Community solar is an innovative new investment model that can provide Americans with the many benefits of solar energy even if they cannot site a system on their own property because they are renters, have roofs that are shaded or in disrepair, or they are not able to finance a solar installation. These barriers are particularly prevalent in less affluent areas, making community solar a promising way to improve access to renewable energy in low-income neighborhoods. This Handbook is intended to help municipalities clearly define and articulate the project’s objectives and understand the financial, legal, and policy issues they would need to address to initiate community solar investments in their communities and convey the resulting benefits to their constituents. The Handbook identifies three obstacles to success — access to capital, expertise, and risk-allocation — and includes suggestions on how to overcome these obstacles, including the potential use of public funds to reduce the project’s cost and public-private partnerships. This study also includes ideas gleaned from other community solar projects that appear particularly interesting or innovative. In addition, it offers five possible deployment models municipalities could use to support, finance, or build a community solar project in their jurisdictions. There are no simple, one-size-fits-all, models for a successful community solar project. However, a municipality can be a catalyst and hub for development of the necessary expertise, and it has opportunities to help reduce project costs and risks that can open the door for successful projects.
Deployment of solar energy systems in the U.S. has grown rapidly over the past decade. Costs have dropped, and new ownership and financing models allow more Americans than ever to choose solar. Solar is now available as a power choice in all states. The solar industry is creating even more solutions that allow all consumers to produce their own electricity by going solar. Consumers who rent their homes, live in an apartment, do not have unshaded or otherwise well-oriented roof space, or may not qualify for a lease now have the ability to choose solar in an increasing number of states. Even for consumers who have the roof and property to install a solar system, community solar offers an alternative option for going solar. Some community solar projects allow subscribers to purchase or lease as little as one panel or a small fraction of the power generated from the project. Subscribers’ interest can also typically stay with them if they move to a new address within the same utility service territory. Community solar brings more choice to consumers interested in solar. Entering into a community solar agreement is a significant decision, similar to signing up for a cell phone, and consumers should understand the basics of solar energy, where community solar is available, key terms in agreements, and the right questions to ask solar professionals.
Solar power offers Long Islanders a host of benefits — reductions in greenhouse gases and air pollution, healthier communities, affordable access to renewable energy, and good paying jobs. Solar can also play a significant role in helping address the climate crisis and meeting the goals of New York’s Climate Leadership and Community Protection Act (CLCPA). This nation-leading 2019 law requires 70% of the state’s electricity to be generated from renewable resources by 2030 and 100% of electricity to be generated from carbon-free sources by 2040. Many people are familiar with residential rooftop solar systems, which range in size from 3 to 10 kilowatts (kW). Larger commercial and utility-scale solar systems, which can generate hundreds to thousands of kilowatts each, offer the opportunity to realize the benefits of solar power more quickly and cost-effectively in the region. This report shows how solar power can be scaled up without impacting the natural areas that are critical for wildlife, water-quality protection, and quality of life on Long Island. Low-impact sites like rooftops, parking lots, and other land already impacted by development, such as capped landfills and remediated brownfields, are excellent locations for the development of commercial- and utility-scale arrays. Building solar on low-impact sites minimizes impacts to natural ecosystems and habitat, reduces the potential for land-use conflicts and community opposition, decreases project cost and permitting times, and avoids the harmful release of carbon pollution that results from the conversion of natural areas for development. The Nature Conservancy and Defenders of Wildlife created the Long Island Solar Roadmap (the Roadmap) with the aim of advancing deployment of mid- to-large-scale solar power on Long Island in a way that minimizes environmental impacts, maximizes benefits to the region, and expands access to solar energy, including access to benefits by underserved communities. The Roadmap’s creation was supported by a diverse group of Long Island stakeholders. Individuals from state, local, and county government; the solar industry; the farm community; environmental and community organizations; the electric utility; businesses; and academic institutions provided input and guidance on design, research, and strategies. The Roadmap identifies low-impact sites for solar arrays on Long Island and shows their energy generation potential. Key findings also highlight Long Islanders’ opinions and preferences about solar development in their communities and provide information about the costs and benefits associated with bringing more solar online. It is our hope that the cohesive set of strategies and actions provided in this report will help lower barriers to low-impact solar development that meets the needs of all Long Island communities and benefits the whole region. Together, the key findings of the Roadmap point toward a promising future for Long Island as we transition to renewable energy. Taking full advantage of Long Island’s solar potential will require the commitment and collective action of a diverse group of stakeholders, including local and state government, Long Island Power Authority (LIPA), PSEG Long Island, the solar industry, commercial and industrial property owners, farmers and farmland owners, nonprofits, and community organizations.
