Towards the development of the supply chain of concentrated solar power

This work focuses on the investigation into the planning of renewable energy power plants in Brazil using the Concentrated Solar Power (CSP) technology. The main aim of the paper is to present an analysis of the planning process that can be used as a basis of the development of a method to assess the Brazilian’s local manufacturing and supply chain capabilities in supporting the deployment of the CSP technology. The paper identifies areas in which the concerted efforts should be emphasized. For this, the paper will first discuss the key components of the chosen CSP technology (in this case the parabolic through). The manufacturing processes of these components will subsequently be analyzed and the key enabling technologies will be determined. The demands of electricity will be estimated using the System Advisory Model®, a modelling tool developed by the National Renewable Energy Laboratory (NREL). An assessment method will finally be proposed to identify the potentials of the local Brazilian supply chain, through the readiness evaluation of the key enabling technologies and manufacturing processes

A deep dive into the modelling assumptions for biomass with carbon capture and storage (BECCS) : A transparency exercise

This work was supported by the UK Energy Research Council (UKERC)-funded project ‘Assessing potential, feasibility and impacts of Bioenergy with CCS (BECCS) in the UK (Access-BECCS)’. We are very grateful to our anonymous reviewers for their constructive feedback which helped us to improve the manuscript.Peer reviewedPublisher PD

Analysis of energy security and sustainability in future low carbon scenarios for Brazil

This study estimated a series of indicators to assess the energy security of supply and global and local environmental impacts under different mitigation scenarios through 2050 in Brazil, designed with the integrated optimisation energy system model MESSAGE-BRAZIL. The assessment of interactions between environmental impacts and energy security dimensions was complemented through the application of life cycle assessment (LCA) methodology. Overall results imply energy security establishes more synergies than trade-offs in increasingly stringent mitigation scenarios, especially patent within the sustainability dimension, which increases energy security and provides additional benefits regarding climate change mitigation and air pollution emissions. It is still necessary to extend analysis to other energy sectors in addition to the power supply sector, to promote a better understanding of repercussions of energy scenario expansion in energy security.This work was funded by the Brazilian research funding agencies CNPq and CAPES, under the Science Without Borders Programme, and the Marie Curie International Research Staff Exchange Scheme Fellowship within the 7th European Union Framework Programme, under the project NETEP- European Brazilian Network on Energy Planning (PIRSES-GA-2013-612263). We also acknowledge funding from US EPA and US AID (under Interagency Agreements DW89923040 and DW89923951US), through the LAMP, and the European Union, through the CLIMACAP project (EuropeAid/131944/C/SER/Multi)

Understanding cost escalation in nuclear reactor construction projects

This work seeks to evaluate overnight construction costs (OCC) and lead time escalation of nuclear reactors from 1955 to 2016. To this end, a comprehensive database of commercial Light Water Reactors (LWR) was developed and a statistical analysis was conducted. Findings reveal that there is significant delay in lead time, especially for the last generation reactors constructed from 2010’s. This results in the escalation of capital costs rather than a decline. Average OCC of newer reactors are 60% higher than the ones implemented in the earlier stages of the nuclear era. This suggests a negative learning curve effect for both OCC and lead time, which threats the market and financial sustainability of current and future nuclear energy projects. Although this is a general trend, this negative effect is country specific and, thus, induced by national policies and regulatory frameworks. Therefore, the role of nuclear technology to cope with the decarbonisation of the power sector must be better evaluated, taking into account the real cost impacts of nuclear technology implementation.This work was also funded by the Brazilian research funding agency CNPq.This work was funded by the Brazilian research funding agency CNPq and the Marie Curie International Research Staff Exchange Scheme Fellowship within the 7th European Union Framework Programme, under the project NETEP- European Brazilian Network on Energy Planning (PIRSES-GA-2013-612263)

Low-carbon scenarios for the Brazilian power system

The Brazilian power generation sector faces a paradigm change driven, on one hand, by a shift from a hydropower dominated mix and, on the other, by international goals for reducing greenhouse gases emissions. The objective of this work was to evaluate five scenarios for the Brazilian power system until 2050 using a multi-criteria decision analysis tool. These scenarios include a baseline trend and low carbon policy scenarios based on carbon taxes and carbon emission limits. To support the applied methodology, a questionnaire was elaborated to integrate the perceptions of experts on the scenario evaluation process. Taking into account the results from multi-criteria analysis, scenario preference followed the order of increasing share of renewables in the power system. The preferable option for the future Brazilian power system is a scenario where wind and biomass have a major contribution. The robustness of the multi-criteria tool applied in this study was tested by a sensitivity analysis. This analysis demonstrated that, regardless the respondents’ preferences and backgrounds, scenarios with higher shares of fossil fuel sources are the least preferable option, while scenarios with major contributions from wind and biomass are the preferable option to supply electricity in Brazil through 2050.This research was supported by a Marie Curie International Research Staff Exchange Scheme Fellowship within the 7th European Union Framework Programme, under project NETEP- European Brazilian Network on Energy Planning (PIRSES-GA-2013-612263)

