Accessible and affordable energy services are a prerequisite for socioeconomic growth and poverty reduction. Yet it is estimated that 600 million people in sub-Saharan Africa will not have access to electricity in 2030. Recent research suggests that universal access to electricity will be achieved through a mix of centralized and decentralized systems and that the diffusion of these technologies is a socio-technical process involving multiple actors. These actors include firms, networks, energy users, and government agencies that interact within a political landscape to deliver innovation within energy service systems. Thus, factors related to the political economy can impact the process of innovation and warrant analysis. This study aims to provide an analysis of the political economy factors that can influence the emergence of mini grid electricity development in the African context exemplified in Kenya as a case study. The study uses the Technology Innovation Systems (TIS) lens as an analytical framework to provide a critical analysis of how political economy factors have influenced the development of mini grid electricity in Kenya. The result shows that despite the presence of some favorable conditions for innovation, political economy factors significantly impede the deployment of mini grids in Kenya. Power and vested interests have created negative competition between public and private developers, limiting knowledge and information diffusion between actors and stalling mini grid developments where they are most needed.

While carbon dioxide removal is indispensable in net-zero climate policy, incentives to deploy removals are limited. Swedish public support to biochar is one exception. This paper draws on the Swedish case to explore expectations put on biochar and the significance of public support for fulfilling these expectations. The analysis shows that biochar is expected to contribute to several environmental objectives. However, while biochar producers and users voice expectations on strengthening the multifunctionality of landscapes, e.g., improved ecosystem resilience and reduced nutrient run-off, the authorities rather narrowly direct attention to the stability of biochar as a carbon storage. Nevertheless, public support is contributing to a small but important protective space for biochar development through three channels: First, through investment grants, which are crucial for the emerging Swedish biochar production capacity. Second, through demand-pull created by municipalities that specify high environmental safeguards, which favours domestic production over import. Third, indirectly through support of production facilities that enable intermediary activities for gathering and sharing knowledge. However, while recent changes to EU state aid regulation may be a game-changer, EU has until now acted as a barrier to support to carbon dioxide removal. This socio-technical regime resistance, combined with a lack of jointly articulated expectations on biochar, appear to have been preventing deployment on more significant scale.

India is aiming at achieving a major shift in energy production and provision from a fossil fuel-based economy to one focussing on clean energy. As a financially constrained context, the move to the use of renewable energy is happening also through foreign investment and centres mostly on large-scale solar rollouts across the country. Analyses of such initiatives disclose uneven distribution of the benefits and challenges across and within adjacent communities, which particularly affect women and girls due to their gendered roles and responsibilities. This perspective reviews solar energy initiatives focusing on women's engagement run by NGOs and partially funded by the Indian central government, and gendered analyses of large-scale solar energy rollouts, through a feminist lens. A feminist approach to the analysis of large-scale solar rollouts discloses asymmetric power relations and energy inequalities against women and girls, which often reproduce those linked to fossil fuel. In contrast to this scenario, NGOs have a long-standing tradition in India of addressing socio-economic issues where governments failed to do so. Yet, available evidence of the impacts of their engagement in small-scale energy projects in India is quite new. Grassroots solar energy innovations, by being shaped by local communities, have the potential to challenge constraints on a just transitions while promoting greater gender equality and responding to communities’ energy needs.

