Professor Chen Haisheng, a pioneering figure in the field of advanced energy storage, has been named to Research.com’s 2025 list of the World’s Best Scientists in Engineering and Technology (https://research.com/u/haisheng-chen). This prestigious recognition reflects his extensive contributions to the development of large-scale physical energy storage systems and his leadership in advancing compressed air energy storage technologies. Research.com, a globally respected academic platform, evaluates candidates using the D-Index, a discipline-specific metric derived from comprehensive citation data, highlighting scientists with sustained and measurable impact.

At the forefront of Engineering Thermophysics, Professor Chen has led groundbreaking work in the development of advanced compressed air energy storage (CAES) systems. His team realized the world’s first demonstration projects of CAES systems across multiple scales—1.5MW, 10MW, 100MW, and 300MW—marking critical advancements in energy storage infrastructure. He has authored over 700 academic papers, with more than 370 indexed by SCI and over 30,000 total citations, including more than 17,000 SCI citations. His intellectual property portfolio includes more than 500 authorized patents. Professor Chen has also published influential monographs and journal articles that rank globally in impact metrics on CAES research. His leadership has culminated in the creation of the National Energy Large Scale Physical Energy Storage Technology R&D Center, the first of its kind in China, fostering a 130-member research team and driving over 30 major national and institutional projects.

Professor Chen’s career is distinguished by a series of significant accolades. His honors include the Special Award of the China Youth Science and Technology Award, the First Prize of the Beijing Science and Technology Award, and the First Prize of the Beijing Technology Invention Award. He has also received the Newton Advanced Fellowship from the Royal Society in the UK and the Young Scientist Award of the Chinese Academy of Sciences. His international experience spans research appointments at leading institutions including the University of Cambridge and the University of Leeds. Professionally, he has held key roles such as Director of the National Energy Storage R&D Center and Deputy Director of the Institute of Engineering Thermophysics at CAS. He contributes actively to global and national energy strategy efforts, including participation in China’s Five-Year Energy Planning initiatives.

This latest distinction from Research.com underscores Professor Chen’s enduring influence in the energy engineering field. His work has not only elevated the scientific understanding of energy storage technologies but has also led to practical systems with transformative potential. As he continues to lead cutting-edge research and policy advising, Professor Chen’s contributions are poised to shape the global trajectory of sustainable energy storage for years to come.

Southeast Asia’s Ambitious Cross-Border Renewable Project Takes Shape with CATL’s Energy Storage Commitment

A major milestone has been reached in Southeast Asia’s cross-border renewable energy ambitions, as China’s Contemporary Amperex Technology Ltd. (CATL) secured a framework agreement to provide 2.2GWh of battery energy storage systems (BESS) for the landmark Vanda Solar & Battery Project. The initiative is set to deliver solar power from Indonesia’s Riau Islands to land-constrained Singapore under a broader regional energy collaboration plan.

The deal underscores CATL’s expanding footprint in the global BESS market while reinforcing Indonesia’s and Singapore’s strategic alignment on clean energy trade. With the storage capacity representing half of the project’s total 4.4GWh BESS needs, the agreement is pivotal for enabling stable, dispatchable energy exports across the undersea transmission corridor.

Bilateral Policy Moves Enable a Regional Clean Energy Exchange

The battery supply deal follows policy groundwork laid by the Indonesian and Singaporean governments in the form of a “green economic corridor” — a bilateral agreement designed to facilitate renewable energy trade between the two nations. Singapore’s Energy Market Authority (EMA) has conditionally approved the export of 300MW of renewable electricity from the Vanda Solar & Battery Project, marking a first-of-its-kind international clean energy trade route for the city-state.

This framework aligns with Singapore’s Green Plan 2030, which seeks to import up to 4GW of low-carbon electricity by 2035, as domestic land limitations severely restrict large-scale renewable development. Indonesia, on the other hand, benefits from extensive land availability and an increasing policy emphasis on clean energy buildout, as demonstrated by its newly ratified plan for state-owned utility PLN to add 42.6GW of renewable generation and 10.3GW of energy storage by 2034.

Technical Design Anchored in Local Manufacturing and Supply Chain Localization

The Vanda project is planned to include 2GWp of solar photovoltaic (PV) capacity alongside the 4.4GWh of energy storage. The 2.2GWh of EnerX BESS units sourced from CATL will be vital to managing the intermittency of solar production and ensuring reliable export to Singapore.

Vanda RE, the project’s joint venture developer—comprising Singapore-based Gurīn Energy and Gentari International Renewables, a Petronas subsidiary—has also secured PV module supply agreements with LONGi Green Energy (1GW) and Trinasolar (1.4GW). All three Chinese manufacturers, including CATL, are building production facilities within Indonesia. This enables the project to satisfy the country’s domestic content requirement (TKDN), which is a policy condition for participation in national infrastructure projects.

CATL’s battery factory, currently under construction in Karawang, West Java, is slated for an initial annual production capacity of 6.9GWh, scalable to 15GWh. This facility is part of a broader US$6 billion investment across the Indonesian battery value chain, involving recycling operations and material processing in partnership with state-owned Indonesia Battery Corporation (IBC) and CATL’s subsidiary Brunp.

Growing Corporate and Governmental Appetite for Regional Energy Integration

The Vanda project is emblematic of a larger trend in Southeast Asia toward energy interconnectivity. As highlighted by a recent Rystad Energy report, a Southeast Asian power grid centered around Singapore could support the deployment of 25GW of renewables and energy storage. Singapore is already importing hydro and solar energy from Laos and Thailand, and new corridors are under consideration for wind from Vietnam and hydropower from Malaysia.

From a geopolitical perspective, Singapore’s leadership in financing and regulation provides a bankable counterpart for countries like Indonesia, Vietnam, and Cambodia, which offer land resources but require external investment to realize energy infrastructure at scale.

This momentum was further reinforced at the 2025 ASEAN Summit, where Singapore signed renewable energy export cooperation agreements with Malaysia and Vietnam. These transnational partnerships mark a shift toward integrated clean energy development, positioning the region to become a global model for renewable electricity trade.

Scaling Challenges Highlight the Complexity of Cross-Border Projects

Despite the promising progress, Vanda RE and its partners face several implementation risks. For one, the complexity of constructing interconnection infrastructure, including undersea transmission, remains a significant engineering and regulatory hurdle. Permitting, financing, and synchronization across jurisdictions are often protracted processes that can delay execution.

Another key challenge involves ensuring timely and reliable delivery of BESS and PV components, even from locally situated factories. While Indonesian localization policy offers benefits, it may also introduce bottlenecks if industrial ramp-up lags behind project schedules.

Furthermore, navigating different national energy regulations, tariff structures, and capacity planning frameworks can strain coordination, particularly as the project scales toward commercial operation. Ensuring grid stability and aligning market rules across countries will require substantial regulatory harmonization.

Strategic Implications for Clean Energy Supply Chains and Investment

The Vanda Solar & Battery Project reflects broader shifts in the global clean energy landscape. For Indonesia, it offers a blueprint for stimulating industrial development through energy exports, while creating domestic manufacturing jobs and advancing climate goals. For Singapore, the project is part of a necessary pivot toward energy import diversification amid space constraints and growing electricity demand.

The CATL agreement also signals increased localization of clean energy supply chains in Southeast Asia. If successfully executed, Indonesia could emerge as a critical node in the global battery and solar module supply web, drawing investment from upstream mineral extraction to downstream manufacturing.

From an investor standpoint, such projects present a high-reward opportunity tied to long-term regional energy demand growth. However, they also entail significant exposure to geopolitical, regulatory, and execution risks that must be carefully managed.

Looking Ahead: A New Regional Clean Energy Ecosystem in Formation

As Southeast Asia intensifies efforts to decarbonize and integrate its energy systems, projects like Vanda represent more than bilateral energy trade—they are foundational steps toward a regional clean energy ecosystem. The combination of robust policy frameworks, maturing supply chains, and growing private-sector participation may create a replicable model for other transnational renewable energy projects.

However, sustained success will depend on harmonizing technical standards, securing finance for grid infrastructure, and balancing domestic interests with regional goals. The CATL deal is a meaningful indicator that stakeholders across the region are aligning around these objectives, but implementation will be the true test.

If executed successfully, the Vanda project could mark a new era of Southeast Asian energy cooperation—one in which clean power flows across borders as freely as capital and innovation already do.

