined by principal component analysis of transformed PLFA data. However, the effect of lime was more pronounced in the field, while N contributed most to changing microbial community structure in the glasshouse. Mean microbial activity in the field increased from 4 µg dwt/hr without lime to 16 and 21 µg dwt/hr where lime was applied at 5 and 10 tons/hectare (t/ha), respectively. Mean microbial activity in the field was markedly higher (7-fold) than in the glasshouse at similar rates of lime. Lime application also increased soil moisture retention in the field, mean gravimetric soil moisture increased from 0.33 in control plots to 0.38 and 0.39 in plots treated with 5 and 10 t/ha lime, respectively. Lime application was associated with greater soil aggregate stability. Soils from test plots treated with 5 and 10 tons/ha lime had 45-50% water-stable aggregates compared to 34% in treatments without lime. After 16 weeks in pots, earthworm treatments increased mean plant dry matter (DM)/pot by at least 19% above the control. The increase was attributed primarily to greater N mineralization in the presence of earthworms. For the duration of the trial the earthworm species tested (Apporectodea caliginosa and Lumbricus rubellus, individually or combined) did not affect any of the measured soil microbial properties. However, the survival rate of A. caliginosa was 83% compared to 25% for L. rubellus. The control not receiving any lime or N and plots treated with 10t/ha lime and 200 kgN/ha had similar nematodes species composition, comprising 40% each of bacterial and fungal feeding nematodes. They differed markedly from the reference sites as the forest soil was dominated by plant associated species (38%) and the long-term pasture had 44% plant parasitic nematodes. Accordingly, the soil food web condition inferred from nematode faunal analysis characterized all test plots as basal, stressed and depleted, while the forest soil was categorized as highly structured and fungal dominated. The findings of this thesis demonstrated that land-use change from forest to pasture can have significant impacts on soil biological properties, earthworms can contribute to pasture productivity even in the short term, and nematode faunal analysis is a robust and reliable indicator of soil biological quality.

forest

pasture

land-use change

microbial diversity

phospholipid fatty acid

earthworms

nematodes

海平面上升對土地利用變遷與人口遷移影響之研究─以台北都會區為例 / The influence of sea level rise on land use changes and population migration ─ A study of Taipei metropolitan area

張伊芳, Chang, Yi Fang

Unknown Date

IPCC於第四次報告書中，模擬氣候持續暖化預測未來海平面上升之情形，而海平面上升對於人口集中的台北都會區將產生莫大之衝擊，同時亦會造成土地利用變遷。本研究目的在於探討海平面上升對台北都會區土地利用變遷之影響，以及受淹沒地區之人口未來可能之遷移區位，主要係從社會經濟發展層面進行分析。運用二元羅吉斯迴歸模式並結合土地利用轉換與影響模型（CLUE-s），以四種不同情境模擬土地利用變遷之情況，其情境分別為海平面上升59公分管制農林地與不管制，以及海平面上升100公分管制農林地與不管制。 　　研究結果顯示，海平面上升之情形越嚴重，未來的都市建地發展會越趨向擴張的形式，對農林地產生變遷之壓力；而於同一海平面上升水平下，針對農林地進行管制，其建地之發展會較為集中於都市計畫地區範圍內，且多數人口亦將遷移至此，容易形成人口壓力。此外，土地利用變遷模擬所得之新增建地部分，於情境A、C下足以容納受影響之人口，但情境B、D則不足以容納，皆會對台北都會區產生容受力之問題，產生累計人口超過計畫人口之現象。因此，建議未來政府於都市發展上，可調整都市計畫內之土地使用強度或都市範圍，也可利用都市更新之方式減少新的土地開發；此外，從國家層級分析，未來的國土計畫法於立法上，亦可將更多氣候變遷相關影響因子納入四大功能分區，透過適宜性分析進行分類分級，以做為未來土地利用發展之引導。 / The 4th IPCC report simulated climate warming and predicted future sea-level rise scenarios. A sea level rise will have a great impact on the population of the Taipei metropolitan area, and it will also produce land-use changes. The purpose of this study is to research the impact of sea level change on land use changes and population migration in Taipei metropolitan, and the areas that will be immigrated by the flooded areas. The method used includes binary logistic regression model combined with Conversion of Land Use and its Effects Model (CLUE-s). Setting the sea-level rise and regulating agricultural land, forest land of the four simulated situations. The results show that the higher sea level rises, the more transformation towards urban development in the future, and the higher sea level will also pressure agriculture and forestry changes. As a result of population pressure on Taipei metropolitan area, the same level of sea-level rise for the regulation of agriculture and forestry land, the development of building sites and population migration will be more concentrated on urban planning areas. In addition, the simulation of land use change generated new building sites, sufficient enough to accommodate the affected population under A and C simulated situations, but B and D couldn’t generate such results. Instead, it will generate a carrying capacity issue. Therefore, this thesis suggests that the government adjust the intensity of land use in urban development, urban areas and urban renewal of urban planning. In addition, the analysis from the national level, the future legislation of Land Planning Act should include the relation of climate change impact factors as a consideration of future land use development.

