Rural America sits at the center of a profound energy paradox: communities with some of the nation's richest renewable resources continue to face persistent energy insecurity, economic vulnerability, and deepening social divides. This Perspective argues that these challenges stem less from technological limitations than from governance structures that sideline local agency. Drawing on insights from a diverse landscape of community-driven solar, wind, biomass, and cooperative initiatives across the United States, we contend that the trajectory of rural energy transitions is profoundly shaped by who owns, controls, and benefits from emerging energy systems. While distributed renewables can reduce fuel dependence, lower household costs, and strengthen local resilience, these gains remain uneven and frequently undermined by top-down decision-making, siting conflicts, and weak participatory processes. Evidence from rural projects shows that Energy Democracy, anchored in the pillars of participation, ownership, equity, and sustainability offers a more durable pathway to rural revitalization than technology deployment alone. We outline why current policy frameworks fall short of supporting democratic energy governance and propose a forward-looking roadmap that centers community authority, anticipates conflict, and aligns socio-technical design with rural priorities. Reframing rural energy transitions around governance rather than hardware is essential for realizing the promise of equitable, resilient, and community-led rural futures.
community ownershipenergy democracyjust transitionparticipatory governancerural resiliencesocio-technical systemsThe author(s) declared that financial support was received for this work and/or its publication. This publication has emanated from research supported by a grant from Science Foundation Ireland under Grant number 12/RC/2289-P2 at Insight, the SFI Research Centre for Data Analytics at UCC, which is co-funded under the European Regional Development Fund.section-at-acceptancePolicy and Environmental ImpactIntroduction
Rural America faces a persistent energy paradox: regions with abundant renewable resources continue to experience high energy insecurity, volatile fuel prices, and unreliable service. Long-standing dependence on fossil fuels exposes households to economic instability and environmental risks (Chen, 2023; Perera, 2017; Jorli et al., 2018). Aging, fragmented infrastructure further increases costs for grid extension and modernization in remote areas (Gkalonaki and Karatzas, 2022; Siemiński et al., 2021). As transportation costs rise and extraction becomes more difficult, rural residents remain disproportionately vulnerable to price shocks and supply disruptions (Sadaghiani et al., 2023; Adua and Beaird, 2018). These pressures intensify as climate change accelerates and environmental burdens accumulate in coal-dependent regions (Moore et al., 2017; Radosits et al., 2024).
Renewable energy is often framed as a solution. Solar, wind, and biomass systems can reduce emissions, stabilize supply, and support rural economic development through job creation and cost savings (Singla et al., 2023; Souza et al., 2024). These benefits align with global sustainability goals emphasizing clean and affordable energy access (Liu et al., 2023; Koengkan et al., 2020). Yet many rural communities encounter conflict when projects are deployed through top-down, developer-driven models. Utility-scale solar can trigger concerns about farmland conversion, while wind projects often face resistance due to landscape and visual impacts (Franco and Piccoli, 2021; Ferreira et al., 2019). These tensions reveal that technological potential alone does not determine project success. While regional policy environments, financial capacity, and market maturity set the stage for development, our analysis suggests that governance structures frequently determine whether these projects face local acceptance or resistance.
Projects that meaningfully involve residents in planning and decision-making build trust, strengthen local capacity, and generate more durable benefits (Aslami, 2023; McGovern and Klenke, 2018). Cooperative and municipal ownership models often achieve higher acceptance and stronger long-term performance (Zheng et al., 2024; Gajdzik et al., 2024). Conversely, communities with histories of environmental harm or extractive industry dominance frequently approach new developments with skepticism, even when they are community-driven (Perera, 2017). Cultural values and local governance norms further shape how residents interpret risks and benefits (Blanchet, 2015; Klepacki et al., 2021; Veelen and Haggett, 2016).
This Perspective argues that the central challenge of rural energy transitions is not technological deployment but the distribution of decision-making power. The Energy Democracy framework clarifies why similar technologies generate divergent outcomes by emphasizing community ownership, participatory governance, and equitable access (Becker and Naumann, 2017; Campos et al., 2020). A narrative synthesis of more than fifty community-driven initiatives across the United States reinforces this point: rural revitalization emerges most reliably when communities control the terms of their own energy transitions (Morrison and Ramsey, 2019; Hart and Breitner, 2022; Janhunen et al., 2017).