Despite the mature and promising potential for solar photovoltaic (PV) technology to retrench global reliance on fossil fuels, large-scale PV development is experiencing complex challenges, including land use conflict and — as the scale of solar has increased — social resistance, which has previously been more commonly associated with large-scale wind farms. Growth in large-scale PV development can create land use disputes, especially in instances of competition between land for agriculture versus energy production. This history and growing concern over land use highlights the challenge of meeting the soaring demands for solar power while conserving rural and agricultural lands. It is posited that the impact of solar development on land will be diminished by siting PV in a manner that is compatible with multiple uses, suggesting changes in conventional practices will be necessary. The specific intent of this study was to draw insight about solar development from participant experience, and responses indicate that the most considerable opportunities and barriers center on social acceptance and public perception issues. Perspectives about the opportunities and barriers to agrivoltaic development were captured via interviews with solar industry professionals, and inductive analysis revealed that interviewees were most focused on opportunities and barriers that correspond with Wüstenhagen et al.’s three dimensions of social acceptance: market, community, and socio-political factors. The social acceptance of renewable energy is shaped by a complex interplay among market, community, and socio-political factors. While this framework is constructive for understanding the varying dimensions of social acceptance, Devine-Wright et al. assert that it is weak in terms of the relationships between dimensions, suggesting that further research should apply a holistic approach for discerning the interdependence among factors shaping social acceptance of renewable energy. The purpose of this study is therefore to explore the perceptions of industry professionals in the U.S. and consider the implications of the identified opportunities and barriers from a social science perspective. To address global demands for both food and energy, the relationship between critical land uses must become complementary rather than competitive. Because social acceptance of renewable energy technology is pivotal to energy transitions, this study reflects a proactive attempt to understand agrivoltaics from a solar industry professional’s perspective to better understand the significant opportunities and barriers to development. This research suggests that agrivoltaics are potentially accretive to the long-term growth of the solar industry, possessing the capacity to increase social acceptance of local solar developments. While the agrivoltaic concept is widely supported by the participants in this study, popularity of an emerging technology among industry experts may not indicate local level acceptance of a specific development. As new energy technologies such as agrivoltaics transcend niche applications to become more prevalent, localized resistance is to be anticipated and the dimensions of social acceptance, including the opportunities and barriers associated with each dimension, can help inform decision making to enhance the growth of agrivoltaic development.