On July 17, the China Energy Storage Alliance (CNESA) held the sixth executive council meeting of the fourth term in Changzhou, Jiangsu. Attending the meeting were Yu Zhenhua, Executive Vice Chairman of CNESA; Liu Wei, Vice Chairman and Secretary-General of CNESA; Wang Shicheng, Vice Chairman of CNESA and Chairman of Soaring Electric; Ni Lili, President of Trina Solar’s Global Solar Product; Yang Rui, Chairman of Shuangdeng Group; Tian Qingjun, President of Envision Energy; Tang Yuanyuan, Party Secretary and General Manager of the Comprehensive Energy Division of CRRC Zhuzhou Institute; Cui Jian, President of Kehua Digital Energy; Su Wei from China Southern Power Grid Technology; Liu Mingyi, Director of the Energy Storage Technology Department at China Huaneng Clean Energy Research Institute; Yin Feijun, General Manager of the Global Energy Storage Business in Huawei Digital Power’s Smart PV division; Yu Jianhua, Vice President of Domestic Marketing Center at Narada Power; as well as representatives from executive council member units including Sungrow, HyperStrong, CATL, BYD, Sineng Electric, XYZ Storage, Alpha ESS, Rongke Power, among others. Attending as observers were Wang Qingsong, Supervisor of the Board of Supervisors and Professor at the University of Science and Technology of China, and Jin Chengri, General Manager of Beijing Nego Automation Co., Ltd.

The meeting was chaired by Liu Wei, Vice Chairman and Secretary-General. The executive council members listened to the work report for the first half of 2025 and the work plan for the second half, and held discussions and reviews on council proposals and adjustments to the executive council membership.

Executive Vice Chairman Yu Zhenhua stated that the energy storage industry is currently at a critical development stage, and leading enterprises must unite efforts to jointly address the challenges facing the industry. The Alliance will play the role of a bridge, leveraging the strength of enterprises to promote the healthy development of the industry, transitioning from cooperation to coordinated breakthroughs.

As the organizer of this executive council meeting, Gao Jiqing, Co-President of Trina Solar, warmly welcomed all attending executive council members and emphasized that the energy storage industry must uphold the safety bottom line, be supported by technological innovation, and plan for the future through the expansion of application scenarios, stimulating vitality along the industry chain through cross-sector collaboration.

Secretary-General Liu Wei reported to the executive council on the Alliance's work in the first half of 2025 and the planning for the second half. In the first half of the year, the Alliance supported multiple ministries and commissions in assessing the impact of "Document No. 136", researching the compensation mechanism for storage capacity, and contributing to the industry’s 15th Five-Year Plan, among various think tank support initiatives. It also provided services to local governments in policy revision and industry layout planning; released multiple research outcomes such as the "2025 Energy Storage Industry White Paper"; established monthly and quarterly data release mechanisms; successfully held the 13th International Energy Storage Summit and Exhibition; initiated four new group standard projects and completed several energy storage station safety assessments. In the second half of the year, the Alliance will continue to provide necessary support to ministries and commissions, establish closer collaboration models with member enterprises, deepen research on energy storage application scenarios, assist enterprises in business layout, identify high-value scenarios, expand overseas markets, and deploy cutting-edge technologies. Events such as the Western Energy Storage Forum and the Sodium-Ion Battery Forum are in preparation; efforts to improve industry data statistics and strengthen industrial service capabilities will continue.

During the proposal discussion session, the Vice Chairmen engaged in in-depth discussions on how the Alliance can further enhance its leadership in the industry, uphold industrial safety baselines, and strengthen industry self-discipline. They also discussed the guiding role of leading enterprises. In particular, they shared insights and suggestions on core issues such as the current domestic and international energy storage market trends, the healthy development of the industrial chain ecosystem, and energy storage safety. The discussions helped build consensus and pointed the way forward for the Alliance’s related initiatives.

The convening of this meeting clarified the core direction for the Alliance’s work in the second half of the year. The Alliance will implement related initiatives based on the consensus and resolutions of the meeting, efficiently promoting the high-quality development of the energy storage industry and contributing to China’s energy transition and green development.

Hybrid Wind-Battery Partnership Signals New Era for Australia’s Renewable Grid Integration

A strategic collaboration between Envision Energy and FERA Australia is set to reshape the landscape of hybrid renewable infrastructure in Australia. Announced at the Australian Energy Wind Conference in Melbourne, the agreement outlines plans for up to 1GW of wind power integrated with 1.5GWh of battery storage, leveraging Envision’s proprietary hybrid control technology.

While a timeline remains undisclosed, a pilot project in Victoria will serve as the first real-world implementation of the companies’ approach, combining wind generation, advanced battery energy storage systems (BESS), and grid-forming capabilities. This marks a critical step forward for Australia’s ambition to modernize and stabilize its National Electricity Market (NEM), which stretches across the country’s eastern and southern coastlines, including Tasmania.

From an industry standpoint, the move represents not only a technical evolution in hybrid deployment but also an inflection point in cross-regional investment as Envision deepens its footprint in the Asia-Pacific energy transition.

Integrated Hybrid Control as a Market Differentiator

Envision’s approach hinges on its vertically integrated technology stack, a distinguishing factor in the hybrid development space. Each project will incorporate:

• Advanced wind turbines with full converter architecture

• Containerized battery storage systems

• Grid-forming power conversion systems (PCS)

• A proprietary Hybrid Power Plant Controller (HPPC)

The HPPC serves as the control hub, enabling coordinated operation of wind and storage assets under a unified system logic. This level of integration allows dynamic response to grid conditions, offering potential grid-forming capabilities—an increasingly vital function in renewable-heavy networks that lack synchronous generation.

While many projects in Australia deploy separately managed wind and battery assets, the Envision-FERA model proposes a more tightly coupled architecture. This could enhance operational efficiency and reduce balance-of-plant complexity.

Strengthening Regional Developers and Global OEMs

FERA Australia, a Melbourne-based offshoot of Italian renewable developer FERA SRL, stands to significantly scale its market presence through the partnership. Currently developing over 1GW of wind capacity in Victoria, the company gains access to Envision’s hardware and digital tools, potentially accelerating project timelines and de-risking technology procurement.

For Envision, the partnership enhances its competitive position in a key growth market. The company has been methodically expanding its presence across the Asia-Pacific region. Its recent collaboration with Indonesia’s SUN Terra and a 320MWh BESS supply deal in India with Juniper Green Energy illustrate a broader effort to build energy storage and wind portfolios across diversified geographies.

The Australian deal adds a strategic layer by pairing market entry with real project execution, signaling Envision’s transition from supplier to system integrator in the region.

Hybrid Value Stack and Competitive Positioning

From a market dynamics perspective, hybrid projects are increasingly viewed as a hedge against grid congestion, volatile wholesale prices, and storage market uncertainties. By co-locating generation and storage, developers may benefit from:

• Shared interconnection infrastructure

• Arbitrage across time-of-day pricing

• Reduced exposure to transmission upgrade delays

In a market where standalone storage is still navigating long-term revenue certainty, hybridization offers potential resilience but also regulatory complexity. Developers must navigate evolving rules on co-location, metering, and market participation within the NEM framework.

Policy, Supply Chain, and Coordination Risks

Despite its promising potential, the Envision-FERA partnership must contend with several real-world implementation challenges.

First, grid connection timelines in Australia have been a major bottleneck for new projects. Technical assessments, system strength remediation, and regulatory approvals often lead to multi-year delays.

Second, the supply chain for energy storage systems remains vulnerable to fluctuations in lithium pricing and constrained inverter manufacturing capacity. Although Envision operates manufacturing assets in China and is constructing a new facility in Kazakhstan, ensuring delivery on a multi-project, multi-year scale in Australia’s regulatory context is no small feat.

Finally, project coordination—especially when integrating complex control systems like HPPC—requires deep engineering collaboration between OEMs, developers, and grid operators. Aligning on grid-forming functionalities and interoperability with AEMO’s system-level requirements will be essential.

Blueprint for Grid-Responsive Hybrid Development

The Envision-FERA alliance may set a precedent for next-generation hybrid projects in Australia and beyond. If successful, it could demonstrate the feasibility of highly integrated, grid-responsive renewable plants capable of operating as virtual synchronous generators.

As Australia continues its transition toward a cleaner and more distributed grid, such hybrid models offer a potential pathway to balance flexibility, capacity, and reliability without relying on fossil backup.

Looking ahead, the pilot’s outcomes—particularly on system performance, regulatory compliance, and revenue optimization—will be closely watched by developers, investors, and policymakers alike.

