Wind
William “Bud” Frabell
Solar
Jonathan Lwowski
Solar
Robert J. Munnelly, Jr.
The U.S. energy storage industry is at a crossroads of economic pressure, regulatory reform and rising energy demand. From tariffs and trade dynamics to the reshaping of material strategies and regulatory compliance, the trends shaping this year reflect a broader industry movement toward resilience, transparency and innovation. Stryten Energy offers a deeper look at what’s driving momentum for the industry’s supply chains in 2025:
Tariffs dominate the supply chain conversation. Recent trade actions have increased the cost of critical, imported materials and components, including those linked to lithium battery production. These increases are not limited to direct imports − they move through domestic suppliers who rely on foreign-sourced raw materials. This is pushing manufacturers to re-evaluate procurement strategies.
China’s bans and limits on exporting certain critical minerals are also causing disruption. In some cases, the nation is the sole supplier of certain materials.
The impact of these trade challenges will likely stay for years, so many companies are exploring onshoring and nearshoring options. Building a lithium cell plant, though, can often be a $300-$500 million investment, which is a significant hurdle for most companies. Large original equipment manufacturers (OEMs) and automakers circumvent the cost by partnering with large battery producers, some of which already have battery manufacturing capabilities onshore.
The cost barrier for onshoring and nearshoring remains a significant issue for the hundreds of small- or mid-sized battery providers in the U.S. To better afford domestic manufacturing investments, many companies may begin consolidating through partnerships, joint ventures, or mergers and acquisitions − a trend that stands to strengthen the entire supply chain over the long term.
The industry was already shifting from importing complete battery packs to assembling modules domestically, with ambitions to eventually localize cell manufacturing and even raw material sourcing. While this transition is both expensive and complex, the goal is to build a resilient domestic supply chain. Though this transformation will take years, many players across the energy storage industry are stepping up to lead the shift.
Energy resilience refers to the ability to recover from and withstand power disruptions. The U.S. electrical grid faces several challenges to reliably deliver a steady source of power to homes and businesses. The integration of more renewable energy sources intensifies pressure on U.S. grid operators to modernize their aging infrastructure. Brownouts and blackouts caused by extreme weather events, like heatwaves, winter storms and floods, are also becoming more frequent and increasing pressure on the grid.
These challenges underscore the urgent need for smarter integration of energy storage systems that can help stabilize the grids, provide backup power and support renewable integration. While lithium has been a leading energy storage material for years, its heavily concentrated global supply chain with China projected to control almost 70% of total capacity by 2030, has raised concerns about strategic reliability. Tariffs are also likely to raise the price of lithium batteries significantly, and a domestic supply chain is years away from being mature.
Therefore, expect to see manufacturers diversifying their battery energy storage system (BESS) technologies this year to provide an ample supply of different, reliable energy storage solutions. Diversification is a key defense against supply shocks and trade bottlenecks. Two alternatives to lithium for BESS systems are vanadium flow batteries (VFB) and lead BESS batteries.
VFBs, ideal for long-duration essential power applications, can support the deployment of clean energy from renewable sources like solar and wind. Energy storage manufacturers are fielding inquiries from data centers about the technology. A domestic supply chain is already being built to provide a reliable supply of this technology.
Advanced lead BESS is also a key technology, especially when domestically sourced materials are a priority. This technology is designed to safeguard against power outages when conventional sources fail. It can also function as a critical grid support tool, providing rapid response capabilities to mitigate fluctuations, stabilize voltage and enhance overall grid resilience. Lead BESS already has a well-established domestic supply chain and a complete circular economy, making it a sustainable and reliable energy storage option.
By diversifying battery chemistry supply this year, manufacturers can help ensure the grid can withstand whatever comes next.
We expect regulatory pressure to evolve in 2025. Governments are introducing policies to increase transparency, sustainability and security across many supply chains, including energy storage sourcing. Manufacturers must prepare for a future where traceability is not optional, but foundational to market access and success.
In the U.S., new Foreign Entity of Concern (FEOC) restrictions are now in place for manufacturers that supply the Department of Defense. Additionally, the clean energy tax credits available to domestic manufacturers in the recent passing of the One Big Beautiful Bill Act include FEOC provisions. To qualify for the tax credits, companies must ensure full supply chain transparency and provide detailed documentation of their ownership structure to comply with the new FEOC requirements.