The remainder of this Perspective advances three arguments. First, rural transitions falter when governance structures overlook local agency. Second, socio-technical fit, how technologies align with local economies, landscapes, and institutions determines whether projects generate benefits or backlash. Third, policy frameworks must shift from incentivizing megawatts to empowering communities. Reframing rural energy transitions around governance rather than hardware is essential for achieving equitable, resilient, and community-anchored rural futures.
This governance-centered perspective also challenges the assumption that community involvement slows climate action. Evidence suggests the opposite: while engagement may lengthen early planning, it reduces long-term delays caused by litigation, siting disputes, and social resistance. Projects that invest early in democratic governance move more smoothly through permitting and face fewer appeals. In practice, “slow is smooth, and smooth becomes fast.” Democratic governance is therefore not a barrier to speed but a prerequisite for avoiding the costly slowdowns associated with top-down development.
The state of rural transitions: what the evidence really shows
Rural energy transitions across the United States reveal a consistent pattern: renewable technologies succeed only when governance structures enable communities to shape, own, and benefit from them. To evaluate these dynamics, we conducted a narrative synthesis of over fifty community-driven energy initiatives across the United States, identified through a review of academic and gray literature on projects active between 2015 and 2024. While our primary analysis focuses on the U.S. context, we draw selectively on international literature to illustrate the broader applicability of the Energy Democracy framework. These global examples serve not as direct comparisons but as contextual evidence that the relationship between local governance and project acceptance is a fundamental socio-technical dynamic, not merely a U.S. phenomenon. Evidence from solar, wind, biomass, and cooperative initiatives shows that economic gains, social acceptance, and environmental improvements emerge not from hardware alone but from institutional arrangements that support local agency.
Local ownership drives economic multipliers
Economic benefits are strongest in projects where communities exercise ownership or governance authority. Cooperative and municipal models reinvest revenue locally, generating broader spillovers than developer-led projects (Franco and Piccoli, 2021; Gajdzik et al., 2024). Solar and biomass initiatives often reduce household energy costs and strengthen rural energy security (Chen, 2023; Gkalonaki and Karatzas, 2022; Moore, 2024). Job creation follows similar patterns: employment grows when communities participate directly in governance (Tzanes et al., 2024; Singla et al., 2023; Souza et al., 2024). Externally controlled projects, by contrast, produce limited or short-term employment, underscoring the importance of community ownership structures rather than technology alone (Acharya and Cave, 2020).
Governance determines social acceptance
Social acceptance consistently shapes project outcomes. Initiatives that embed participation through public meetings, cooperative membership, or advisory committees report higher trust and long-term support (Aslami, 2023; Janhunen et al., 2017). These structures allow residents to influence siting and negotiate benefits. Wind projects illustrate the consequences of weak governance: despite generating tax revenue, many face resistance due to landscape and noise concerns (Nuortimo et al., 2018). Utility-scale solar encounters similar tensions when farmland is displaced (Franco and Piccoli, 2021). Conflict arises not from the technologies themselves but from governance arrangements that marginalize local voices. Historical legacies of environmental harm deepen skepticism (Perera, 2017). Cultural values and governance norms further shape perceptions, reinforcing the need for participatory processes that reflect rural identities (Blanchet, 2015; Klepacki et al., 2021; Veelen and Haggett, 2016).
Socio-technical fit shapes project performance
Technologies interact with rural economies and landscapes in distinct ways, making socio-technical fit essential. Solar's modularity enables deployment in communities with limited technical capacity (Ranganathan et al., 2023; Zhang, 2024; Liu et al., 2023), though large-scale installations can trigger land-use conflict (Franco and Piccoli, 2021). Wind projects deliver strong environmental benefits but require transmission infrastructure often lacking in rural regions (Thao and Uchida, 2017). Biomass aligns with agricultural economies but depends on reliable feedstock and logistics (Radosits et al., 2024; Malik et al., 2024). Socio-technical fit is clearest in dual-use models such as agrivoltaics, which integrate energy production with farming. These examples show that technology-place alignment is critical and that transitions falter when technologies are deployed without regard for local capacity or resource conditions (Lu et al., 2019).