Should the collaboration achieve its intended scale, it could catalyze further localization of advanced storage manufacturing, hybrid plant controls, and system integration expertise across the APAC region—key enablers of the next phase of the global energy transition.

A New Risk-Sharing Model Emerges in Storage Offtake Contracts
In a notable shift toward risk distribution in clean energy procurement, EDP Renewables North America and Ava Community Energy have finalized long-term energy storage agreements totaling over 1GWh that feature mechanisms to share future policy-driven cost risks. The contracts represent a growing trend in which power purchase agreements (PPAs) incorporate financial flexibility to account for uncertainties tied to import tariffs and tax credit eligibility—factors that have added volatility to clean energy project economics in the U.S.

The structured risk-sharing approach employed in these deals marks a significant departure from traditional fixed-price agreements, signaling a maturation of market strategies in response to evolving federal policy and global trade tensions.

Navigating Tariffs and ITC Uncertainty in the Post-IRA Era
The agreements were shaped against a backdrop of heightened regulatory unpredictability. Earlier in 2025, negotiations between Ava and EDP Renewables stalled temporarily due to mounting concerns over potential reinstatement of U.S.-China import tariffs. While those specific tariffs have since been suspended, the threat of their return continues to cloud financial forecasts for energy storage developers reliant on imported battery components.

Simultaneously, debate surrounding the passage of the comprehensive “One, Big, Beautiful Bill Act” brought the status of clean energy tax credits into question. While the bill ultimately maintained energy storage incentives under the Inflation Reduction Act (IRA), the contentious debate created hesitation among developers banking on predictable long-term subsidies.

Particularly relevant are new provisions under Foreign Entity of Concern (FEOC) guidelines, which restrict access to investment tax credits (ITCs) for projects sourcing components from companies linked to certain nations. These constraints are already pushing developers to reconsider supply chain strategies and contract structures.

Two Projects, One Risk-Adaptive Framework
The larger of the two agreements centers on EDP’s Sonrisa Solar and Storage project in Fresno County, California. Ava Community Energy has committed to a 20-year PPA for 200MW of solar generation paired with 184MW/736MWh of battery energy storage system (BESS) capacity. The contract includes not only energy delivery but also capacity, ancillary services, and renewable energy credits.

The second deal expands Ava’s footprint in EDP’s Scarlet complex, located adjacent to the Sonrisa site. Ava is set to offtake 70MW/280MWh of new BESS capacity from the “Scarlet III” expansion. The original Scarlet project, completed in 2024, already supplies 100MW of solar and 30MW of storage to Ava, with additional capacity contracted to San Jose Clean Energy.

Both projects are contractually scheduled to commence operations by June 30, 2027, though EDP is targeting an earlier commercial operation date of December 31, 2026.

Risk Allocation as a Strategic Norm
The evolving terms of these contracts reflect a broader shift in market behavior. Ava, in documentation prepared for its July 2025 Board of Directors meeting, noted that developers are no longer willing to absorb all policy-related cost uncertainties. Instead, developers and offtakers are increasingly negotiating shared exposure models.

The Sonrisa and Scarlet agreements incorporate pricing adjustment clauses tied to specific material cost impacts arising from tariff changes. These clauses are structured with defined price caps, ensuring that Ava bears a portion of future tariff-related cost escalations but within controllable financial boundaries.

Ava previously employed a similar model in a renegotiated PPA with Intersect Power, while Sacramento Municipal Utility District (SMUD) has also used tariff-adjustable structures in contracts with developer DESRI, according to reports from Energy-Storage.news. These developments underscore a growing consensus that flexible pricing terms may be necessary to ensure project viability under current policy volatility.

Storage Procurement Faces Rising Complexity
From a procurement perspective, these agreements exemplify how market participants are internalizing risk amid rising uncertainty over global supply chains and domestic policy shifts. While storage remains a cornerstone of California’s decarbonization strategy, the financial assumptions underpinning project economics are under strain.

By introducing contractual terms that explicitly address external risks, developers like EDP are improving the bankability of storage projects and reducing the likelihood of stalled deployments due to midstream policy changes. Offtakers such as Ava, meanwhile, are accepting limited risk exposure in exchange for long-term project continuity and resilience.

The use of 20-year terms in both PPAs also reinforces the long-duration commitment to energy storage as a foundational grid asset. With increased regulatory scrutiny over tax credit eligibility—especially related to FEOC compliance—projects that can demonstrate financial adaptability stand a better chance of securing financing and interconnection approval.

Policy Risk Management Without Clear Precedent
Despite the positive momentum, executing these contracts will not be without challenges. The tariff adjustment clauses introduce a layer of complexity that may complicate future project valuations and investor due diligence. Moreover, the lack of precedent for applying FEOC rules to BESS components raises concerns about retroactive ineligibility for ITCs.

Timeline pressures could also intensify if regulatory interpretations shift. Although EDP aims for a late-2026 commercial start, any delays in component delivery, particularly from restricted foreign vendors, could jeopardize both operational targets and tax credit eligibility.

Toward Institutionalized Flexibility in Clean Energy Contracts
The Ava-EDP agreements point to a future where energy procurement is defined as much by financial engineering as by technology. With federal energy policy becoming more fluid and international trade conditions remaining fraught, utilities and CCAs are likely to favor offtake agreements that allow for tactical adjustments without renegotiation.

Over time, mechanisms such as tariff pass-through pricing and ITC contingency clauses may become standard features in large-scale solar and storage procurement, especially for projects relying on foreign-sourced equipment.

As developers refine contractual models to better align with regulatory realities, and offtakers accept a more active role in risk management, the sector may witness more resilient growth—even in the face of volatile policy environments.

On July 14, 2025, the National Energy Administration of the People’s Republic of China and the European Commission jointly released a readout summarizing the outcomes of the 12th China-EU Energy Dialogue. The meeting, held in Beijing, underscored both sides' commitment to deepening cooperation in the clean energy transition and ensuring global energy security. Below is the full official text of the joint readout:

Joint Readout of the 12th Meeting of the China-EU Energy Dialogue between Administrator Wang and Commissioner Jørgensen

On July 14 2025, Wang Hongzhi, Administrator of National Energy Administration of People’s Republic of China, and Dan Jørgensen, European Commissioner for Energy and Housing, jointly held the 12th meeting of the China-EU Energy Dialogue in Beijing.

Both sides reaffirmed that, the overarching objective of China-EU energy cooperation is to expedite the global transition to clean energy, with full consideration for ensuring energy security，with the aim of addressing the challenges of global climate change.

Both sides agreed to sustain cooperation on advancing various aspects of the clean energy transition as discussed during the Dialogue. The discussions broadly included accelerating the transition, ensuring energy security, enabling benefits of the transition, as well as energy market design.

The EU-China Energy Cooperation Platform (ECECP) and the China-Europe Energy Innovation Cooperation Platform (CEEI) participated in the Dialogue meeting.

In a recent move to support energy security and the transition to green, low-carbon development, the National Energy Administration (NEA) has released a batch of major industry standards. These standards aim to promote emerging technologies, new industries, and innovative business models within the energy sector. Among the newly released documents are several that directly concern energy storage technologies, particularly electrochemical energy storage and compressed air energy storage (CAES) stations.

The following energy storage standards are included:

Technical Specification for Grid-Connection Acceptance of Electrochemical Energy Storage Stations

This standard applies to the grid-connection acceptance of newly built, reconstructed, and expanded electrochemical energy storage stations connected at 10kV (or 6kV) voltage level or above. It specifies the grid-connection acceptance conditions, acceptance procedures, scope of acceptance responsibilities, acceptance content, and technical requirements. The implementation of this standard can regulate the grid-connection acceptance procedures during the production preparation phase of electrochemical energy storage stations and help enhance the level of safe and stable operation.

Design Code for Underground Gas Storage Facilities in Compressed Air Energy Storage Stations

This standard is applicable to the design of underground gas storage facilities in newly built, expanded, or reconstructed compressed air energy storage stations. It stipulates site selection and layout, stability analysis, support design, structural design, and main equipment for underground gas storage. The implementation of this standard fills the gap in domestic technical standards for underground gas storage facilities in CAES stations and holds significant importance for standardizing their design and construction.

Design Code for Compressed Air Energy Storage Stations

This standard applies to non-combustion compressed air energy storage stations with a single generator unit capacity of 10MW or above. It outlines requirements for power systems, site selection, overall planning and layout, main equipment and systems, thermal storage and exchange systems, main plant area layout, gas storage systems, auxiliary process systems and equipment, and electrical equipment. The release and implementation of this standard is expected to improve the standardization of CAES station designs, enhance equipment compatibility, and reduce investment risks.