海平面上升

土地利用變遷

二元羅吉斯迴歸

CLUE-s

人口遷移

Sea-level rise

land use change

binary logistic regression

CLUE-s

population migration

The effect of forest to pasture conversion on soil biological diversity and function

Lloyd, Davidson A.

January 2008

Recent declines in returns from primary forest products in New Zealand and projected increases in world food prices have led to the land-use conversion from plantation forest to pastoral farming in many lowland areas. After decades of forest cover the soils are in many cases less than adequate for pastoral farming, as they are acidic, with toxic levels of exchangeable aluminum, and contain low levels of available nitrogen (N), very high carbon (C):N ratio, and are devoid of earthworms and structural integrity. Overcoming the major site limitations of low soil pH and available N was a major priority and a field experiment was established in April 2005 to determine the impact of various rates of lime and N in relation to pasture establishment and production. Concerns about the short and long-term effects of these inputs on biological soil quality gave rise to the present study. The effects of land-use change and establishment inputs were assessed by comparison of selected treatment plots with two adjacent reference sites (long-term pasture and a 60–year Pinus radiata forest) on the same soil type. The effects of lime and N on soil biological quality were investigated under field and controlled environment conditions by determination of: microbial community structure (phospholipid fatty acids - PLFA), microbial biomass (total PLFA), and microbial activity (dehydrogenase activity). Soil physical (percentage water-stable aggregates) and chemical (pH, and total C and N) properties were also determined. Similarly, the effects of earthworm addition on soil biological properties were explored in a short-term glasshouse pot experiment. The role of earthworms as indicators of soil biological quality in the field was assumed by nematodes and these were assessed in field trial plots and the reference sites mentioned above. Land-use change and applications of lime and N contributed to changing the microbial community structure determined by principal component analysis of transformed PLFA data. However, the effect of lime was more pronounced in the field, while N contributed most to changing microbial community structure in the glasshouse. Mean microbial activity in the field increased from 4 µg dwt/hr without lime to 16 and 21 µg dwt/hr where lime was applied at 5 and 10 tons/hectare (t/ha), respectively. Mean microbial activity in the field was markedly higher (7-fold) than in the glasshouse at similar rates of lime. Lime application also increased soil moisture retention in the field, mean gravimetric soil moisture increased from 0.33 in control plots to 0.38 and 0.39 in plots treated with 5 and 10 t/ha lime, respectively. Lime application was associated with greater soil aggregate stability. Soils from test plots treated with 5 and 10 tons/ha lime had 45-50% water-stable aggregates compared to 34% in treatments without lime. After 16 weeks in pots, earthworm treatments increased mean plant dry matter (DM)/pot by at least 19% above the control. The increase was attributed primarily to greater N mineralization in the presence of earthworms. For the duration of the trial the earthworm species tested (Apporectodea caliginosa and Lumbricus rubellus, individually or combined) did not affect any of the measured soil microbial properties. However, the survival rate of A. caliginosa was 83% compared to 25% for L. rubellus. The control not receiving any lime or N and plots treated with 10t/ha lime and 200 kgN/ha had similar nematodes species composition, comprising 40% each of bacterial and fungal feeding nematodes. They differed markedly from the reference sites as the forest soil was dominated by plant associated species (38%) and the long-term pasture had 44% plant parasitic nematodes. Accordingly, the soil food web condition inferred from nematode faunal analysis characterized all test plots as basal, stressed and depleted, while the forest soil was categorized as highly structured and fungal dominated. The findings of this thesis demonstrated that land-use change from forest to pasture can have significant impacts on soil biological properties, earthworms can contribute to pasture productivity even in the short term, and nematode faunal analysis is a robust and reliable indicator of soil biological quality.