Governance capacity enables long-term resilience
Local governance capacity is central to sustaining rural transitions. Institutions such as cooperatives, municipal utilities, and energy committees enable communities to manage operations, distribute benefits, and maintain long-term stability (Zheng et al., 2024; McGovern and Klenke, 2018). They also provide platforms for conflict resolution and adaptive management, functions especially important in rural contexts where social cohesion shapes project trajectories. Projects with weak governance capacity or external control face greater delays, conflict, and uneven benefits, highlighting the importance of institutional strength (Castilla et al., 2024).
Synthesis: technology does not drive rural revival, governance does
Across rural America, technology alone does not drive rural revival; governance frames the outcome. Technologies can reduce emissions, lower costs, and create jobs, but these benefits materialize only when communities guide development, negotiate trade-offs, and retain value locally (Chen, 2023; Singla et al., 2023; Moore, 2024). Solar, wind, biomass, and cooperative models offer distinct opportunities, yet their success depends on alignment with governance structures, cultural values, and socio-technical conditions (Lu et al., 2019). Evidence consistently shows that community capability and participatory governance rather than hardware determine whether rural transitions generate durable benefits (Aslami, 2023; Zheng et al., 2024).
The energy democracy imperative
Rural energy transitions demonstrate that technology alone cannot deliver equitable or durable outcomes. As illustrated in Figure 1, Energy Democracy reframes rural energy projects as civic institutions grounded in participatory decision-making, local ownership, social equity, and sustainability. Figure 1 demonstrates the functional relationship between governance and resilience. The pillars of participation and ownership function not merely as values but as operational mechanisms that reduce transaction costs (conflict) and increase economic retention. These pillars consistently determine whether renewable energy strengthens or destabilizes rural communities. Projects that embed community authority through cooperatives, municipal utilities, or structured participation achieve higher acceptance and more durable benefits (Aslami, 2023), while developer-led models that limit local input often encounter resistance (Castilla et al., 2024).
The four pillars of Energy Democracy. This conceptual framework illustrates how governance principles (foundation) support specific operational pillars (Center) to achieve the ultimate goal of rural resilience (Top), shifting the focus from technical deployment to institutional capacity.
Diagram illustrating how four pillars—participatory decision-making, local ownership, social equity, and sustainability—underpin energy democracy governance architecture, which collectively supports rural resilience, revitalized economies, and reduced conflict.
Public meetings and informational sessions rarely translate into meaningful influence. Evidence from community-driven initiatives shows that participation without authority does little to build trust or legitimacy. Cooperative models demonstrate that when residents hold ownership stakes or voting rights, they are more likely to support projects and reinvest benefits locally (Zheng et al., 2024; Gajdzik et al., 2024). Historical legacies of environmental harm deepen skepticism toward externally controlled projects (Perera, 2017). Energy Democracy addresses this distrust by embedding accountability mechanisms into governance structures, ensuring communities shape rather than merely respond to energy development (Aslami, 2023; McGovern and Klenke, 2018).
Ownership as the foundation of rural revitalization
Ownership remains one of the strongest predictors of positive outcomes. Locally or cooperatively owned projects generate stable revenue, create longer-term employment, and reinvest profits into community services (Franco and Piccoli, 2021; Gajdzik et al., 2024). Distributed ownership reduces dependence on external developers and volatile fuel markets (Chen, 2023; Gkalonaki and Karatzas, 2022; Moore, 2024). When communities control energy assets, they retain authority over pricing, siting, and benefit distribution, aligning projects with agricultural preservation, cultural values, and long-term planning. Ownership thus functions as a governance tool that anchors transitions in local identity and agency (Zheng et al., 2024; McGovern and Klenke, 2018).