With the publication of these standards, the National Energy Administration continues to set a clear regulatory framework for advancing critical energy technologies. The inclusion of detailed specifications for both electrochemical and compressed air energy storage facilities marks a significant step in aligning technical standards with the evolving demands of China’s modern energy infrastructure.

Chengdu-led initiatives dominate the list, with compressed air and hybrid battery projects highlighting diversified technology strategies

The Sichuan Provincial Development and Reform Commission (DRC) and the Sichuan Energy Bureau have officially released the “2025 Grid-Side New Energy Storage Project List,” comprising 27 storage projects across the province. The notice, dated July 9, 2025, directs local authorities, grid companies, and project developers to expedite construction, ensure safety compliance, and regularly report progress.

The inclusion of these projects marks a continuation of Sichuan’s strategy to scale up non-hydro grid flexibility in tandem with growing renewable integration. Projects that fail to demonstrate substantive construction progress within one year of the notice risk removal from the list, reinforcing the province’s push for implementation over intent.

Provincial Backing to Accelerate Energy Storage Buildout

Issued under official document Chuan Fa Gai Neng Yuan [2025] No. 309, the notification underscores the province’s commitment to grid-side energy storage as a means of enhancing system stability and optimizing resource allocation. Local Development and Reform Commissions and energy authorities are tasked with coordinating inter-agency efforts, while grid operators such as State Grid Sichuan are expected to facilitate access and interconnection.

The notice stipulates that all stakeholders—particularly project owners—must adhere to market-based principles in project advancement, while also complying with safety, fire protection, and regulatory oversight. Monthly progress reporting is mandatory, and the policy reiterates that failure to commence substantive construction within a year will lead to project disqualification from the list.

Technology Diversity Reflects Strategic Positioning

While electrochemical storage continues to dominate—with most projects sized at 100MW/200MWh—Sichuan is also experimenting with a range of storage technologies. Notably, the 300MW/2400MWh compressed air energy storage (CAES) project in Chengdu Eastern New Area stands out as the largest capacity installation and the only CAES project on the list.

Other variations include:

• A hybrid electrochemical + supercapacitor project in Pengzhou (100MW/200MWh + 2.5MW supercapacitor), reflecting interest in fast-response ancillary services

• A mixed lithium iron phosphate/sodium-ion battery system in Leshan’s Qianwei County

• A vanadium redox flow battery project in Jiajiang County, offering long-duration discharge capabilities

These examples suggest a strategic tilt toward technology diversification to support various grid functions, from peak shaving to black-start capability.

Policy Implementation Mechanics and Compliance Framework

The policy stipulates clear accountability:

• Local governments must coordinate and supervise project rollout.

• Grid enterprises are expected to expedite interconnection procedures.

• Project developers must follow market-driven financing and implementation models.

• Safety and fire management are prioritized, with site-level responsibility assigned to project owners.

Crucially, projects will be delisted if not meaningfully under construction by July 2026, injecting a strong compliance signal into the project pipeline. Progress updates are to be submitted monthly, reinforcing bureaucratic visibility and minimizing lag.

Market and Competitive Landscape Outlook

The approved list suggests that energy storage is becoming an essential infrastructure class in Sichuan, not merely an auxiliary service. With capacity additions ranging predominantly in the 100–200MW bracket, developers appear to be responding to a provincial market increasingly shaped by:

• Renewable intermittency

• Peak demand differentials

• Grid congestion in urban clusters like Chengdu

The integration of CAES, hybrid chemistries, and flow batteries may position Sichuan as a testing ground for scaling non-lithium storage technologies—though most commercial traction remains in lithium-based solutions.

Conclusion

Sichuan’s 2025 grid-side storage project list represents a significant step in expanding the province’s energy flexibility infrastructure. As construction progresses and projects begin operation, industry observers will closely watch for updates on revenue mechanisms, dispatch roles, and integration challenges—all of which will determine whether Sichuan’s diversified storage ambitions can translate into lasting grid resilience.

On July 13, it was reported that the main structure of the Mulei CO₂ energy storage project by China Huadian Corporation was successfully topped out on July 10, laying the foundation for subsequent equipment installation and commissioning work.

This project is a demonstration project of new energy storage supporting the construction of large-scale wind and solar bases in desert, Gobi, and arid regions. It is planned to have an installed capacity of 600,000 kW of wind power, 400,000 kW of photovoltaic power, and 1,000,000 kWh of energy storage, making it the world’s largest CO₂ energy storage project.

The project is located in Western China. It involves the construction of one set of compressed CO₂ energy storage system with an energy storage duration of 8 hours and a power generation duration of 10 hours, adopting a non-combustion compressed CO₂ energy storage process system.

What is CO₂ energy storage?

Energy storage phase:
During periods of electricity surplus, atmospheric pressure gaseous CO₂ is compressed, the compression heat is stored, and the high-pressure CO₂ is liquefied at ambient temperature for storage.

Power generation phase:
Stored heat is used to heat the high-pressure liquid CO₂ into high-temperature gas to drive a turbine for power generation.

What are the advantages of CO₂ energy storage?

CO₂ energy storage systems offer multiple advantages in large-capacity, long-duration, and safety-related energy storage applications—

Environmentally friendly
CO₂ operates within a closed system with minimal environmental impact, and the entire process consists of physical changes, producing no pollutants.

No special geological conditions required
Does not require underground space, has good site adaptability, and does not depend on specific geological conditions.

Short construction period, long lifespan, zero carbon emissions
Approximately 2-year construction period, service life exceeding 30 years, non-combustion, zero carbon emissions, and low levelized cost of electricity over the full lifecycle.

Constant pressure operation throughout the entire process
The system runs at constant pressure across all time periods, with rotating machinery operating for extended periods under rated conditions, resulting in high system efficiency.

Meets grid dispatching requirements
Equipment such as compressors, expanders, and heat exchangers can start and stop quickly in a short time, promptly responding to grid dispatching needs.

Provides ancillary services
Can provide rotational inertia support to the grid and offer ancillary services such as peak shaving and frequency regulation.

Controllable industry chain
All subsystems and key core equipment are independently developed and are safe and controllable.

Australia has unveiled a significant overhaul of its flagship Capacity Investment Scheme (CIS), shifting to a one-stage tender model aimed at accelerating project timelines and providing greater clarity for developers. With four major tenders scheduled for 2025, the government is reinforcing its commitment to a more flexible and reliable clean energy system while opening doors for smaller-scale participants through a parallel consultation process.

Transition to Single-Stage Tendering: A Strategic Pivot

The move to consolidate CIS tenders into a single-stage format reflects a targeted response to delays and uncertainties that have characterized previous rounds. By eliminating the two-step process—formerly divided into technical and financial bidding phases—the Department of Climate Change, Energy, the Environment and Water (DCCEEW) aims to shorten the tender cycle from nine to six months. This streamlined structure is expected to provide earlier decision-making, reduce administrative burden, and help prevent overlapping rounds that have historically complicated planning for developers.

According to the department, this reform is not merely procedural—it represents a structural evolution in how Australia procures firmed renewables, offering clarity and efficiency in a fast-moving energy transition.

Regulatory Context: Enabling a Clean Energy Backbone

This revision aligns with broader national energy policy goals: to secure reliable, dispatchable capacity as coal exits the grid and renewables scale up. Under the CIS, the federal government underwrites long-term revenue for selected projects, providing investment certainty in a market increasingly shaped by variable supply and rising electrification demands.

The scheme complements state-level initiatives and dovetails with the federal government’s Rewiring the Nation plan, which prioritizes grid upgrades to support renewable integration. By refining the CIS process, Australia positions itself to better execute its national emissions targets and clean energy rollout.

Merit Criteria Refined for Competitive Clarity

With the single-stage process now in place, proponents are required to submit comprehensive bids within a 6–8 week window. These will undergo a dual-layer evaluation by AEMO Services—first for eligibility compliance, then for in-depth merit assessment.

The revised merit framework preserves key pillars—financial value, system reliability, and social impact—but now presents them in a reorganized, holistic structure. Criteria include:

• Project financial value

• System benefits and reliability

• Deliverability and timeline

• Organizational and financial capability

• Revenue strategy and risk mitigation

• First Nations participation and social outcomes

While assessment categories remain largely consistent across tender rounds, DCCEEW has indicated that weightings and thresholds may be fine-tuned depending on technology type or regional focus.

This reconfiguration offers a clearer roadmap for developers while aligning with Australia’s equity and sustainability goals, especially regarding First Nations inclusion and local community benefit sharing.

