Fluxo de gases-traco de efeito estufa na interface solo/atmosfera em solos de cerrado (2001).

A contribuicao da agricultura para as emissoes de gases de efeito estufa tem sido discutida em varios estudos. No que se refere as emissoes de CH4 (metano) e N2O (oxido nitroso), tem sido demostrado que a contribuicao dela esta em torno de 65% e 90% do total das emissoes antropogenicas respectivamente. O metano e produzido pela decomposicao anaerobica da materia organica no solo, queima de residuos e fermentacao de ruminantes. O cosumo desse gas ocorre pela oxidacao de radicais OH na troposfera e por oxidacao microbiologica no solo. O oxido nitroso e igualmente distribuido na troposfera e apresenta um tempo de resistencia bem maior do que o metano. Esse gas e produzido nos solos por processos biologicos e não-bioloicos, a partir de tranformacoes microbianas de nitrogenio inorganico nos solos, sendo a denitrifigacao e a nitrifigacao, os processos microbiologicos que mais contribuem para a emissao de N2O. A conversao de floresta para o uso agricola tem sido indicado como causador do aumento no fluxos de N2O, no entanto, neste estudo, em areas de Cerrado, emissoes muito reduzidas foram medidas. A capacidade de solos da Regiao do Cerrado consumir CH4 foi demostrada neste estudo. Embora tenha sido observada uma variacao sazonal dos fluxos, em nenhum periodo foi medida emissao desse gas, mesmo durante o periodo chuvoso. A possível reducao nas taxas de oxidacao de metano como resultado do aumento de fontes nitrogenadas em areas cultivadas, indicada por trabalhos anteriores, não e verificada pelo estudo.

Relação entre pressão e volume para implantação da técnica in vitro semi-automática de produção de gases na Embrapa Cerrados.

2008

Estudo do processo de difusão de gases em carvões com base em isotérmicas de Langmuir

Tese de Doutoramento apresentada à Universidade Fernando Pessoa como parte dos requisitos para obtenção do grau de Doutror em Ciências da Terra.

Operational retrieval of trace gases concentrations from IASI spectra

info:eu-repo/semantics/nonPublished

Operational retrieval of trace gases concentrations from IASI spectra

info:eu-repo/semantics/nonPublished

Quantitative laboratory spectroscopy of atmospheric trace gases

info:eu-repo/semantics/published

Volcanic Gases

info:eu-repo/semantics/published

Technical Note: Ensuring consistent, global measurements of short-lived halocarbon gases in the ocean and atmosphere

Very short-lived halocarbons are significant sources of reactive halogen in the marine boundary layer, and likely in the upper troposphere and lower stratosphere. Quantifying ambient concentrations in the surface ocean and atmosphere is essential for understanding the atmospheric impact of these trace gas fluxes. Despite the body of literature increasing substantially over recent years, calibration issues complicate the comparison of results and limit the utility of building larger-scale databases that would enable further development of the science (e.g. sea-air flux quantification, model validation, etc.). With this in mind, thirty-one scientists from both atmospheric and oceanic halocarbon communities in eight nations gathered in London in February 2008 to discuss the scientific issues and plan an international effort toward developing common calibration scales (http://tinyurl.com/c9cg58). Here, we discuss the outputs from this meeting, suggest the compounds that should be targeted initially, identify opportunities for beginning calibration and comparison efforts, and make recommendations for ways to improve the comparability of previous and future measurements.

Air-Sea Exchange of Marine Trace Gases

Many of the reactive trace gases detected in the atmosphere are both emitted from and deposited to the global oceans via exchange across the air–sea interface. The resistance to transfer through both air and water phases is highly sensitive to physical drivers (waves, bubbles, films, etc.), which can either enhance or suppress the rate of diffusion. In addition to outlining the fundamental processes controlling the air–sea gas exchange, the authors discuss these drivers, describe the existing parameterizations used to predict transfer velocities, and summarize the novel techniques for measuring in situ exchange rates. They review trace gases that influence climate via radiative forcing (greenhouse gases), those that can alter the oxidative capacity of the atmosphere (nitrogen- and sulfur-containing gases), and those that impact ozone levels (organohalogens), both in the troposphere and stratosphere. They review the known biological and chemical routes of production and destruction within the water column for these gases, whether the ocean acts as a source or sink, and whether temporal and spatial variations in saturation anomalies are observed. A current estimate of the marine contribution to the total atmospheric flux of these gases, which often highlights the significance of the oceans in biogeochemical cycling of trace gases, is provided, and how air–sea gas fluxes may change in the future is briefly assessed.