INVOLVEMENT OF RESIDUAL GAS OF MEMBRANE HYDROGEN SEPARATION UNIT IN RAW OF STEAM CONVERSION

For a more qualified use of the residual gas formed during the separation of hydro gen from a hydrogen-containing gas, a scheme was proposed for its processing together with hydro carbon gases (HCG) in the process of steam conversion. At the same time, it became possible to re pair the HCG pipeline without stopping production, was reached HCG savings and received additional amount of hydrogen, the products (split gas) corresponded to standards.

Potential Production of Carbon Gases and Their Responses to Paleoclimate Conditions: An Example From Xiaolongtan Basin, Southeast Tibetan Plateau

Uplift of the Tibetan Plateau plays a significant and lasting role in the variations of climate conditions and global carbon cycle. However, our knowledge is limited due to the lack of long-sequence records revealing rates of CO2 and CH4 production, hampering our understanding of the relationship between paleoclimatic conditions, carbon cycling and greenhouse gas flux. Here, we present a combination of paleoclimate records and low-temperature thermal simulation results from sediments of the Xiaolongtan Basin at the southeastern margin of the Qinghai-Tibetan Plateau, spanning the late Miocene (14.1 ∼ 11.6 Ma). The n-alkane-derived proxies suggested that the sources of organic matter were obviously different: a mixed source including lower organisms and terrestrial higher plants for the Dongshengqiao Formation from 14.1 to 12.6 Ma, and a predominant contribution from terrestrial higher plants for Xiaolongtan Formation between 12.6 and 11.6 Ma. The paleoclimate was generally warm and humid as reflected by the lipid biomarkers, consistent with previous studies. In addition, the carbon gases (including CO2 and hydrocarbon gases) generated by the low-temperature thermal simulation experiments indicated a production rate of CO2 and CH4 were as high as 88,000 ml/kg rock and 4,000 ml/kg rock, respectively, implying there were certain amounts of carbon gases generated and released into the atmosphere during their shallow burial stage. Besides, the calculated production rate of carbon gases and the estimated burial flux of organic carbon varied in response to the variations of paleoclimate conditions. Based on these observations, we propose that the climate conditions predominantly controlled the formation and accumulation of organic matter, which consequently affected the production of carbon gases and burial flux of organic carbon. The results presented here may provide a significant insight into the carbon cycle in the southeast of the Tibetan Plateau.

How will energy transition impact the major EU natural gas suppliers?

This paper focuses on the adaptation strategies of two major EU natural gas suppliers – Gazprom and Equinor – to new challenges imposed by the clean energy transition. Oil and gas companies around the world have already started to adjust their business strategies, inter alia, by investing in renewable energy. The recently proposed European Green Deal adds additional decarbonisation pressure to the gas sector with the increasing supply of renewable and low-carbon gases and the reduction of energy-related methane emissions.

Simultaneous shipborne measurements of CO₂, CH₄ and CO and their application to improving greenhouse-gas flux estimates in Australia

Quantitative understanding of the sources and sinks of greenhouse gases is essential for predicting greenhouse-gas–climate feedback processes and their impacts on climate variability and change. Australia plays a significant role in driving variability in global carbon cycling, but the budgets of carbon gases in Australia remain highly uncertain. Here, shipborne Fourier transform infrared spectrometer measurements collected around Australia are used together with a global chemical transport model (GEOS-Chem) to analyse the variability of three direct and indirect carbon greenhouse gases: carbon dioxide (CO2), methane (CH4) and carbon monoxide (CO). Using these measurements, we provide an updated distribution of these gases. From the model, we quantify their sources and sinks, and we exploit the benefits of multi-species analysis to explore co-variations to constrain relevant processes. We find that for all three gases, the eastern Australian coast is largely influenced by local anthropogenic sources, while the southern, western and northern coasts are characterised by a mixture of anthropogenic and natural sources. Comparing coincident and co-located enhancements in the three carbon gases highlighted several common sources from the Australian continent. We found evidence for 17 events with similar enhancement patterns indicative of co-emission and calculated enhancement ratios and modelled source contributions for each event. We found that anthropogenic co-enhancement events are common along the eastern coast, while co-enhancement events in the tropics primarily derive from biomass burning sources. While the GEOS-Chem model generally reproduced the timing of co-enhancement events, it was less able to reproduce the magnitude of enhancements. We used these differences to identify underestimated, overestimated and missing processes in the model. We found model overestimates of CH4 from coal burning and underestimates of all three gases from biomass burning. We identified missing sources from fossil fuel, biofuel, oil, gas, coal, livestock, biomass burning and the biosphere in the model, pointing to the need to further develop and evaluate greenhouse-gas emission inventories for the Australian continent.