2025 Tender Timeline: National Rollout across Two Grids

In a parallel announcement, DCCEEW confirmed four CIS tenders will be launched before the end of 2025. These will span both of Australia’s primary electricity markets:

Image: DCCEEW.

Each market—Western Australia’s Wholesale Electricity Market (WEM) and the National Electricity Market (NEM) on the east coast—will see one generation and one dispatchable capacity tender.

This even distribution reflects a balanced national strategy, ensuring that renewable build-out and firming resources are deployed where most needed. Prior consultations, particularly on WEM tender design, have informed the criteria and process for the upcoming rounds.

Aggregated Resources: Unlocking Decentralized Capacity

In a forward-looking step, DCCEEW is also exploring how Aggregated Resources (ARs)—a collection of smaller-scale assets—could be integrated into future CIS rounds. A public consultation now open through early August seeks feedback on including assets like:

• Small-scale wind and solar projects (<5MW)

• Community and distribution-level batteries

• Virtual power plants (VPPs) aggregating residential solar and battery systems

From a system operations perspective, ARs can contribute flexible, distributed capacity and enhance grid resilience. But their participation in traditional procurement programs has been limited by complex eligibility and merit frameworks designed for utility-scale infrastructure.

By launching this consultation, the government is acknowledging the value of decentralized energy resources while also signaling intent to reform access mechanisms to foster fair competition. Submissions from developers, community groups, and the public will shape how ARs are positioned within the CIS architecture going forward.

Industry Dynamics: Competitive Gains and Compliance Pressures

The tender streamlining is expected to benefit both project economics and market stability. Faster timelines mean developers can secure financing earlier, align with supply chain schedules, and bring capacity online more predictably.

However, the tighter submission window and broader scope of required documentation may prove challenging for smaller developers or first-time applicants. Projects lacking robust financial modeling or community engagement frameworks may find themselves disadvantaged under the merit criteria.

In contrast, established players with experienced bid teams and vertically integrated capabilities are likely to find the process more navigable, further intensifying competition in Australia’s clean energy landscape.

Challenges Ahead: Timeline Pressure and Coordination

While the streamlined process reduces waiting periods, it also compresses preparatory timelines, increasing pressure on developers to finalize engineering, financing, and stakeholder engagement strategies quickly. For larger or more complex projects, especially in regions with permitting or grid connection constraints, this may create a bottleneck.

Additionally, coordinating multiple concurrent tenders—especially across two separate electricity markets—demands high administrative capacity and cross-jurisdictional alignment. Any discrepancies in process, criteria, or approval timelines between the NEM and WEM could create inefficiencies or distort market outcomes.

Strategic Implications: Toward a More Adaptive Procurement Model

Australia’s CIS redesign reflects a maturing energy procurement framework that prioritizes speed, transparency, and systemic value. By coupling procedural reform with a national tender rollout and inclusivity consultation, the government signals a long-term commitment to evolving how clean energy is integrated into the grid.

Looking ahead, the integration of Aggregated Resources could mark a shift toward a more modular, distributed model of capacity procurement. If implemented effectively, this would democratize participation, deepen community engagement, and unlock a wider set of tools for achieving net-zero goals.

Ultimately, how the restructured CIS plays out will shape investment decisions, grid readiness, and energy equity in the years ahead.

Source: Xinhua News Agency

The industrial chain is now connected, forming a new energy industry layout of “PV-generated green electricity and green electricity-produced green hydrogen.”

On July 2, the fully seawater-based floating photovoltaic (PV) project of Sinopec Qingdao Refining and Chemical Co., Ltd. was completed and commissioned. This is China’s first fully seawater-environment floating PV project to achieve industrial operation. Combined with the previously commissioned pile-based water surface PV system, it has become Sinopec’s largest water surface PV power station to date. The entire project is expected to generate 16.7 million kilowatt-hours of green electricity annually, reducing carbon dioxide emissions by 14,000 tonnes—equivalent to planting 750,000 additional trees. It provides an important demonstration for the promotion of floating PV in coastal and shallow sea areas under full seawater conditions.

Tapping into land-use potential and creating a new “dual-use” model. The floating PV power station is located in a water area connected to the sea, utilizing the surface of the seawater for power generation. The project is situated within the Qingdao Refining and Chemical Hydrogen Energy “Production-Research-Plus” Demonstration Park and features advantages such as zero emissions, high efficiency, and low cost. It covers approximately 60,000 square meters with an installed capacity of 7.5 MW. The project adopts an innovative floating PV structure, allowing PV panels to rise and fall with the tides, reducing the gap between the panels and the water surface to about one-tenth that of traditional pile-based structures. It maximizes the cooling effect of seawater, improving power generation efficiency by 5%–8%.

Three innovations address the challenges of seawater PV industrial applications. In fully seawater environments, PV systems face issues such as seawater corrosion, biofouling, and tidal fluctuations. To tackle these challenges, the R&D team collaborated with leading domestic material research and float production enterprises to achieve three key innovations: the development of special floats and brackets resistant to salt spray corrosion and barnacle attachment; the design of an underwater anchoring system capable of withstanding Category 13 typhoons and adapting to a 3.5-meter tidal range, reducing investment by approximately 10% compared to traditional pile-based PV; and the installation of panel and cable inspection passages close to the water surface, which significantly enhances operation and maintenance safety and reduces costs compared with traditional pile-based PV. These technological breakthroughs provide standardized solutions for PV development in coastal and shallow sea areas and promote cost reductions in new energy projects.

Supporting high-quality integrated development of hydrogen and PV. Previously, Qingdao Refining and Chemical had built the nation’s first “carbon-neutral” hydrogen refueling station and China’s first factory-scale seawater electrolysis hydrogen production project. The full completion and commissioning of the water surface PV project opens the most critical link in Qingdao Refining and Chemical’s new energy industrial chain, forming a new energy layout of “PV-generated green electricity and green electricity-produced green hydrogen.” This supports high-quality integration between hydrogen and PV and lays the resource foundation for green hydrogen refining and green hydrogen transportation. Next, Qingdao Refining and Chemical will leverage its new energy industry advantages to further expand and build an additional 23 MW floating PV project, strengthening its green energy supply capacity.

In recent years, Sinopec has accelerated the construction of a clean and low-carbon energy supply system to foster new growth drivers for high-quality development. The company is vigorously implementing its green and clean development strategy, adhering to ecological priority, green transformation, and clean development. It is comprehensively advancing the clean development of fossil energy, the large-scale development of clean energy, and the low-carbon transformation of production processes. Sinopec has launched the “10,000 Stations Bathed in Light” initiative, planning to build approximately 10,000 PV-powered sites by 2027 to promote deep integration between new and traditional energy industries. It continues to deepen its geothermal energy efforts, with geothermal heating capacity reaching 120 million square meters, making it China’s largest geothermal energy developer and operator. Focusing on hydrogen-powered transportation and green hydrogen refining, Sinopec is rapidly building a full hydrogen energy industry chain, having completed and commissioned the country’s first 10,000-ton photovoltaic green hydrogen demonstration project and established 144 hydrogen refueling stations, making it the company with the most hydrogen stations in operation globally. In 2024, Sinopec’s new energy supply totaled the equivalent of over 5.8 million tonnes of standard coal, promoting the coordinated development of traditional oil and gas with new energy businesses.

Lithium-ion and emerging technologies dominate provincial storage roster as Energy Administration of Shandong Province clears 96 projects for grid integration

Shandong Province has officially announced the approval of 96 new energy storage projects totaling 18.6292 gigawatts (GW) for 2025, in a move that reinforces its role as a national leader in energy transition and power system flexibility. The projects—ranging from lithium-ion battery installations to compressed air and flywheel storage systems—have been publicly listed by the Energy Administration of Shandong Province as part of its annual new energy storage project registry.

According to the public notice released on July 9, the inclusion process was based on recommendations from municipal governments and expert reviews in accordance with the bureau’s earlier call for project applications. The 2025 storage roster includes 81 lithium-ion peak-shaving projects, two compressed air energy storage (CAES) systems, one flow battery installation, seven frequency regulation units, and five categorized under other new energy storage technologies. The public comment period will remain open from July 9 to July 15.

Policy Continuity and Technological Diversification

This announcement marks a significant continuation of Shandong’s multi-year strategy to accelerate the deployment of new energy storage systems in support of its dual-carbon goals. The provincial government has consistently promoted a diversified portfolio of energy storage technologies to address different grid stability and load-shifting needs.