Governance as the missing variable in technology-centered policy
Current policy frameworks prioritize megawatts deployed rather than the governance structures needed for equitable transitions. Incentives for solar and wind development typically reward scale and speed, favoring large developers over community-led initiatives (Othman and Khallaf, 2022). This approach overlooks rural socio-technical realities, where land-use concerns, cultural values, and institutional capacity strongly shape outcomes (Franco and Piccoli, 2021; Campos et al., 2020). Energy Democracy reframes policy by treating governance as infrastructure, arguing that participatory institutions and benefit-sharing mechanisms are as essential as transmission lines. Without these components, communities experience renewable energy as externally imposed, fueling resistance (Hart and Breitner, 2022; Seetharaman et al., 2019; Morrison and Ramsey, 2019).
Aligning socio-technical fit with community priorities
Technologies interact with rural contexts in distinct ways. Solar's modularity supports distributed ownership, while wind's visual prominence and infrastructure requirements demand robust participatory processes (Franco and Piccoli, 2021; Nuortimo et al., 2018). Biomass thrives where agricultural partnerships are strong but falters when feedstock supply chains are weak (Radosits et al., 2024; Malik et al., 2024). Energy Democracy provides a framework for aligning technology design with local governance capacity, resource availability, and cultural values. Rather than treating rural communities as deployment sites, it positions them as co-designers of socio-technical systems (Blanchet, 2015; Campos et al., 2020).
The imperative moving forward
Energy Democracy is a practical necessity for reducing conflict, strengthening local economies, and building long-term resilience (Aslami, 2023; Zheng et al., 2024; McGovern and Klenke, 2018). As the United States accelerates its transition toward cleaner energy systems, rural communities will play a decisive role, making it essential that transitions are equitable, durable, and locally grounded. Achieving this requires shifting from technology-first approaches toward governance models that distribute power, ownership, and benefits more fairly (Morrison and Ramsey, 2019; Hart and Breitner, 2022; Campos et al., 2020). Evidence from rural America demonstrates that governance-centered transitions are both urgently needed and achievable (Becker and Naumann, 2017; Gajdzik et al., 2024). The central challenge is embedding locally anchored decision-making into policy so communities can build the participatory institutions and ownership models required for long-term resilience.
Implementation challenges and trade-offs
Implementing democratic governance in rural energy systems faces persistent constraints, including limited administrative capacity and fiscal resources that hinder effective project management (Shayan et al., 2022). Local control also does not guarantee equity; without well designed participatory structures, initiatives risk capture by local elites and the reproduction of existing power asymmetries (Berthod et al., 2022; Gonda, 2025). Participatory processes can slow early planning, trading deployment speed for legitimacy and durable community support (Veelen and Eadson, 2020). Robust capacity building is therefore essential to prevent exclusion and ensure energy democracy delivers genuine empowerment rather than reinforcing structural inequities (Opoku-Mensah et al., 2024).
A policy roadmap for rural energy resilience
Evidence from rural renewable energy initiatives shows that policy rather than technology is the decisive factor shaping whether communities experience revitalization or conflict. Current frameworks reward rapid deployment of solar, wind, and biomass systems but rarely address the governance structures that determine who benefits. As a result, many rural communities encounter top-down development models that marginalize local voices and weaken long-term support (Othman and Khallaf, 2022). A governance-centered policy architecture is therefore essential for ensuring that rural transitions are equitable, durable, and aligned with community priorities.
While Energy Democracy provides the principles for community-anchored governance, these principles cannot operate within a regulatory vacuum. Rural projects face structural bottlenecks, including inconsistent permitting, limited capital access, land-use conflict, and grid constraints that prevent community-driven initiatives from scaling. As illustrated in Figure 2, these barriers can be directly addressed through targeted interventions that strengthen local authority, stabilize supply chains, and modernize infrastructure (Franco and Piccoli, 2021; Campos et al., 2020). As detailed in Figure 2, the policy roadmap targets specific friction points. For instance, “Smart Zoning” is proposed specifically to mitigate the land-use conflicts identified in the “Barriers” column, essentially translating a social friction into a regulatory standard.