Remote islands, comprising over one-sixth of the Earth's surface area and home to approximately 9% of the global population, face formidable challenges in securing affordable, sustainable, and reliable energy. This paper presents a pioneering investigation into Mornington Island's transition from diesel reliance to renewable energy predominance over the next four decades. By demonstrating the tangible benefits of renewable energy implementation on Mornington Island, this research provides compelling simulated evidence that blending traditional and renewable energy sources can revolutionize energy provision for small island communities. Employing hybrid Wind-Solar renewable energy systems bolstered by an effective battery storage system (ESS), this innovative approach ensures a seamless shift to renewable energy, resilient against seasonal variations and extreme weather events such as cyclones. Our analysis, conducted through a tech-economic model simulating each 5% increment of renewable energy penetration, reveals that renewable energy outperforms traditional diesel generation in terms of affordability over a 40-year operational span. Specifically, a 95% renewable energy penetration yields the lowest levelized energy cost ($162.2/MWh), resulting in a remarkable $8.54 million reduction in diesel costs. A 5% diesel component secures annual energy supply, bridging the gap during periods of seasonal renewable energy variability and extreme cyclonic weather. While achieving 100% renewable energy generation is financially feasible, challenges arise in scaling battery capacity to stabilize energy supply during cyclone seasons. Moreover, our carbon accounting model indicates that although the construction of renewable energy infrastructure entails some indirect (Scope 3) carbon emissions, a 95% renewable penetration mitigates emissions by 90% compared to traditional diesel generation, amounting to a reduction of 39.17 kilotons over the 40-year period. This comprehensive study provides policymakers with invaluable insights, fostering a holistic understanding of the financial, technical, environmental, and political dimensions inherent in island energy transitions.

In supporting the phase-out of the fossil fuels, Roof Top Photovoltaic (RTPV) deployment has been adopted worldwide as an important step of a bottom-up driving pathway of citizens’ transformation to become net energy producers within the community of their localized building environment. However, the diverse bioclimatic conditions of this environment may affect the best RTPV implementation. This is facilitated by climate-related characterization and regional adaptation. Hence, the built environment globally as a function of the global horizontal irradiation (GHI), the local environmental parameters of the different climatic zones and the associated technological developments are surveyed.In this work, we have critically assessed the RTPV effect on the building's overall energy performance and found beneficial over a diverse range of moderate and warm climates. By applying adequate insulation beneath the RTPVs, the increased heating needs in winter in cold climates or higher nighttime cooling needs in summertime can be avoided. To design low-energy buildings, we propose an analytical framework based on the space energy coverage by RTPV and the global horizontal irradiation. Moreover, RTPV cooling at elevated temperatures improves the efficiency up to 20 % and increases the generated electricity up to 15 %. Increasing the RTPV efficiency with emerging technologies could extend the decarbonization of high-rise buildings with energy efficiency and RTPV measures. To accelerate the clean energy transition, rooftop PVs should be widely adopted for sustainable solar building applications. Combined with electrical storage, this will allow renewable energy resources to cover a large fraction of future building energy needs worldwide.

This article explores the potential convergence between the Social Construction of Technology (SCOT) framework and failure studies in the context of the alternative energy program in the Global South. It focuses on a single case study, namely the failure of micro-hydro technology in Banyubiru (the Banyubiru project). Using qualitative research methods, this article examines the construction of the Banyubiru project and its failure to integrate with the power grid of the Indonesia State Electricity Company (PLN), despite substantial investments, installations, and considerable interest in renewable energy from diverse stakeholder groups at local, national, and international levels. In a hybrid (online and in-person) format, semi-structured interviews were employed to obtain data. The data collection procedure also includes site visits, observations, and document analysis. The finding indicates that technology development follows a more complicated path than a straight one from interpretative flexibility to closure. It illustrates a progression from closure to interpretive flexibility, wherein social groupings initially establish formal agreements but afterwards encounter conflicting interpretations. In conclusion, the article illustrates the potential for failure studies to provide insights into the limitations of SCOT in the analysis of energy technology failures.

British Columbia (BC) is committed to transitioning to a low-carbon energy system to meet its CO2 emission reduction targets, but this shift towards renewable energy sources may have significant implications for land use. This paper investigates the land-use impacts of different electrification pathways and technology choices in BC's energy system using the BC Nexus model. Our analysis highlights the potential increase in land-use requirements associated with transitioning from fossil fuels to renewable energy sources, with the occupied land of the power system potentially increasing up to six times larger than the current total build-up land (depending on the scale of electrification and technology choice). These findings have important implications for policymakers in terms of balancing the trade-offs between energy security, economic development, and environmental sustainability. By understanding the physical footprint of the energy transition, decision-makers can develop more effective climate policies and sustainable development strategies.