Beginning in 2027, the European Union (EU) will require a Digital Battery Passport for electronic vehicles (EVs), along with industrial and light mobility batteries under Regulation (EU) 2023/1542. This regulation mandates a digital record, which will be accessible through a mechanism like a QR code, that documents a battery’s origin, composition, performance and recycling history throughout its lifecycle. Although U.S.-based companies are not directly subject to EU law, those serving European customers will be expected to comply, putting pressure on global manufacturers to adopt new tracking capabilities.
Additionally, the Critical Mineral Transparency and Reporting in Advanced Clean Energy (TRACE) Act, known to many as H.R. 8187, is a proposed U.S. bill that aims to increase accountability in the sourcing and use of critical minerals. If enacted, the legislation would require digital tracking identifiers for battery components and minerals throughout their lifecycle. This move signals a shift toward deep supply chain traceability as a baseline for market participation.
These regulatory developments will require major investments in data infrastructure, supply chain visibility and internal coordination. Energy storage manufacturers should continue to closely watch as the EU and the U.S. work to clearly define the rules for each regulation.
Simultaneously, it’s important to remember that global and U.S. regulators are targeting per- and polyfluoroalkyl substances (PFAS), also known as “forever chemicals,” because of their environmental persistence and health risks. PFAS, which are in everyday household products like carpets, cosmetics, pesticides and paint, have also been widely used in battery manufacturing and electronic components for their thermal stability and chemical resistance.
Regulatory restrictions are expanding, and as PFAS phase-outs progress, product design and material sourcing will need to evolve.
While the challenge is tough, it also unlocks opportunity. Companies that proactively phase out PFAS and innovate with safer alternatives will lead the pack. Compliance will become a differentiator.
A defining year for energy storage supply chains
For energy storage stakeholders, 2025 is not business as usual. It’s a pivotal moment. This year’s trends signal deep structural changes to how energy storage systems are sourced, built and sustained. To lead through this transition, companies should focus on three strategic moves:
In today’s unpredictable environment, those who adapt fastest will lead the way. These companies will shape the future of the energy storage industry.
Stryten Energy | https://www.stryten.com/
Apex Clean Energy announced that four utility-scale wind and storage projects totaling over 625 MW have reached commercial operations across Illinois, Maine, and Texas—bringing Apex’s total operating and construction portfolio to over 3 GW. These facilities—each of which came online in the first half of 2025—underscore the company’s ability to deliver energy solutions across diverse markets and technologies. With a combined local economic impact of nearly $150 million and significant investments in conservation efforts for the regions surrounding these four projects through the Apex Conservation Grant Program, the operational facilities highlight clean power’s role in supporting local economic and ecological resilience.
“From Maine to Texas, these sites reflect the strength of the Apex team and our ability to execute at scale—delivering the infrastructure our country needs at the moment it’s needed most,” said Ken Young, CEO of Apex Clean Energy. “As we continue to expand our operating portfolio, we’re focused not only on supplying the grid with reliable, low-cost energy, but on maximizing the long-term value our projects create for the communities where we work.”
More about the newly operational facilities:
Apex Clean Energy | https://www.apexcleanenergy.com/
Cabot Corporation (NYSE: CBT) announced the launch of its new LITX 95F conductive carbon developed for use in lithium-ion batteries for energy storage systems (ESS). Engineered for ESS cells used in residential, commercial and industrial applications, this high-performance conductive additive delivers enhanced conductivity, long cycle life, and improved processability, which is essential for systems that demand durability and stability under frequent cycling.
The global ESS market is growing rapidly, driven by the rising demand for grid flexibility, the transition to renewable energy, and the need for reliable power across residential, commercial and industrial sectors. Meeting these evolving needs requires advanced lithium-ion batteries that offer superior cycle life, optimal power delivery and long-term reliability. As the market continues to scale, battery manufacturers need to deliver solutions that are both high-performing and cost-effective. Cabot’s LITX 95F solution addresses these challenges by delivering key performance and efficiency advantages that are vital for accelerating ESS adoption.
The LITX 95F grade is formulated to improve cycle life and increase energy density. It has demonstrated excellent capacity retention in pouch cell performance testing with thick electrode design, offering ideal flexibility for battery manufacturers to optimize formulations across a wide range of ESS designs. Its high structure morphology helps to enhance conductivity and stability during repeated charge-discharge cycles. It also enables thick cathode design, helping to reduce material costs without compromising battery performance.