Community solar programs (also called “shared solar”) offer the economic and environmental benefits of solar to the 49% of Americans without traditional solar access. Such programs are experiencing rapid growth, with active projects across 26 states, up from 6 states in 2010. This market has the potential to grow more than 50-fold from the 110 megawatt (MW) capacity in early 2016 to between 5,500 MW and 11,000 MW by 2020. Previously, it was often uneconomic to develop individual solar projects of less than 2 MW in capacity (2,000 kilowatts [kW]) if they were not tied directly to or net metered with a customer site. With community solar, projects between 50kW and 2,000 kW are often viable because numerous off-site subscribers can purchase shares of a solar installation rather than hosting the installation themselves. By bringing an enormous source of new demand into the market and offering new contracting arrangements to the 51% of Americans who already have potential solar access, community solar is expected to greatly expand the market for mid-sized solar projects. One strong but sometimes overlooked source of suitable sites for community solar are those covered by the U.S. Environmental Protection Agency (EPA) RE-Powering America’s Land Initiative. The RE-Powering Initiative provides data, tools, analysis, case studies, issue briefings, and outreach resources to encourage renewable energy development on contaminated lands, landfills, and mining sites (collectively “RE-Powering sites”). Community solar can overcome financing, contract flexibility, project size, and siting challenges that largely shut out LMI homes, apartments, and small businesses from the solar market, while offering added local economic development benefits if the community solar project itself is located in LMI areas. Because RE-Powering sites are frequently located in or near LMI areas, this paper will explore not only the general potential for developing RE-Powering sites for community solar, but also where siting adjacent to LMI areas extends their benefits. This market intersection is conceptually depicted in Figure 1. Within and outside LMI areas, this paper is intended to support sustainable re-use by characterizing the potential and pointing out the challenges and opportunities of community solar development on RE-Powering sites.
As solar energy continues to become more affordable, many families are expressing interest in this local, clean power source, but are unable to install a solar system at their homes for various reasons. In fact, due to structural constraints, shading from trees, and other issues, about 75% of residential rooftop area in America is not suitable for hosting a solar system. This prevents a large segment of the population from taking advantage of solar energy. The solution to this problem is Community Solar. Community Solar (aka Shared Solar) takes place through the development of solar energy projects that provide power to multiple community members. Community Solar systems are typically sited close to the community they will serve. These programs leverage economies of scale to reduce the price of solar for individual customers. This model allows Southerners to access the benefits of solar energy even if they would be unable to install solar panels on their own homes or businesses. Community Solar can be utility-sponsored (either a utility developing its own program or working with a solar company to offer a program), or it can be third party-sponsored in states that allow for competition. By offering well-designed Community Solar projects, utilities can give their customers meaningful access to affordable, local solar power and tangible control of their energy choices. By providing families more options to lower their energy costs and take advantage of the South’s vast solar resource, Community Solar can create healthier, cleaner, and stronger communities across the region. Community Solar programs also provide benefits for utilities by increasing customer satisfaction, bolstering clean energy investment, and contributing to local economic development. Utilities can take advantage of economies of scale by choosing the optimal system size and number of participants. They can also decide which location will offer the most value to the grid. Community Solar can be a win-win by providing tangible benefits to participating customers, strengthening local communities, and delivering valuable clean energy to the grid. We encourage utilities to adopt the following best practices when developing Community Solar programs to ensure that all customers receive meaningful access to solar power through this innovative program.
The concept of energy sovereignty redefines the priorities for decision making regarding energy systems while encouraging increased reliance on renewable energy technologies like solar. Energy sovereignty involves centering the inherent right of humans and communities to make decisions about the energy systems they use, including decisions about the sources, scales, and forms of ownership that structure energy access. Current U.S energy policy does not center concerns of energy sovereignty, and in many cases may work against it. Policies to enhance energy sovereignty can accelerate electricity decarbonization while also empowering community scale decision making and offering communities control to reduce the myriad externalities associated with the fossil-fuel energy system. Energy policy designed based on the concept of energy sovereignty would prioritize community voices in energy system decision making, ensuring that communities are given an opportunity to express their right to self-determined sovereignty in energy systems transitions and energy system use. Energy sovereignty is an inherently place-based practice, and policy tools that center energy sovereignty would enhance community capacity to plan for transitions while embracing considerations of the health and wellbeing of communities, both human and non-human, now and in the future. The policy tools most effective for enhancing energy sovereignty may not yet exist, but they are essential for promoting a just energy transition that benefits all communities based on their own understanding of energy transition priorities and values.