forest

pasture

land-use change

microbial diversity

phospholipid fatty acid

earthworms

nematodes

Integrated modelling of Global Change impacts in the German Elbe River Basin

Hattermann, Fred Fokko

January 2005

The scope of this study is to investigate the environmental change in the German part of the Elbe river basin, whereby the focus is on two water related problems: having too little water and having water of poor quality. <br><br> The Elbe region is representative of humid to semi-humid landscapes in central Europe, where water availability during the summer season is the limiting factor for plant growth and crop yields, especially in the loess areas, where the annual precipitation is lower than 500 mm. It is most likely that water quantity problems will accelerate in future, because both the observed and the projected climate trend show an increase in temperature and a decrease in annual precipitation, especially in the summer. Another problem is nutrient pollution of rivers and lakes. In the early 1990s, the Elbe was one of the most heavily polluted rivers in Europe. Even though nutrient emissions from point sources have notably decreased in the basin due to reduction of industrial sources and introduction of new and improved sewage treatment facilities, the diffuse sources of pollution are still not sufficiently controlled. <br><br> The investigations have been done using the eco-hydrological model SWIM (Soil and Water Integrated Model), which has been embedded in a model framework of climate and agro-economic models. A global scenario of climate and agro-economic change has been regionalized to generate transient climate forcing data and land use boundary conditions for the model. The model was used to transform the climate and land use changes into altered evapotranspiration, groundwater recharge, crop yields and river discharge, and to investigate the development of water quality in the river basin. Particular emphasis was given to assessing the significance of the impacts on the hydrology, taking into account in the analysis the inherent uncertainty of the regional climate change as well as the uncertainty in the results of the model. <br><br> The average trend of the regional climate change scenario indicates a decrease in mean annual precipitation up to 2055 of about 1.5 %, but with high uncertainty (covering the range from -15.3 % to +14.8 %), and a less uncertain increase in temperature of approximately 1.4 K. The relatively small change in precipitation in conjunction with the change in temperature leads to severe impacts on groundwater recharge and river flow. Increasing temperature induces longer vegetation periods, and the seasonality of the flow regime changes towards longer low flow spells in summer. As a results the water availability will decrease on average of the scenario simulations by approximately 15 %. The increase in temperatures will improve the growth conditions for temperature limited crops like maize. The uncertainty of the climate trend is particularly high in regions where the change is the highest. <br><br> The simulation results for the Nuthe subbasin of the Elbe indicate that retention processes in groundwater, wetlands and riparian zones have a high potential to reduce the nitrate concentrations of rivers and lakes in the basin, because they are located at the interface between catchment area and surface water bodies, where they are controlling the diffuse nutrient inputs. The relatively high retention of nitrate in the Nuthe basin is due to the long residence time of water in the subsurface (about 40 years), with good conditions for denitrification, and due to nitrate retention and plant uptake in wetlands and riparian zones. <br><br> The concluding result of the study is that the natural environment and communities in parts of Central Europe will have considerably lower water resources under scenario conditions. The water quality will improve, but due to the long residence time of water and nutrients in the subsurface, this improvement will be slower in areas where the conditions for nutrient turn-over in the subsurface are poor. / Ziel der vorliegenden Arbeit ist die Untersuchung der Auswirkungen des Globalen Wandels auf den Wasserkreislauf im deutschen Teil des Elbeeinzugsgebietes. Der Fokus liegt dabei auf Wassermengen- und