Isolated mini-grids (MG) can be an efficient option for rural electrification worldwide. Nonetheless, a large share of MG fail after a few years and inadequate sizing has been identified as a major risk. Academia, public authorities and funding agencies tend to consider the sizing of mini-grids mostly from a technical and economic angle, looking to optimize performance for MG developers and operators with tools such as HOMER. This paper proposes a different approach. We study the strategies adopted by different MG stakeholders to deal with their own uncertainties and constraints in the sizing process. Based on field work in Kenya, we detail how MG funders and regulators transfer risks to private MG developers and operators. As a result, the latter face risks regarding demand estimation, funding and regulatory aspects when sizing MGs. In turn, they adapt their methods and business models, sometimes transferring risks to end users. While flexible sizing might be a solution, we show that regulatory and funding issues limit MG modularity, leading low-income customers to eventually bear the consequences of ill-suited sizing.

The Benin energy sector faces serious challenges, including an unfavorable energy mix with regular power shortages, erratic power outages, reliance on electricity imports, and dependence on traditional cooking stoves. This study has investigated strategies critical for Benin to employ to achieve 24.6 %, 44 %, and 100 % renewable energy (RE) integration targets in the final electricity mix in 2025, 2030, and 2050, respectively. This study used the EnergyPLAN model to develop different energy scenarios suitable for Benin to achieve its proposed RE penetration target. A combination of natural gas (NG) with solar photovoltaic (PV), wind energy, hydropower, and concentrated solar power (CSP) is used to develop three scenarios for RE integration namely the government targets scenario, 2 % RE per year scenario and 50 % RE in 2050 scenario. The results show that the government targets scenario is too ambitious because of the current trend and pace of developing the energy sector. Moreover, a combination of 563 MW of NG, 125 MW of PV, 200 MW of wind, 600 MW of hydropower, and 60 MW of CSP would achieve 50 % RE by 2050 under the 50 % RE scenario. This scenario would decrease CO2 emissions by 50 % with no CEEP generation. Furthermore, the total electricity generation from MSW in Benin is estimated to be 0.232, 0.3215, and 1.16 TWh/yr in 2025, 2030, and 2050, respectively. The study's findings could help decision-makers and stakeholders make informed decisions to promote the integration of RE resources in the Benin Republic.

The transition from fossil fuels to carbon-neutral energy sources is necessary to reduce greenhouse gas (GHG) emissions and combat climate change. Hydrogen (H2) provides a promising path to harness fossil fuels to reduce emissions in sectors such as transportation. However, regional economic analyses of various H2 production techniques are still lacking. We selected a well-known fossil fuel-exporting region, the USA's Intermountain-West (I-WEST), to analyze the carbon intensity of H2 production and demonstrate regional tradeoffs. Currently, 78 % of global H2 production comes from natural gas and coal. Therefore, we considered steam methane reforming (SMR), surface coal gasification (SCG) and underground coal gasification (UCG) as H2 production methods in this work. We developed the cost estimation frameworks of SMR, SCG and UCG with and without carbon capture, utilization and sequestration (CCUS). In addition, we identified optimal sites for H2 hubs by considering the proximity to energy sources, energy markets, storage sites and CO2 sequestration sites. We included new production tax credits (PTCs) in the cost estimation to quantify the economic benefit of CCUS. Our results suggest that the UCG has the lowest levelized cost of H2 production due to the elimination of coal production cost. H2 production using the SMR process with 99 % carbon capture is profitable when the PTCs are considered. We also analyzed carbon utilization opportunities where CO2 conversion to formic acid is a promising profitable option. This work quantifies the potential of H2 production from fossil fuels in the I-WEST region, a key parameter for designing energy transition pathways.