“As the global energy landscape continues to evolve, the ESS market requires advanced materials that deliver both performance and efficiency,” said Jeff Zhu, executive vice president and president, Carbon & Silica Technologies, Battery Materials and Asia Pacific Region. “Our new LITX 95F product is a direct response to the needs of the market and our battery customers — leveraging our deep industry expertise with proven performance to help scale ESS applications faster and more efficiently. This launch reflects our commitment to enabling a more sustainable future by delivering innovative solutions for battery technologies that support the energy transition at a global scale.”
Cabot Corporation | cabotcorp.com/batteries
700 Santana Row, an innovative mixed-use development, brings a new dimension to San Jose’s acclaimed Santana Row district by offering a seamless blend of modern design, sustainability and vibrant public spaces. 700 Santana Row encompasses 28,000 square feet of retail space, 290,000 square feet of Class A office space and a 450,000-square-foot parking structure with 1,300 stalls. Its dynamic façade, made of Solarban 70 glass by Vitro, and its LEED Silver certification underscore its commitment to both aesthetic innovation and environmental responsibility.
This year marks two decades of Solarban 70 glass, the industry’s most trusted and widely specified triple-silver-coated low-e glass. With over 700 million square feet shipped since its debut, Solarban 70 glass has become a benchmark in performance and design. In a standard one inch insulating glass unit (IGU), Solarban 70 glass delivers a solar heat gain coefficient (SHGC) of 0.27 and a visible light transmittance (VLT) of 64%.
The ideal balance of VLT, solar control and exceptional clarity provided by Solarban 70 glass aligned perfectly with architect WRNS Studio’s vision for a dynamic and engaging design.
700 Santana Row features a metal facade with flowing curves that reflect sunlight and a translucent curtain wall design that brings natural light into its eight stories. A breezeway connects the public plaza to the office lobby and parking garage for better accessibility and connectivity. At the center, the building includes a public plaza that serves as a space for community gatherings, events, and activities.
700 Santana Row showcases a range of environmentally sustainable features, including cool roofs, water-efficient landscaping, an eco-friendly irrigation system, and the use of recycled materials. This innovative development transforms its surroundings, elevating the district from a renowned shopping and entertainment hub into a dynamic, integrated space for living, working, and leisure.
Project Credits:
· Architect: WRNS Studio
· Fabricator: Glassfab Tempering Services
· Glazier: Walters & Wolf
· Photography: Bernardo Grijalva
Vitro Architectural Glass | vitroglazings.com
A new report from Aurora Energy Research, commissioned by the American Clean Power Association (ACP), finds that the deployment of 10 GW of battery storage— enough to power 8 million homes during peak demand —across the Midwestern and Central U.S. could result in $25 billion in energy cost savings for American consumers, while significantly boosting reliability for the region.
A 500% increase in battery storage by 2035 in the Midcontinent Independent System Operator (MISO) territory—which serves 45 million consumers—will be needed to maintain grid reliability as demand grows. During this time, MISO is expecting a significant increase in demand for electricity, which will place additional strain on energy generation infrastructure and transmission networks.
As noted in the report, battery storage has the unique ability to capture excess power and deliver it to the grid when it is needed most, as well as its ability to provide instantaneous dispatchable power, making the technology a natural complement to both renewables and thermal power plants.
“As power demand surges, battery storage is one of the fastest and most effective ways to strengthen reliability and lower electricity bills,” said Noah Roberts, ACP Vice President of Energy Storage. “Grid batteries deliver massive cost savings for families and businesses, while ensuring that the grid delivers power when it’sneeded most. With more than $25 billion in energy savings at stake, this is a generational opportunity for the Midwest to secure a more reliable and affordable energy future.”
If MISO and state policymakers harness the potential of energy storage:
More than 10 GW of battery storage could be economically and quickly deployed over the next decade to meet rising demand for power and acute grid reliability needs.
States in the MISO region could generate more than $4.5 billion in energy cost savings over the next decade, and more than $25 billion over the next two decades.
Energy storage resources could cut evening energy price spikes by more than 60% between now and 2035.
This summer, the MISO territory saw their capacity prices jump over 2,000%. If energy storage in the MISO electricity market is not built, the report’s modeling shows that peak electricity prices for consumers will continue to soar. Additionally, without batteries, the region faces limited options to maintain reliability. The report highlights how other markets have shown that battery storage benefits reliability by dispatching at times of highest system stress, while also freeing up thermal generation to operate as base power more efficiently.