Wasserqualitätsproblemen. <br><br> Die Elbe liegt im Zentrum Europas im Übergangsbereich zwischen ozeanischen und kontinentalen Klimaten, wo die Wasserverfügbarkeit in den Sommermonaten den limitierenden Faktor für das Pflanzenwachstum und die landwirtschaftlichen Erträge bildet. Dies gilt insbesondere für die Lössgebiete im Lee des Harzes, wo die jährlichen Niederschläge unter 500 mm liegen. Es ist sehr wahrscheinlich, dass sich die Wassermengenprobleme in Zukunft noch verstärken werden, denn sowohl das beobachtete als auch das für die Zukunft projizierte Klima in der Region zeigen höhere Temperaturen und fallende Niederschläge, besonders im Sommer. Ein weiteres Problem ist die hohe Nährstoffbelastung der Flüsse und Seen im Elbeeinzugsgebiet. Anfang der neunziger Jahre war die Elbe eine der am stärksten belasteten Flüsse in Europa. Obwohl die Einträge besonders aus Punktquellen durch den Rückgang der Industrie und den Bau von neuen Kläranlagen seitdem gefallen sind, gelangen trotzdem noch große Nährstoffmengen aus diffusen Quellen in die Gewässer. <br><br> Die Untersuchungen wurden unter Anwendung des ökohydrologischen Modells SWIM (Soil and Water Integrated Model) durchgeführt, welches über Schnittstellen mit Klimamodellen und agroökonomischen Modellen verbunden wurde. Ein globales Szenario des Klimawandels und des landwirtschaftlichen Wandels wurde regionalisiert, um so die geänderten Randbedingungen für den Szenarienzeitraum zu erhalten. Simulationen mit SWIM dienten dann dazu, die geänderten Randbedingungen in Änderungen im Wasserhaushalt und in den landwirtschaftlichen Erträgen zu transformieren. Außerdem wurde das Langzeitverhalten von Nährstoffen im Untersuchungsgebiet modelliert. Besonderer Wert wurde dabei darauf gelegt, die Unsicherheit der Szenarienergebnisse zu quantifizieren. <br><br> Der mittlere Szenarientrend zeigt eine Reduzierung der mittleren jährlichen Niederschläge bis zum Jahre 2055 um ungefähr 1.5 %, wobei die Ergebnisse mit einer großen Unsicherheit behaftet sind: die Spannweite der Niederschläge in den Szenarienrealisationen liegt zwischen -15.3 % und +14.8 %. Die Erwärmung unter Szenarienbedingungen mit ungefähr 1.4 K ist weniger unsicher. Diese relativ geringen Änderungen habe starke Auswirkungen auf den Wasserhaushalt im Elbegebiet: durch die steigenden Temperaturen wird die Vegetationszeit verlängert, und die Niedrigabflussperiode im Sommer wird sich in den Herbst ausdehnen. Insgesamt wird unter dem mittleren Szenarientrend die Wasserverfügbarkeit um ca. 15 % abnehmen. Außerdem werden sich durch die steigenden Temperaturen die Anbaubedingungen für wärmeliebende Ackerfrüchte in der Landwirtschaft verbessern. Die Unsicherheit des Klimatrends ist dort am größten, wo auch die lokalen Änderungen am größten sind. <br><br> Die Simulationsergebnisse für das Nuthe-Teileinzugsgebiet der Elbe zeigen, das Retentionsprozesse im Untergrund und in den Feucht- und Auengebieten einen starken Einfluss auf die Wasserqualität und die Nitratkonzentration der Oberflächengewässer haben, da sie durch ihre Lage im Einzugsgebiet eine Schnittstelle zwischen dem umliegenden Einzugsgebiet und den Flüssen und Seen bilden. Die relativ hohe Umsetzung von Nitrat im Einzugsgebiet der Nuthe kann dadurch erklärt werden, dass Nitrat eine relativ lange Aufenthaltszeit im Grundwasser (im Mittel 40 Jahre) mit einer hohen Nitratumsetzungsrate hat, und durch die guten Denitrifizierungsbedingungen in den Feucht- und Auengebieten. Dazu kommt noch, dass große Nitratmengen durch die Pflanzen in den Feuchtgebieten aus dem Grundwasser aufgenommen werden. <br><br> Zusammenfassend kann man sagen, das sich die Ökosysteme und die Gesellschaft im Elbeeinzugsgebiet unter Szenarienbedingungen auf niedrigere Wasserverfügbarkeit einstellen müssen. Die Wasserqualität wird sich grundsätzlich zwar weiter verbessern, aber aufgrund der langen Verweilzeit der Nährstoffe im Grundwasser wird dies insbesondere in den Teileinzugsgebieten, in denen die geochemischen Bedingungen für einen hohen Nährstoffumsatz nicht gegeben sind, noch relativ lange dauern.

Hydrologie

Modellierung

Einzugsgebiet

Mathematisches Modell

integrierte hydrologische Modellierung

Klimaänderung

Wasserqualität

Landnutzungsänderung

Ertragsänderung

integrated hydrolocal modelling

climate change impacts

water quality

land use change

ecohydrology

Earth sciences