Lithium-ion batteries remain the dominant technology, accounting for more than 80 of the 96 listed projects. However, the inclusion of non-lithium systems such as compressed air, liquid air, flywheel, molten salt, and even carbon dioxide-based thermal storage indicates a deliberate shift toward technological diversification and risk mitigation.

Project Breakdown and Implementation Outlook

The 81 lithium-ion storage projects account for the lion’s share of the 18.6GW, with most systems sized in the 100–400 megawatt (MW) range. Notable entries include:

• A 510MW/1020MWh shared storage station

• A 600MW/1800MWh flow battery project in its second phase

• A 500MW/1000MWh grid-forming lithium-ion battery plant

In the compressed air segment, two large-scale projects—one in Jinan's Zhangqiu District and another in Jining’s Sishui County—account for a combined 500MW and 2200MWh of storage. These systems are notable for their long-duration discharge capacity and potential grid inertia support.

The inclusion of specialized applications such as frequency regulation and multi-technology hybrid systems further reflects the province’s effort to align with national mandates for smarter and more flexible power systems. Projects like the 100MW flywheel storage station in Yantai exemplify high-power, short-duration technologies geared toward frequency modulation rather than energy shifting.

Industry Participation and Geographic Distribution

Dozens of private and state-backed firms feature in the list, ranging from established developers to newer entrants. Notably, investment activity is distributed across all major prefectures, including Dongying, Yantai, Zibo, Weifang, and Jining, suggesting an even regional deployment pattern that may help mitigate localized grid congestion and renewable curtailment.

Market Implications
The release of the 2025 project list marks a strong policy signal for Shandong’s commitment to accelerating energy storage deployment. Certain projects stand out for their strategic significance and policy positioning. Notably, the 200 MW/440 MWh flow battery project, the only flow-based system on the list, is set to benefit from Shandong’s “policy–technology–revenue” triple-guarantee mechanism. This suggests prioritized access to regulatory support, technical validation, and market-based revenue opportunities—positioning it as a provincial benchmark for long-duration storage.

More broadly, the diversity of technologies and application types included in the 18.6 GW docket offers a valuable testing ground for evaluating operational performance under varying grid scenarios. As the July 15 comment period draws to a close, attention will shift to project readiness assessments, financing strategies, and the mechanisms by which these projects will be integrated into Shandong’s evolving power market architecture.

For detailed entry list, refer to the official notice here:

China’s top economic and energy regulators have jointly released a sweeping policy directive to initiate the large-scale construction of “zero-carbon industrial parks,” marking a significant acceleration in the country’s pursuit of carbon neutrality and green industrial transformation.

Issued on June 30, 2025, by the National Development and Reform Commission (NDRC), the Ministry of Industry and Information Technology (MIIT), and the National Energy Administration (NEA), the policy—formally titled Notice on Launching the Construction of Zero-Carbon Industrial Parks (NDRC Environment and Resources [2025] No. 910))—lays out a coordinated plan to reshape industrial energy systems, promote low-carbon technologies, and develop replicable models for decarbonization across China’s vast network of industrial zones.

Coordinated Effort to Lead with Pilot Parks

The notice calls on local governments to recommend no more than two candidate parks by August 22, 2025, for inclusion in a first batch of national-level zero-carbon demonstration zones. Selection will consider factors such as local renewable energy resources, carbon reduction potential, and power supply security. The goal is to support regions with the right conditions to pioneer zero-carbon transitions, while establishing a foundation for wider adoption across the country.

Under the policy, local development and reform commissions (DRCs), in collaboration with MIIT and NEA counterparts, will assess park-level feasibility, conduct impact modeling, and submit formal applications based on a standardized outline. National authorities will then evaluate submissions based on industrial representativeness, carbon mitigation potential, and integrated demonstration value.

Strategic Context: Green Transformation with Chinese Characteristics

The directive comes amid China’s broader “dual carbon” strategy—its commitment to peak carbon emissions before 2030 and achieve carbon neutrality by 2060. Zero-carbon parks are positioned as foundational nodes within this long-term strategy, supporting both national carbon targets and regional economic upgrading.

While earlier policies focused on energy-intensive industries and emission reduction standards, the new directive shifts attention to place-based, system-level transformations. Industrial parks, which concentrate production, infrastructure, and energy loads, are seen as ideal testbeds for integrated decarbonization solutions.

Core Tasks: From Energy Structure to Industrial Synergy

The document outlines eight key task areas for implementation, ranging from energy transition and emissions management to infrastructure upgrades and technological innovation.

1. Energy System Restructuring:
Parks are encouraged to increase reliance on renewable energy through direct green power connections, local clean energy integration into distribution networks, and participation in green certificate trading. New models such as hydrogen-electric coupling and localized storage deployment are explicitly promoted.

2. Energy Efficiency and Carbon Management:
Industrial facilities within the parks are expected to establish energy and carbon management systems, retire outdated equipment, and upgrade to high-efficiency technologies. The policy supports the construction of “ultra-efficient” or “zero-carbon” factories where feasible.

3. Industrial Structure Optimization:
Zones are urged to pivot toward low-energy, high-value-added industries, fostering “green manufacturing with green energy.” Relocation of high-energy-consuming industries to resource-rich and energy-secure parks is also encouraged.

4. Resource Conservation and Circularity:
Parks must improve spatial planning, promote land-use efficiency, and enhance systems for waste heat, water, and material recycling. The development of industrial symbiosis and cascading energy utilization is prioritized.

5. Infrastructure Modernization:
Comprehensive upgrades to park infrastructure—including electricity, heat, gas, hydrogen, water, and environmental controls—are mandated. Standards for ultra-low or near-zero energy buildings and low-carbon transportation are introduced.

6. Technology Integration and Innovation:
The policy encourages collaborations among parks, enterprises, and research institutions to pilot scalable low-carbon technologies. Demonstration scenarios should be built around commercially viable solutions.

7. Digital Carbon Management:
Parks are to establish energy-carbon management platforms capable of real-time monitoring, forecasting, and load optimization. These platforms will underpin initiatives such as demand-side management and resource coordination.

8. Market and Institutional Reform:
The directive calls for broad stakeholder participation—including grid operators, energy service providers, and local governments—and experimentation with new models such as virtual power plants to enhance system flexibility and market integration.

Funding and Institutional Support

To ensure policy traction, the directive includes a robust set of enabling mechanisms. These include:

• Financial Incentives: Parks may access existing central funds and qualify for local government special bonds. Policy banks are encouraged to provide long-term credit for eligible projects, while qualified enterprises may issue bonds for construction.

• Talent and Expertise Support: External experts and institutions may be engaged to support carbon accounting, efficiency upgrades, and product carbon footprint certification.

• Streamlined Approvals: The policy signals possible adoption of single-window approval systems for multi-energy integration projects, along with piloting regional-level energy reviews and carbon assessments.

• Land and Resource Guarantees: Enhanced support is promised for land and sea-use approvals, particularly for new energy sources and supporting infrastructure within zero-carbon zones.

Oversight and Evaluation Framework

Implementation will follow a phased approach. Local DRCs will first submit applications for candidate parks. After central review and selection, the NDRC will announce the first cohort of national-level parks, which will then receive targeted guidance and troubleshooting support.

Each park will undergo a structured evaluation upon completion. Provincial authorities will lead self-assessments, followed by a formal national evaluation process based on a trial indicator system (provided in the policy annex). Parks that pass evaluation will earn the designation of “National Zero-Carbon Industrial Park.”

Outlook: Pilots First, Scale Later

While the policy provides clear direction and generous institutional support, challenges remain. These include aligning stakeholder incentives, ensuring data accuracy for carbon management, and translating demonstration success into scalable models.

Still, the move signals a decisive pivot toward systems-based decarbonization at the industrial park level—an approach with high potential for replicability and impact. As China navigates its complex energy transition, the success of these zero-carbon parks may provide a critical blueprint for industrial transformation across other emerging economies.

Developers accelerate construction as industry navigates foreign content restrictions and shifting clean energy priorities

The U.S. energy storage sector is expected to continue expanding after the enactment of the FY2025 Budget Act, which secures Investment Tax Credit (ITC) eligibility for storage projects commencing construction through the end of 2033. Amid changes to federal policy and evolving supply chain rules, developers are expediting project timelines to stay ahead of emerging compliance constraints.

Signed into law on July 4 during the Independence Day holiday, the legislation—branded by Republicans as the “One, Big, Beautiful Bill Act”—introduces sweeping reforms to federal clean energy incentives. While support for solar and wind has been significantly curtailed, the final law preserves robust incentives for storage, geothermal, biomass, and hydropower via a new technology-neutral ITC structure.

