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AbstractSustainable biorefineries have a critical role to play in our common future. The need to provide more goods using renewable resources, combined with advances in science and technology, has provided a receptive environment for biorefinery systems development. Biorefineries offer the promise of using fewer non‐renewable resources, reducing CO2 emissions, creating new employment, and spurring innovation using clean and efficient technologies. Lessons are being learned from the establishment of first‐generation biofuel operations. The factors that are key to answering the question of biorefinery sustainability include: the type of feedstock, the conversion technologies and their respective conversion and energy efficiencies, the types of products (including coproducts) that are manufactured, and what products are substituted by the bioproducts. The BIOPOL review of eight existing biorefineries indicates that new efficient biorefineries can revitalize existing industries and promote regional development, especially in the R&D area. Establishment can be facilitated if existing facilities are used, if there is at least one product which is immediately marketable, and if supportive policies are in place. Economic, environmental, and social dimensions need to be evaluated in an integrated sustainability assessment. Sustainability principles, criteria, and indicators are emerging for bioenergy, biofuels, and bioproducts. Practical assessment methodologies, including data systems, are critical for both sustainable design and to assure consumers, investors, and governments that they are doing the ‘right thing’ by purchasing a certain bioproduct. If designed using lifecycle thinking, biorefineries can be profitable, socially responsible, and produce goods with less environmental impact than conventional products … and potentially even be restorative!. Copyright © 2010 Society of Chemical Industry and John Wiley & Sons, Ltd

Micropollutants in freshwater, e.g., pharmaceuticals such as contraceptives, are a source of increased concern for human health and wildlife. Even after excretion, some of these compounds are pharmaceutically active in aquatic environment and they are found to cause endocrine disruption in both human and wildlife populations. In this study we analyzed a membrane system, coated with enzymes, which removes endocrine disrupting chemicals or micropollutants from surface water used for drinking. In order to help a membrane manufacturer in product development, we conducted a cradle-to-grave life cycle assessment. Water purification with two membrane systems, based on membrane coating covalent binding versus adsorption, were analyzed and compared with granulated activated carbon made from coal and wood. It was found that the membrane with covalent binding can have much lower environmental impacts than activated carbon made from coal. A sensitivity analysis showed that operational electricity use, the source of electricity and membrane coating frequency influence the results significantly. Scenario analysis indicates that a membrane system with covalent binding which uses operational electricity lower than 0.2 kWh per m3 of filtered water and with monthly enzyme coating frequency can perform better than conventional activated carbon systems irrespective of the electricity source. These findings can be used to guide the optimization of the membrane parameters. This study provided an understanding of the membrane modification for micropollutant removal and its impacts on environment. Finally, we describe how environmental sustainability can be integrated into business decisions, such as process and material selection and design optimization, with the help of life cycle assessment.

The Lower Silurian Longmaxi Formation is an organic-rich (black) mudrock that is widely considered to be a potential shale gas reservoir in the southern Sichuan Basin (the Yangtze plate) in Southwest China. A case study is presented to characterise the shale gas reservoir using a workflow to evaluate its characteristics. A typical characterisation of a gas shale reservoir was determined using basset sample analysis (geochemical, petrographical, mineralogical, and petrophysical) through a series of tests. The results show that the Lower Silurian Longmaxi Formation shale reservoir is characterised by organic geochemistry and mineralogical, petrophysical and gas adsorption. Analysis of the data demonstrates that the reservoir properties of the rock in this region are rich and that the bottom group of the Longmaxi Formation has the greatest potential for gas production due to higher thermal maturity, total organic carbon (TOC) enrichment, better porosity and improved fracture potential. These results will provide a basis for further evaluation of the hydrocarbon potential of the Longmaxi Formation shale in the Sichuan Basin and for identifying areas with exploration potential.

AbstractPolicies aimed at supporting the bio‐based economy have so far centered on biomass use for electricity and fuels. But using biomass for the production of materials offers higher greenhouse gas savings than bioenergy per kg feedstock as well as per hectare. This has received comparatively little attention from policy‐makers; analyses of either existing or potential policy measures are almost entirely missing in this field. This paper by Barbara Hermann, M Carus, M Patel and K Blok, provides an overview of policy measures which are currently in place and investigates how they affect market penetration of biomaterials. © 2011 Society of Chemical Industry and John Wiley & Sons, Ltd

Recently, the international trade of various bioenergy commodities has grown rapidly, yet this growth is also hampered by some barriers. The aim of this paper is to obtain an overview of what market actors currently perceive as major opportunities and barriers for the development of international bioenergy trade. The work focuses on three bioenergy commodities: bioethanol, biodiesel and wood pellets. Data were collected through an internet-based questionnaire. The majority of the 141 respondents had an industrial background. Geographically, two-thirds were from (mainly Western) Europe, with other minor contributions from all other continents. Results show that import tariffs and the implementation of sustainability certification systems are perceived as (potentially) major barriers for the trade of bioethanol and biodiesel, while logistics are seen mainly as an obstacle for wood pellets. Development of technical standards was deemed more as an opportunity than a barrier for all commodities. Most important drivers were high fossil fuel prices and climate change mitigation policies. Concluding, to overcome some of the barriers, specific actions will be required by market parties and policy makers. Import tariffs for biofuels could be reduced or abolished, linked to multinational trade agreements and harmonization (including provisions on technical standards and sustainability requirements).

Renewable & sustainable energy reviews 189, 114033 - (2024). doi:10.1016/j.rser.2023.114033 Published by Elsevier Science, Amsterdam [u.a.]

The chemical sector is the largest industrial energy user, but detailed analysis of its energy use developments lags behind other energy-intensive sectors. A cost-driven forecasting model for basic chemicals production is developed, accounting for regional production costs, demand growth and stock turnover. The model determines the global production capacity placement, implementation of energy-efficient Best Practice Technology (BPT) and global carbon dioxide (CO2) emissions for the period 2010–2030. Subsequently, the effects of energy and climate policies on these parameters are quantified. About 60% of new basic chemical production capacity is projected to be placed in non-OECD regions by 2030 due to low energy prices. While global production increases by 80% between 2010 and 2030, the OECD's production capacity share decreases from 40% to 20% and global emissions increase by 50%. Energy pricing and climate policies are found to reduce 2030 CO2 emissions by 5–15% relative to the baseline developments by increasing BPT implementation. Maximum BPT implementation results in a 25% reduction. Further emission reductions require measures beyond energy-efficient technologies. The model is useful to estimate general trends related to basic chemicals production, but improved data from the chemical sector is required to expand the analysis to additional technologies and chemicals.