From barriers to resilience: a policy roadmap for rural revival. This diagram maps seven primary obstacles we identified (Left) to specific, actionable policy interventions (Center) required to achieve a durable rural energy transition (Right).
Infographic showing current barriers on the left, policy interventions in the center, and a resilient rural future on the right. Barriers include governance, trust, variability, land-use, financing, interconnection, and permitting. Corresponding interventions are energy democracy, participatory planning, supply chain stability, smart zoning, financial support, grid modernization, and regulatory reform, all leading to an equitable, durable, and locally grounded resilient rural future.
A first priority is shifting from technology-centered incentives to governance-centered incentives. Federal and state programs typically emphasize megawatts installed through tax credits and procurement mandates, but these mechanisms do little to support community ownership or participatory governance. Evidence from cooperative and municipal projects shows that local control produces more stable revenue, stronger reinvestment in community services, and more durable institutional capacity (Franco and Piccoli, 2021; Zheng et al., 2024; Gajdzik et al., 2024). Policies that reward community ownership, require meaningful participation, and provide technical assistance for rural governance development would help ensure that economic benefits remain local and that communities have the institutional tools to manage energy systems over time (Ehiaguina et al., 2023).
Reforming siting and permitting processes is equally critical. Many rural conflicts arise not from the technologies themselves but from the perception that decisions are imposed without local input. Wind projects often face resistance due to concerns about landscape change and noise, while utility-scale solar developments can trigger tensions over farmland conversion (Nuortimo et al., 2018; Franco and Piccoli, 2021). These conflicts are especially acute in regions with histories of environmental harm, where trust in external developers is already low (Perera, 2017). Embedding local authority into siting decisions through early-stage consultation, rural siting councils, and binding benefit-sharing agreements ensures that projects reflect community priorities and reduces long-term opposition.
Financing remains a major barrier for rural communities, which often lack access to low-cost capital. Policies that expand loan guarantees, provide low-interest financing, and support cooperative or municipal ownership models can help overcome high upfront costs. Similarly, supply chain stability particularly for biomass feedstocks requires long-term contracts and regional coordination to ensure reliable inputs and predictable revenue (Radosits et al., 2024; Malik et al., 2024). Grid constraints also limit rural energy development. Many regions lack the transmission capacity or interconnection processes needed to integrate new renewable projects. Clearer standards, dedicated rural support programs, and targeted grid modernization efforts would reduce delays and expand opportunities for community-led generation.
Finally, regulatory reform is needed to streamline permitting and provide rural-specific guidance. Lengthy, inconsistent processes disproportionately burden small communities and favor large developers with greater administrative capacity. Simplified permitting pathways, standardized requirements, and technical assistance programs would help level the playing field and enable rural communities to pursue locally grounded energy strategies. Together, these interventions form a coherent policy roadmap that moves beyond technology deployment toward governance structures capable of supporting equitable, resilient rural energy futures.
Conclusion
Rural America stands at a pivotal moment. The communities most affected by volatile fuel prices, aging infrastructure, and environmental burdens are also those best positioned to lead the nation's clean energy transition. Yet the evidence from a diverse landscape of community-driven initiatives shows that technological deployment alone cannot deliver the resilience, equity, or economic revitalization rural regions urgently need. What determines success is governance, specifically, whether communities have the authority to shape energy development, retain ownership, and distribute benefits on their own terms.
This Perspective has argued that Energy Democracy provides the most coherent and actionable framework for addressing these governance challenges. Our primary scholarly contribution is to operationalize this framework, moving the debate beyond normative advocacy to demonstrate that democratic governance is a functional prerequisite for the technical and economic success of rural transitions. Its principles, local ownership, participatory decision-making, and equitable access align closely with the empirical patterns observed across solar, wind, biomass, and cooperative projects. Where these principles are embedded, communities experience stronger economic multipliers, higher social acceptance, and more durable institutional capacity. Where they are absent, conflict, mistrust, and uneven benefits persist, even when technologies perform well.