There are hundreds of energy storage projects in the MISO project queue, working through their lengthy interconnection and permitting process. These projects represent billions of dollars in economic investment, thousands of jobs, and billions of dollars in energy cost savings. Policymakers can act now to help deploy these projects, investing in future energy security and affordability.
* MISO is the largest regional transmission organization (RTO) in the U.S. stretching across Arkansas, Illinois, Indiana, Iowa, Kentucky, Louisiana, Michigan, Minnesota, Mississippi, Missouri, Montana, North Dakota, South Dakota, Texas, Wisconsin, and the Canadian province of Manitoba.
American Clean Power Association | cleanpower.org
An innovative student-led design-build project, combining hands-on architectural education with high-performance sustainability, has been completed in partnership with the University of Kansas School of Architecture. The project marks the 18th consecutive LEED Platinum-certified home completed through the university’s Studio 804 program and is the second to be supported by product donations from S-5!
Studio 804 is a unique, hands-on design-build program within the University of Kansas’ Master of Architecture curriculum. Founded by Professor Dan Rockhill, it provides graduate students in their final year with an immersive experience, challenging them to design, source materials for, and construct a fully realized building within just nine months—providing a practical foundation for sustainable architectural practice.
Photo Credit to Gaffer Photography
The 1040 New York Street House features a 2,000-square-foot primary residence alongside a 1,000-square-foot accessory dwelling unit (ADU), housing a garage and additional living space. The exterior is clad in white composite metal with a dynamic sheen, complemented by a sleek 22-gauge matte black standing seam metal roof. Situated on a previously vacant infill lot, the home seamlessly integrates into East Lawrence—a vibrant historic neighborhood near the Kansas “KAW” River and downtown Lawrence.
Sustainability was central to the students’ design intent. To help achieve LEED Platinum certification, the project incorporated a solar photovoltaic system. S-5! donated its PVKIT DirectAttach solar mounting system, enabling a streamlined, penetration-free installation of an 8.8 kW solar array using Navitas 550W Bifacial 144 Half Cut Mono modules. The solar array is expected to offset most, if not all, of the home’s energy consumption.
In addition, S-5! contributed its ColorGard snow retention system, engineered to match the roof’s aesthetics and provide reliable snow management through the harsh winter months, protecting both the roof and occupants.
“We’re honored to support a program like Studio 804 that combines high-level design, hands-on learning, and real-world sustainability,” said Rob Haddock, S-5! CEO and Founder. “These students are learning to build smarter and better—and that starts with quality materials and streamlined installation practices.”
S-5! remains committed to advancing sustainable building practices and supporting educational initiatives that prepare the next generation of architects to design responsibly and innovatively.
S-5! | www.S-5.com
As solar energy projects continue to grow across the U.S., a fact sheet from the Center for Rural Affairs outlines how new development can be designed to protect soil health, reduce erosion, and maintain long-term agricultural productivity.
The newly released fact sheet, “Soil Health in Solar Development,” provides practical guidance for developers, landowners, and communities constructing solar sites with soil conservation in mind. It highlights strategies such as low-impact construction methods, native vegetation establishment, and dual-use solar practices.
“Well-designed solar development can protect the long-term viability of agricultural land that is used for solar sites,” said Alex Delworth, senior policy associate with the Center for Rural Affairs. “As more solar is developed in agricultural settings, it is important to support soil health so that at the end of project life the land can be returned to agricultural production, if desired.”
One recommendation is to use low-impact construction practices that minimize soil disruption. This includes preserving topsoil, avoiding grading, and adapting panel leg height to the land’s natural contours. These approaches contrast with conventional methods that often involve topsoil stripping, soil compaction, and vegetation removal.
Establishing native vegetation beneath and around solar arrays is also important for erosion control, according to the fact sheet. Deep-rooted perennial native plants anchor soil, improve water infiltration, and help minimize stormwater runoff. Compared to turfgrass or gravel ground cover traditionally used on solar sites, native vegetation offers long-term erosion control and helps store carbon in the soil.
“When carefully planned and managed, solar energy projects can minimize impacts on soil quality and ensure optimal outcomes,” said Delworth.
Additionally, the fact sheet talks about the value of dual-use solar practices. Co-locating solar panels with agriculture, such as grazing livestock or growing crops, can keep land in agricultural use while maintaining and enhancing soil health.
To read and download a copy of “Soil Health in Solar Development,” visit cfra.org/publications.
Center for Rural Affairs | https://www.cfra.org/
Alternative Energies Jul 15, 2025
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