Incentive Structure Realigned: Solar and Wind Scale Back, Storage Stays Protected

The legislation effectively eliminates Sections 48E and 45Y tax credits for solar and wind installations. To retain residual incentives, these projects must either begin construction within a year of the bill’s passage or reach operational status by the close of 2027. Meanwhile, residential energy efficiency programs are scheduled to sunset by year-end, accompanied by a reduction in environmental research funding.

Energy storage, however, avoided a parallel rollback. The House-passed version initially proposed shortening ITC eligibility for storage, mirroring the limitations set for solar and wind. But during Senate deliberations, the original timeline was reinstated following Finance Committee revisions and vote-a-rama negotiations.

Under the updated framework, qualifying storage and other dispatchable technologies can receive a base ITC of 30% of capital expenditures. Projects that satisfy domestic content standards may unlock an additional 15% bonus, pushing the total potential tax credit to 45%.

“Construction Start” Benchmark Replaces Commissioning Date for ITC Eligibility

A key change introduced in the law is the replacement of the “placed in service” requirement with a more flexible “construction start” standard for determining ITC eligibility. This aligns with prior changes under the 2022 Inflation Reduction Act (IRA), providing developers with expanded planning options.

Projects that commence construction before 2033 qualify for the full ITC, with credit values dropping to 75% in 2034 and 50% in 2035. Industry observers point to this extended phase-down as a critical advantage that sets storage apart from other clean energy technologies now facing tighter timelines.

FEOC Provisions Drive Pre-2026 Construction Rush

Beginning in 2026, the law introduces new sourcing requirements tied to “foreign entities of concern” (FEOC). To qualify for the ITC, at least 55% of a project’s costs must originate from non-FEOC sources—a threshold that will rise to 75% by 2030. Battery cells, which make up roughly 52% of total storage system costs, are a key focus of this provision.

To navigate compliance, the Internal Revenue Service (IRS) is expected to issue new cost allocation tables by 2027. Until those are available, developers may reference existing safe harbor benchmarks used to determine domestic content bonus eligibility under current ITC rules.

Due to limited availability and elevated costs of non-Chinese battery cells, many developers are working to launch projects before the end of 2025 to avoid the stricter FEOC rules. Projects slated for later execution will need to reconfigure procurement strategies or face diminished credit access.

Domestic Battery Supply Remains a Bottleneck

Current domestic manufacturing capacity is not yet sufficient to meet projected demand for FEOC-compliant battery cells. Fluence is utilizing Tennessee-made AESC cells for a portion of its U.S. projects, while LG Energy Solution has initiated construction of a lithium iron phosphate (LFP) facility in Michigan. Meanwhile, startup Our Next Energy (ONE) has begun domestic LFP cell production, taking advantage of domestic content incentives.

Even with support from the Section 45X advanced manufacturing tax credit, the industry awaits detailed IRS guidance on applying FEOC criteria to domestically produced components. Until then, developers face supply limitations and ongoing uncertainty.

Trade Policy Clouded by Looming Tariff Expiration

U.S. tariffs on batteries imported from China—currently set at approximately 54%—are due to expire on August 12. The absence of clarity on whether these duties will be extended or modified is leading developers to accelerate purchases and construction while trade conditions remain stable.

Although some projects may be economically viable even without ITC support due to low-cost components from China, ongoing policy volatility and compliance risk are prompting many developers to pursue more secure, domestic-aligned supply chains.

Non-Lithium Alternatives Emerge, Face Cost Barriers

A range of alternative battery chemistries—including vanadium flow, zinc-based, and iron-air technologies—are gaining attention for their potential to meet long-duration energy storage (LDES) needs. These technologies may also help circumvent FEOC-related challenges by tapping into non-Chinese supply sources.

LDES applications are particularly relevant in states like California, Massachusetts, and New York, where policy incentives and market demand are aligned. However, cost competitiveness remains a key barrier. Lithium-ion batteries still enjoy strong economies of scale, making alternatives less attractive for large-scale deployment in the near term.

Policy Focus Shifts from Decarbonization to Grid Reliability

According to policy watchers, the current administration’s sustained support for energy storage is driven more by concerns over electric grid stability than by emissions reductions. Dispatchable resources like storage, geothermal, and nuclear are viewed as essential to maintaining power system reliability, which has become a central focus of federal energy strategy.

Despite the rollback of many climate-oriented subsidies, these technologies remain integral to the administration’s broader vision for a secure and resilient grid.

Outlook: Storage Maintains Strategic Position Amid Regulatory Shifts

While sweeping changes to federal clean energy policy have introduced new constraints for several sectors, energy storage retains a favorable position. A longer ITC phase-out schedule, expanded eligibility flexibility, and ongoing federal manufacturing incentives provide a runway for continued growth.

However, developers must act swiftly to navigate FEOC-related deadlines, tariff uncertainties, and domestic capacity bottlenecks. The sector’s success will depend on how effectively stakeholders can adapt to these shifting conditions and restructure their supply chains to align with evolving regulatory requirements.

Source: Xinhua News Agency

According to the Energy Bureau of Inner Mongolia Autonomous Region, China’s first interprovincial, long-distance, large-scale green hydrogen pipeline project—the Inner Mongolia Ulanqab to Beijing-Tianjin-Hebei Hydrogen Transmission Pipeline Demonstration Project—has recently received official approval for its Inner Mongolia section.

This pipeline is a national-level pilot demonstration project aimed at facilitating large-scale transmission of green hydrogen and exploring an integrated commercial operation model covering production, storage, transmission, and utilization of hydrogen energy. It also serves as a key green hydrogen outbound project in the preliminary implementation of Inner Mongolia’s hydrogen transmission network. The project is invested in and constructed by Sinopec Xinxing (Inner Mongolia) West-to-East Hydrogen Transmission New Energy Co., Ltd. Upon completion, it will significantly reduce the cost of green hydrogen transportation, further promote the consumption of green hydrogen, and support the full industrial chain development of hydrogen production, storage, transmission, and utilization in Inner Mongolia.

At present, Inner Mongolia is actively improving green hydrogen pipeline infrastructure. It has issued the country’s first provincial-level green hydrogen pipeline development plan and is planning to build a green hydrogen pipeline network featuring “one main line, two loops, and four outlets,” fully opening up both local consumption and outbound transmission channels for green hydrogen. Meanwhile, a relatively complete set of policies and management systems for green hydrogen pipeline construction, operation, and management has taken shape, and the construction and operation of green hydrogen pipelines have entered a normalized management phase.

Next, Inner Mongolia will align green hydrogen resources with market demand, strengthen green hydrogen trade cooperation with neighboring provinces and cities, and continue to advance green hydrogen pipeline construction. It aims to build hydrogen transmission infrastructure that serves major surrounding consumer markets and support the establishment of Inner Mongolia as a northern green hydrogen supply center and the country’s largest green hydrogen production and transmission base. (An Lumeng)

Core Data:
• In June, newly commissioned new energy storage reached 2.33GW/5.63GWh in China; for the first time, the “June 30” grid-connection peak cooled down.
• In the second quarter, newly commissioned new energy storage still exceeded previous years at 12.61GW/30.82GWh.
• Jiangsu’s new installed capacity exceeded 750MW, accounting for more than 35% of the national total.
• The average energy storage duration of new projects in Xinjiang, Inner Mongolia, and Qinghai exceeded 3.5 hours.
• Inner Mongolia saw 17 projects start construction in June, totaling 8.2GW/33.1GWh.
• The full-year new installed capacity for large-scale energy storage in 2025 is expected to exceed 43GW.

According to incomplete statistics from the CNESA DataLink Global Energy Storage Database, in June 2025, newly commissioned new energy storage projects in China reached a total of 2.33GW/5.63GWh, down 65%/66% year-on-year and 71%/72% month-on-month.

It can be seen that, due to the “rush installation” of new energy, the grid-connection surge for new energy storage projects in the first half of the year shifted forward to before the “May 31” node, and the “June 30” node’s grid-connection activity declined for the first time in history. Although new installations in June showed negative growth, second-quarter additions still exceeded those of previous years, reaching 12.61GW/30.82GWh, a year-on-year increase of 24%/27%.

Figure 1: New Commissioned Capacity of New Energy Storage Projects in China from January to June 2025
Data Source: CNESA DataLink Global Energy Storage Database
https://www.esresearch.com.cn/
Note: Year-on-year compares with the same period last year; month-on-month compares with the previous statistical period.