The path forward requires a fundamental reorientation of policy. Incentives must reward governance structures, not just installed capacity. Siting and permitting must elevate local agency rather than treat it as an obstacle. Infrastructure investment must prioritize rural transmission and interconnection needs, and equity must be treated as a core design principle rather than an afterthought. Treating governance as infrastructure, something to be built, funded, and maintained, is essential for ensuring that rural communities remain active stewards of their energy futures.
To validate these connections, future research should prioritize longitudinal comparative studies that measure specific outcomes, such as permitting duration, litigation rates, and local economic retention, across different governance models. Empirical quantification of these “governance dividends” will be critical for moving the field from conceptual framing to evidence-based policy design.
Rural revival will not emerge from hardware alone. It will emerge from institutions that empower communities to direct their own transitions, negotiate trade-offs, and capture long-term value. Centering Energy Democracy provides the governance foundation for this shift, enabling policymakers, practitioners, and rural leaders to build energy systems that are not only cleaner and more resilient, but also more just, more trusted, and more deeply rooted in the places they serve. The opportunity is unmistakable: a rural energy future defined not by extraction or imposition, but by agency, ownership, and collective possibility.
Data availability statement
The original contributions presented in the study are included in the article/supplementary material, further inquiries can be directed to the corresponding author.
L. M. Ayompe acknowledges Dr. B. N. Egoh for her mentorship and guidance.
Conflict of interest
The author(s) declared that this work was conducted in the absence of any commercial or financial relationships that could be construed as a potential conflict of interest.
Generative AI statement
The author(s) declared that generative AI was not used in the creation of this manuscript.
Any alternative text (alt text) provided alongside figures in this article has been generated by Frontiers with the support of artificial intelligence and reasonable efforts have been made to ensure accuracy, including review by the authors wherever possible. If you identify any issues, please contact us.
Publisher's note
All claims expressed in this article are solely those of the authors and do not necessarily represent those of their affiliated organizations, or those of the publisher, the editors and the reviewers. Any product that may be evaluated in this article, or claim that may be made by its manufacturer, is not guaranteed or endorsed by the publisher.
ReferencesAcharyaB.CaveJ. (2020). Analyzing community initiatives in UK's energy transition through the lens of sustainable entrepreneurship. Energy Environ. Res.10:13. doi: 10.5539/eer.v10n2p13AduaL.BeairdA. (2018). Place-based inequality in “energetic” pain: the price of residence in rural America. Socius4:3032. doi: 10.1177/2378023118803032AslamiM. (2023). Key role of construction industry in achieving the goal of sustainable energy worldwide. E3S Web Conf.457:02061. doi: 10.1051/e3sconf/202345702061BeckerS.NaumannM. (2017). Energy democracy: mapping the debate on energy alternatives. Geogr. Compass11:12321. doi: 10.1111/gec3.12321BerthodO.BlanchetT.BuschH.KunzeC.NoldenC.WenderlichM. (2022). The rise and fall of energy democracy: 5 cases of collaborative governance in energy systems. Environ. Manag.71, 551–564. doi: 10.1007/s00267-022-01687-835906345BlanchetT. (2015). Struggle over energy transition in Berlin: how do grassroots initiatives affect local energy