Bioenergy for climate change mitigation: Scale and sustainability

Many global climate change mitigation pathways presented in IPCC assessment reports rely heavily on the deployment of bioenergy, often used in conjunction with carbon capture and storage. We review the literature on bioenergy use for climate change mitigation, including studies that use top-down integrated assessment models or bottom-up modelling, and studies that do not rely on modelling. We summarize the state of knowledge concerning potential co-benefits and adverse side effects of bioenergy systems and discuss limitations of modelling studies used to analyse consequences of bioenergy expansion. The implications of bioenergy supply on mitigation and other sustainability criteria are context dependent and influenced by feedstock, management regime, climatic region, scale of deployment and how bioenergy alters energy systems and land use. Depending on previous land use, widespread deployment of monoculture plantations may contribute to mitigation but can cause negative impacts across a range of other sustainability criteria. Strategic integration of new biomass supply systems into existing agriculture and forest landscapes may result in less mitigation but can contribute positively to other sustainability objectives. There is considerable variation in evaluations of how sustainability challenges evolve as the scale of bioenergy deployment increases, due to limitations of existing models, and uncertainty over the future context with respect to the many variables that influence alternative uses of biomass and land. Integrative policies, coordinated institutions and improved governance mechanisms to enhance co-benefits and minimize adverse side effects can reduce the risks of large-scale deployment of bioenergy. Further, conservation and efficiency measures for energy, land and biomass can support greater flexibility in achieving climate change mitigation and adaptation

Bioenergy for climate change mitigation: Scale and sustainability

Many global climate change mitigation pathways presented in IPCC assessment reports rely heavily on the deployment of bioenergy, often used in conjunction with carbon capture and storage. We review the literature on bioenergy use for climate change mitigation, including studies that use top-down integrated assessment models or bottom-up modelling, and studies that do not rely on modelling. We summarize the state of knowledge concerning potential co-benefits and adverse side effects of bioenergy systems and discuss limitations of modelling studies used to analyse consequences of bioenergy expansion. The implications of bioenergy supply on mitigation and other sustainability criteria are context dependent and influenced by feedstock, management regime, climatic region, scale of deployment and how bioenergy alters energy systems and land use. Depending on previous land use, widespread deployment of monoculture plantations may contribute to mitigation but can cause negative impacts across a range of other sustainability criteria. Strategic integration of new biomass supply systems into existing agriculture and forest landscapes may result in less mitigation but can contribute positively to other sustainability objectives. There is considerable variation in evaluations of how sustainability challenges evolve as the scale of bioenergy deployment increases, due to limitations of existing models, and uncertainty over the future context with respect to the many variables that influence alternative uses of biomass and land. Integrative policies, coordinated institutions and improved governance mechanisms to enhance co-benefits and minimize adverse side effects can reduce the risks of large-scale deployment of bioenergy. Further, conservation and efficiency measures for energy, land and biomass can support greater flexibility in achieving climate change mitigation and adaptation

Bioenergy for climate change mitigation : scale and sustainability

Funding Information: The authors are grateful for comments from three reviewers and the editor. The views expressed in this article are those of the authors alone.Peer reviewedPublisher PD

Photostabilization of sunscreens by incorporation of tea as the external phase

The use of isolated ultraviolet (UV) filters in photoprotective formulations creates products with limited protection against radiation, emphasising the need to develop formulations containing UVA and UVB filter combinations. However, most of the formulations developed to include both filters are unstable as a result of this combination, as well as by exposure to UV radiation. It is, therefore, crucial to include additives that enable photostabilization. Tea is the second most widely consumed beverage in the world and represents a good source of bioactive compounds, particularly polyphenols, which provide antioxidant activity. In the present work formulations containing green tea or black tea, as well as the sunscreens avobenzone (UVA sunscreen) and octilmetoxinamato (UVB sunscreen), were developed and evaluated in order to develop new and effective photostable formulations providing broad spectrum photoprotection. These formulations have been developed with complete replacement of the external phase of the oil in water (O/W) emulsion by these teas. The results showed that both teas presented photostabilizing capacity, particularly for green tea in the storage conditions at room temperature and at 5 °C, and black tea for the samples stored at 40 °C

Impact of stirring speed, glycerin and sodium chloride concentrations on photoprotective nanoemulsions

New technologies that improve the physical as the sensory properties of sunscreens can help to increase its continued use and impact on health. The use of nanoemulsions in the development of photoprotective vehicles is an advantage, since nanostructured components may have superior properties regarding their performance when compared to conventional products. The advantages of using nanobiotechnology in manufacture of cosmetic and dermatological formulations arise from the protection of compounds from chemical or enzymatic degradation, from the control of their release, and also to the prolonged retention time of cosmetic ingredients in the stratum corneum. Thus, this study aimed to evaluate the impact of stirring speed and of glycerin and sodium chloride concentrations in the development and effectiveness of a nanoemulsion containing ethylhexyl methoxycinnamate and benzophenone-3. The results of statistical analyses regarding the impact of the variables in the process of nanoemulsion development showed that these parameters affect the phase inversion temperature (PIT). However, this did not affect the particle size and the photoprotective efficacy in vitro