The Criminal Dimension of Climate Change

Peter D. Carter and Elizabeth Woodworth, Unprecedented Crime: Climate Science Denial and Game Changers for Survival (Atlanta: Clarity Press, 2017), 270 pages, $27.95, paperback. Unprecedented Crime, a book by Peter Carter and Elizabeth Woodworth, with a foreword by leading climate scientist James Hansen, outlines the criminality of those who actively promote the continuing emission of carbon gases into the atmosphere despite having full knowledge of the consequences. These consequences include the breakdown of large ice sheets, rising sea levels, and the intensification of extreme weather events around the world, such as hurricanes, floods, and fires.

Simultaneous shipborne measurements of CO₂, CH₄ and CO and their application to improving greenhouse gas flux estimates in Australia

Quantitative understanding of the sources and sinks of greenhouse gases is essential for predicting greenhouse gas-climate feedback processes and their impacts on climate variability and change. Australia plays a significant role in driving variability in global carbon cycling, but the budgets of carbon gases in Australia remain highly uncertain. Here, shipborne Fourier Transform Infrared Spectrometer measurements collected around Australia are used together with a global chemical transport model (GEOS-Chem) to identify and quantify the sources of three direct and indirect carbon greenhouse gases: carbon dioxide (CO2), methane (CH4) and carbon monoxide (CO). Using these measurements, we provide an updated distribution of these gases and their sources and sinks. We find that for all three gases, the east Australian coast is largely influenced by local anthropogenic sources, which can be transported as far as 400 km off the coast. The south and west coasts are characterised by a mixture of anthropogenic sources and biomass burning. Tropical northern regions are dominated by biomass burning emissions, with significant contribution from fossil fuel for CO2 and wetlands for CH4. Averaged across Australia, fossil fuels followed by biomass burning contribute the most to total CO2 and to both its background value and short-term enhancements. Wetlands provide the largest background CH4 source, followed by livestock, oil, gas and waste emissions, with short-term enhancements mainly driven by anthropogenic sources. For CO, secondary production from oxidation of CH4 and non-methane volatile organic compounds contributes most to the background and total CO burdens, while enhancements are driven by biomass burning and anthropogenic sources. Clean air characteristic of the tropospheric background was observed away from the coast in the Indian Ocean, Coral Sea, and Tasman Sea. From the measurements in the Indian Ocean, we found that the background values of all three gases increase towards the tropics with latitudinal gradients of 0.019 ± 0.003 ppm deg−1 for CO2, 0.34 ± 0.02 ppb deg−1 for CH4 and 0.82 ± 0.05 ppb deg−1 for CO. Comparing coincident and co-located enhancements in the three carbon gases highlighted several common sources from the Australian continent. We found evidence for 17 events with similar enhancement patterns indicative of co-emission and calculated enhancements ratios and modelled source contributions for each event. We found that anthropogenic co-enhancement events are common along the east coast, while co-enhancement events in the tropics primarily derive from biomass burning sources. Few co-enhancement events were observed along the south and west coasts. While the GEOS-Chem model generally reproduced the timing of co-enhancement events, it was less able to reproduce the magnitude of enhancements. We found model overestimates of CH4 from coal burning and underestimates of all three gases from biomass burning with overestimates for CO during some events. We identified missing sources from fossil fuel, biofuel, oil, gas, coal, livestock, biomass burning and the biosphere in the model, pointing to the need to further develop and evaluate greenhouse gas emission inventories for the Australian continent.

Innovation in Nuclear Power

Next-generation nuclear technologies represent a change to how nuclear power plants are designedand the crucial role nuclear power can play in the world’s future energy mix. The authors examine the current regulatory framework for nuclear power in the United States, the birthplace of nuclear energy. That framework was shaped by concerns over release of nuclear secrets to hostile nations, focus on a single technology in light-water reactors, recognition that nuclear electric generation would be handled in the realm of monopoly control of generation, transmission, and distribution of the electricity produced, and a limited appreciation of the contribution of nuclear power to current goals of control of release of carbon gases and need to emphasize sustainability in energy supply. Recent bold innovations in nuclear technology, and legal impediments to their development, are identified. The authors identify helpful steps to make the law receptive to the new needs and technologies.