policy-making?Energy Policy78, 246–254. doi: 10.1016/j.enpol.2014.11.001CamposI.LuzG.Marín-GonzálezE.GährsS.HallS.HolstenkampL. (2020). Regulatory challenges and opportunities for collective renewable energy prosumers in the EU. Energy Policy138:111212. doi: 10.1016/j.enpol.2019.111212CastillaD.DuranoK.MegabonM.VillanuevaA.YusonS. (2024). Analytical hierarchal process of environmental ethics decision making for environmental sustainability. Int. J. Sci. Res. Arch.12, 2081–2091. doi: 10.30574/ijsra.2024.12.1.0982ChenS. (2023). Multiple stock prediction based on linear and non-linear machine learning regression methods. Adv. Econ. Manag. Polit. Sci.46, 225–232. doi: 10.54254/2754-1169/46/20230343EhiaguinaV.IzukaU.Ninduwezuor-EhiobuN.TulaO.BakareA. (2023). Advancing solar integration in security and alarm systems: a review of innovations and challenge. Eng. Sci. Technol. J.4, 222–234. doi: 10.51594/estj.v4i4.584FerreiraP.LimaF.RibeiroF.VieiraF. (2019). A mixed-method approach for the assessment of local community perception towards wind farms. Sust. Energy Technol. Assess.33, 44–52. doi: 10.1016/j.seta.2019.02.004FrancoW.PiccoliM. (2021). “Intermediate agricultural machines energy efficiency: the example of harvesting and threshing,” in Advances in Italian Mechanism Science, eds. V. Niola and A. Gasparetto (Cham: Springer), 1–8. doi: 10.1007/978-3-030-55807-9_60GajdzikB.JaciowM.WolniakR.WolnyR.GrebskiW. (2024). Diagnosis of the development of energy cooperatives in Poland. Energies17:647. doi: 10.3390/en17030647GkalonakiS.KaratzasK. (2022). Assessing the environmental impacts of renewable energy sources with emphasis on wind energy. IOP Conf. Ser.: Earth Environ. Sci.1123:012053. doi: 10.1088/1755-1315/1123/1/012053GondaN. (2025). Democratizing energy justice: rethinking energy justice in authoritarian times. Progress Environ. Geogr.4, 208–229. doi: 10.1177/27539687251342264HartM.BreitnerM. (2022). Fostering energy resilience in the rural Thai power system—a case study in Nakhon Phanom. Energies15:7374. doi: 10.3390/en15197374JanhunenS.HujalaM.PätäriS. (2017). The acceptability of wind farms: the impact of public participation. J. Environ. Policy Plann.20, 214–235. doi: 10.1080/1523908X.2017.1398638JorliM.PasselS.SaghdelH. (2018). External costs from fossil electricity generation: a review of the applied impact pathway approach. Energy Environ.29, 635–648. doi: 10.1177/0958305X18761616KlepackiB.KustoB.BórawskiP.Bełdycka-BórawskaA.MichalskiK.PerkowskaA.. (2021). Investments in renewable energy sources in basic units of local government in rural areas. Energies14:3170. doi: 10.3390/en14113170KoengkanM.PovedaY. E.FuinhasJ. A. (2020). Globalisation as a motor of renewable energy development in Latin America countries. Geojournal85, 1591–1602. doi: 10.1007/s10708-019-10042-0LiuK.YamadaH.IwatsukiK.OtsujiT. (2023). Experimental verification and simulation analysis of a battery directly connected DC microgrid system. Int. J. Electr. Electr. Eng. Telecommun.12, 326–333. doi: 10.18178/ijeetc.12.5.326-333LuJ.RenL.YaoS.RongD.SkareM.StreimikisJ. (2019). Renewable energy barriers and coping strategies: evidence from the Baltic States. Sust. Dev.28, 352–367. doi: 10.1002/sd.2030MalikK.CaparedaS.KambojB.ShwetaS.SinghK.AryaS.. (2024). Biofuels production: a review on sustainable alternatives to traditional fuels and energy sources. Fuels5, 157–175. doi: 10.3390/fuels5020010McGovernG.KlenkeT. (2018). A process approach to mainstreaming civic energy. Energies11:2914. doi: 10.3390/en11112914MooreC. (2024). Renewable energy adoption and its effect on rural development in the United States. J. Dev. Country Stud.8, 15–31. doi: 10.47604/jdcs.2674MooreJ.AkinyemijuT.WangH. (2017). Pollution and regional variations of lung cancer mortality in the United States. Cancer Epidemiol.49, 118–127. doi: 