Driven by climate change and economics, energy generation is undergoing a necessary and rapid transformation towards non-emitting renewable energy, especially solar and wind. As the world decarbonizes, the energy grid will become distributed, characterized by increased local control and decreased transmission losses. The future grid also provides extensive energy security, local employment, and local risk reduction, if coupled with battery storage. Photovoltaics (PV), the direct production of electrical energy by photovoltaic cells, stand out as a key component in the required transition for social and economic reasons: scalability, safety, rapid deployment, longevity, reliability, resilience, and minimal emissions. In the last decade, the cost of solar has decreased precipitously and reached grid parity (costing the same or less than electricity from conventional sources) for most of the world in 2015. In 2019, unsubsidized residential solar was less expensive than most rates charged by utilities, while industrial solar-plus-storage produced electricity at rates that outcompeted all other means of electricity generation. Both residential and industrial solar have a miniscule carbon footprint, as compared with fossil fuels. Since globally 64% of electricity is generated through the combustion of fossil fuels, the potential to decarbonize through solar and wind is not only enormous, but is a societal imperative. Decarbonization of electrical generation becomes even more essential considering the adoption of heat pumps, electric vehicles, and other electrification initiatives. As shown by Jacobson et al. (2019), using just wind, water, and solar, almost complete decarbonization of energy is achievable before 2050. In this period of multiple crises, the UN’s Sustainable Development Goals (SDGs) offer a framework to understand and address global issues concurrently. The framework also ensures that tackling one goal does not incidentally hinder or reverse achievement of the others. Community owned solar, especially with added storage, contributes to climate change action, pollution reduction, and energy security, while reducing the relatively high energy burden for low income households. Before addressing avenues to and challenges of community solar, it is necessary to briefly summarize the many benefits of PV, separating societal benefits from benefits to an existing electrical grid. Given the stark reality of less than 10 years remaining to achieve the SDGs (United Nations 2015), community solar provides a readily available and economically viable solution to multiple SDGs. It targets the elusive middle ground in scale between residential and industrial solar and can deliver electricity competitively and at scale without requiring massive investment in supporting infrastructure. Most importantly, community solar provides more than just affordable and clean energy by democratizing the renewable energy transition. By giving power to the people, communities can utilize community solar programs in providing decent work, reducing inequalities, and increasing local resilience – while making a positive climate impact.
Community shared solar is a new and growing model for broadening local solar markets and extending the benefits of solar energy to new customers. By expanding access to solar energy, community shared solar can be a useful tool for San Francisco and other jurisdictions that seek to expand use of distributed, local solar power. To help educate stakeholders, including other Rooftop Solar Challenge partners and other cities, this paper discusses: (1) the basics of community shared solar; (2) the benefits of community shared solar; (3) variations in design of community shared solar programs; (4) examples of community shared solar program; (5) California’s regulatory context; and (6) community shared solar’s potential to expand San Francisco’s solar market. Community shared solar could also improve San Francisco’s solar market by enabling more San Francisco residents and businesses to invest in solar energy. The majority of San Francisco residents live in multi-family buildings, rent, or both: two-thirds of residential units are in multi-family buildings and 60% of San Francisco households rent. Community shared solar would allow renters and others who cannot install solar onsite to purchase solar energy for their home or business.
This guide is designed as a resource for those who want to develop community solar projects, from community organizers or solar energy advocates to government officials or utility managers. By exploring the range of incentives and policies while providing examples of operational community solar projects, this guide will help communities to plan and implement successful local energy projects. In addition, by highlighting some of the policy best practices, this guide suggests changes in the regulatory landscape that could significantly boost community solar installations across the country. The information in this guide is organized around three sponsorship models: utility-sponsored projects, projects sponsored by special purpose entities – businesses formed for the purpose of producing community solar power, and non-profit sponsored projects. The guide addresses issues common to all project models, as well as issues unique to each model. This guide focuses on projects designed to increase access to solar energy and to reduce up-front costs for participants. The secondary goals met by many Community Solar projects include: Improved economies of scale, Optimal project siting, Increased public understanding of solar energy, Generation of local jobs, Opportunity to test new models of marketing, project financing and service delivery.