Starting this month, we will publish monthly updates on grid-side and user-side new energy storage projects by application market. The following is the installed capacity status of grid-side new energy storage projects in June.

In June, newly installed grid-side capacity was 2.00GW/4.79GWh, down 68%/64% year-on-year and 74%/76% month-on-month. Of this, grid-side new installations were 1.39GW/3.56GWh, down 74%/69% year-on-year, all of which were independent storage; power-side new installations were 0.61GW/1.23GWh, down 33%/42% year-on-year, with nearly 90% of new installations coming from new energy configuration sub-scenarios.

Figure 2: Application Distribution of Newly Commissioned New Energy Storage Projects in June 2025 (MW%)
Data Source: CNESA DataLink Global Energy Storage Database
https://www.esresearch.com.cn/

The newly commissioned grid-side new energy storage projects in June exhibited the following characteristics.

By Region:
Jiangsu leads in newly installed capacity nationwide

This month, Jiangsu’s newly installed capacity exceeded 750MW, accounting for more than 35% of the national total; among this, newly installed independent storage accounted for 43% of the national grid-side new capacity.

On one hand, construction of independent storage power stations in Jiangsu accelerated in the first half of the year; all independent storage power stations commissioned in June were started and commissioned within the first half of the year, with the shortest construction time being only 81 days (from commencement to commissioning).

On the other hand, on June 1, 2025, Jiangsu officially launched trial operation of long-cycle settlement in the electricity spot market. The “Jiangsu Electricity Spot Market Operation Rules (Version 2.0)” stipulate that grid-side storage voluntarily participates in the spot market, and during participation, is no longer settled based on the charging and discharging prices defined in the “Notice by the Provincial Development and Reform Commission on Accelerating the High-Quality Development of New Energy Storage Projects in Our Province” (Su Fa Gai Neng Yuan Fa [2024] No. 775). Grid-side storage participates in the spot market through “quantity bidding and pricing” on a per-station basis.

Figure 3: Provincial Distribution of New Grid-Side New Energy Storage Projects in China in June 2025 (MW%)
Data Source: CNESA DataLink Global Energy Storage Database
https://www.esresearch.com.cn/

By Energy Storage Duration:
Average durations in Xinjiang, Inner Mongolia, and Qinghai exceed 3.5 hours

From a regional perspective, the average energy storage duration of newly commissioned grid-side storage projects in most provinces such as Jiangsu, Zhejiang, and Yunnan was around 2 hours. In Xinjiang, Inner Mongolia, and Qinghai, the average energy storage duration exceeded 3.5 hours, with all newly commissioned projects in Inner Mongolia being 4-hour storage projects.

According to official information, as of May this year, the proportion of new energy installed capacity in Xinjiang, Inner Mongolia, and Qinghai exceeded half of total local generation capacity, leading to higher energy storage duration requirements for new energy storage projects.

Figure 4: Average Energy Storage Duration of New Grid-Side New Energy Storage Projects in China in June 2025 (Unit: Hours)
Data Source: CNESA DataLink Global Energy Storage Database
https://www.esresearch.com.cn/

By Technology:
Lithium-ion dominates, non-lithium technologies accelerating deployment

Newly commissioned projects were primarily based on electrochemical energy storage technology, with lithium iron phosphate batteries accounting for 89% of installed power capacity. For non-lithium technologies, two 100MW-class all-vanadium flow battery energy storage projects were commissioned, with flow battery technology accounting for 10% of installed power capacity. Frequency regulation stations using lithium iron phosphate + flywheel hybrid storage and grid-side stations combining lithium iron phosphate + aqueous flow batteries were also commissioned.

By Energy Storage Planning:
Demonstration project deployment for new energy storage accelerating

Among the independent new energy storage projects included in the “2025 New Energy Storage Special Action Implementation Project List” and the “First Batch of Independent New Energy Storage Construction Projects List in 2025” released by Inner Mongolia in the first half of the year, 17 started construction in June, totaling 8.2GW/33.1GWh. These projects involve multiple technology routes including lithium-ion batteries, flow batteries, solid-state batteries, and compressed air energy storage.

Guizhou Province included 24 grid-side independent new energy storage projects—such as the 500MW/1000MWh shared energy storage station in Zhenning Autonomous County—into its “2025 Provincial Key Projects and Major Engineering Projects” list, with a total scale of 2.7GW/5.5GWh.

Yangquan City in Shanxi released the “Yangquan City Carbon Peaking Implementation Plan for the Energy Sector,” prioritizing construction of grid-side new energy storage projects including the Hongshengtong 500MW/1000MWh independent storage project, with a total scale exceeding 1.1GW.

Market Outlook:
Full-year new grid-side installations expected to exceed 43GW

According to CNESA’s incomplete statistics, more than 23GW of grid-side new energy storage was under construction in the first half of the year. Additionally, over 10GW of provincial new energy storage demonstration projects still in the planning stage are expected to be connected to the grid by the end of 2025. Assuming 80% of these projects are completed and commissioned in the second half of the year, new grid-side installations for the year are expected to exceed 43GW (compared with 41GW for all of last year).

Source: National Energy Administration (NEA)

Recently, many regions across China have experienced hot and humid weather. Coupled with the dual driving forces of economic growth, power loads in various regions have risen rapidly. On July 4, the national maximum power load reached 1.465 billion kilowatts, an increase of approximately 200 million kilowatts from the end of June, setting a new historical high (compared to 1.451 billion kilowatts in 2024), and an increase of nearly 150 million kilowatts compared with the same period last year. Since the beginning of summer, the power grids in East China, eastern Inner Mongolia, Jiangsu, Anhui, Shandong, Henan, and Hubei have all reached historical highs.

At present, the national power supply remains generally stable and orderly. According to the China Meteorological Administration, from July 4 to 10, regions including Huanghuai, Jianghan, and Jiangnan will experience sustained high temperatures, with some areas reaching or exceeding historical extreme values for the same period. Power loads in East China and Central China are expected to continue rising, further driving nationwide power load growth. The National Energy Administration will closely monitor weather changes and the power supply-demand situation, guiding localities and power enterprises to ensure stable and full operation of generating units, coordinate inter-provincial and inter-regional power balance, promptly resolve emerging issues, and make every effort to ensure electricity supply for people to stay cool during the summer, fully supporting high-quality economic and social development.

Source: Xinhua Daily

According to State Grid, due to the ongoing high temperatures, as of July 7, Jiangsu’s power grid load has broken historical records for the third time this year, reaching 152 million kilowatts. On July 6, under the unified command of the Power Dispatch and Control Center of State Grid Jiangsu Electric Power Co., Ltd., a total of 93 new-type energy storage stations across the province discharged electricity to the grid during the evening peak, with a maximum discharge power of 7.14 million kilowatts, achieving the largest centralized dispatch of new-type energy storage in China.

New-type energy storage is known as a “super power bank,” capable of discharging power during peak demand periods for peak regulation, and charging during off-peak periods to aid the consumption of new energy.

On the evening of the 6th, to support the evening peak of grid electricity usage, a total of 64 grid-side and 29 power-side energy storage stations participated in the centralized discharge. The total participating capacity reached 7.248 million kilowatts, and the actual maximum dispatch scale was 7.14 million kilowatts. This set a new record in centralized dispatch scale, marking a 56.9% year-on-year increase compared to the centralized dispatch of 4.55 million kilowatts of new-type energy storage last summer.

In this centralized dispatch of new-type energy storage, State Grid Jiangsu Electric Power issued discharge instructions to more than 7 million kilowatts of new-type energy storage through its next-generation dispatch support system during peak demand, with a maximum capacity sufficient to meet the one-hour electricity needs of approximately 48 million households.

While it may appear simple, the timing of charging and discharging must be carefully chosen. Discharging, while considering urban electricity demand, must also strive to enable energy storage projects to generate revenue. “Spatially, most of Jiangsu’s energy storage projects are located in northern Jiangsu, while electricity demand is concentrated in southern Jiangsu. The electricity peak in southern Jiangsu occurs during the day, while in northern Jiangsu it occurs at night. Therefore, energy storage can act as a ‘spatiotemporal regulator,’” explained Qiu Chenguang, Director of Dispatch Operation at the Dispatch and Control Center of State Grid Jiangsu Electric Power. Jiangsu’s current installed capacity of new-type energy storage is 7.616 million kilowatts, ranking fourth nationwide, and includes various forms such as electrochemical energy storage and salt cavern compressed air energy storage. (Ni Min)