10.1016/j.canep.2017.05.01328601785MorrisonC.RamseyE. (2019). Power to the people: developing networks through rural community energy schemes. J. Rural Stud.70, 169–178. doi: 10.1016/j.jrurstud.2018.07.006NuortimoK.HärkönenJ.KarvonenE. (2018). Linking the public acceptance of wind power to technology deployment. Interdiscip. Environ. Rev.19, 219–242. doi: 10.1504/IER.2018.095727Opoku-MensahE.ChenW.TuffourP.AgozieD.GyamfiB.MahmoudA. (2024). Toward sustainable energy transition: unveiling the synergies of democracy, energy justice, and structural adjustment on emissions in West Africa. Sust. Dev.33, 379–398. doi: 10.1002/sd.3119OthmanK.KhallafR. (2022). Identification of the barriers and key success factors for renewable energy public private partnership projects: a continental analysis. Buildings12:1511. doi: 10.3390/buildings12101511PereraF. (2017). Pollution from fossil-fuel combustion is the leading environmental threat to global pediatric health and equity: solutions exist. Int. J. Environ. Res/ Public Health15:16. doi: 10.3390/ijerph1501001629295510RadositsF.AjanovićA.HarasekM. (2024). The relevance of biomass based gases as energy carriers: a review. Wiley Interdiscipl. Rev.: Energy Environ.13:e527. doi: 10.1002/wene.527RanganathanR.SubbaramS.IndiraG. N, ATharmarS. (2023). A comparative study of renewable energy sources for power generation in rural areas. E3S Web Conf.387:05011. doi: 10.1051/e3sconf/202338705011SadaghianiS.MafakheriF.ChenD. (2023). Life cycle assessment of bioenergy production using wood pellets: a case study of remote communities in Canada. Energies16:5697. doi: 10.3390/en16155697SeetharamanP.MoorthyK.PatwaN.Saravanan GuptaY. (2019). Breaking barriers in deployment of renewable energy. Heliyon5:e01166. doi: 10.1016/j.heliyon.2019.e0116630723834ShayanM.HayatiM.NajafiG.ShayanS. (2022). The strategy of energy democracy and sustainable development: policymakers and instruments. Iran. J. Energy Environ.13, 185–201. doi: 10.5829/IJEE.2022.13.02.10SiemińskiP.HadyńskiJ.LiraJ.RosaA. (2021). Regional diversification of electricity consumption in rural areas of Poland. Energies14:8532. doi: 10.3390/en14248532SinglaM.GuptaJ.AlsharifM.JahidA. (2023). Optimizing integration of fuel cell technology in renewable energy-based microgrids for sustainable and cost-effective energy. Energies16:4482. doi: 10.3390/en16114482SouzaR.González QuiñónezL.Reyna TenorioL.Salgado OrtizP.Chere QuiñónezB. (2024). Renewable energy development and employment in Ecuador's rural sector: an economic impact analysis. Int. J. Energy Econ. Policy14, 464–479. doi: 10.32479/ijeep.15297ThaoN.UchidaK. (2017). A two level control strategy with fuzzy logic for large scale photovoltaic farms to support grid frequency regulation. Control Eng. Pract.59, 77–99. doi: 10.1016/j.conengprac.2016.11.006TzanesG.ZafirakisD.KaldellisJ. (2024). Practice of a load shifting algorithm for enhancing community-scale RES utilization in an island context. Sustainability16:5679. doi: 10.20944/preprints202401.1936.v1VeelenB.EadsonW. (2020). Assembling community energy democracies. Volunt. Sect. Rev.11, 231–249. doi: 10.1332/204080519X15740562779512VeelenB.HaggettC. (2016). Uncommon ground: the role of different place attachments in explaining community renewable energy projects. Sociol. Ruralis57, 533–554. doi: 10.1111/soru.12128ZhangD. (2024). Recent advances in smart grid architecture and grid–electric vehicle charging station interaction. J. Phys.: Conf. Ser.2786:012017. doi: 10.1088/1742-6596/2786/1/012017ZhengJ.HeW.DengK.ChengN.ShengT.ZhangL.. (2024). Zero carbon innovative torch design based on ammonia combustion technology. Front. Artif. Intell. Applic.391, 288–297. doi: 10.3233/FAIA241114
Edited by: Festus Adedoyin, Bournemouth University, United Kingdom
Reviewed by: Varun Kumar Singh, Tula's Institute, India