Summary:

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### **1. PETITION OVERVIEW**

* **Petitioner:** Himachal Pradesh Power Transmission Corporation Limited (HPPTCL)
* **Respondents:** Himachal Pradesh State Electricity Board Limited (HPSEBL) and Others
* **Subject:** A petition filed under the **Electricity Act, 2003** and relevant CERC regulations for:
1. **Truing up** of the transmission tariff for the **2019-24** period (adjusting past tariffs based on actual costs).
2. **Determination** of the transmission tariff for the **2024-29** period (setting future tariffs).
* **Assets Involved:** The petition pertains to **three (3) Inter-State Transmission System (ISTS) assets** owned by HPPTCL.

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### **2. PROCEEDINGS & COMMISSION’S DIRECTIONS**

During the hearing, the Petitioner’s counsel confirmed the petition’s purpose. The Commission then issued the following procedural and substantive directions:

**A. Procedural Timeline:**
1. **Notice** to be issued to all Respondents.
2. **Respondents** must file their **replies (on affidavit) within two weeks**, with an advance copy to HPPTCL.
3. **HPPTCL** may then file its **rejoinder within one week**.

**B. Specific Information Sought from HPPTCL (on affidavit within two weeks):**
The Commission directed HPPTCL to provide the following critical documents and justifications:
1. **Justification for Weighted Average Rate of Interest (WAROI):** HPPTCL must explain its use of a **10% WAROI** in its calculations.
2. **Tax Documentation:** Submission of **Assessment Orders or Income Tax Returns** for Minimum Alternate Tax (MAT) for Financial Years **2022-23 and 2023-24**.
3. **Detailed Note on Disputed Financial Components:** A comprehensive explanation claiming:
* **Interest on Loan (IoL)** for Asset-1.
* **Return on Equity (RoE)** for all assets in this petition.
* **Critical Context:** The Commission had previously **disallowed** these very components (IoL & RoE) in its past orders dated **16.5.2016 (Petition 119/TT/2014)** and **27.9.2021 (Petition 305/TT/2020)**. HPPTCL must now justify why these claims should be reconsidered.
4. **Auditor’s Certificates:** Submission of auditor-certified statements for the assets covering both the **2019-24 and 2024-29 tariff periods**.

**C. Next Hearing Date:** The petition is scheduled for the next hearing on **19 February 2026**.

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### **3. KEY BUSINESS & REGULATORY IMPLICATIONS**

* **Regulatory Scrutiny:** CERC is subjecting HPPTCL’s tariff claims to **rigorous scrutiny**, especially on financial parameters that have been contentious in the past.
* **Critical Financial Disputes:** The core of the inquiry revolves around **Interest on Loan (IoL)** and **Return on Equity (RoE)**, which are major components of the tariff. HPPTCL’s ability to successfully justify these claims, contrary to past rejections, will significantly impact the final approved tariff and its revenue.
* **Data-Driven Justification:** The Commission demands **concrete evidence and detailed justifications** (WAROI rationale, tax proofs, auditor certifications) rather than mere claims, emphasizing **prudence and transparency**.
* **Historical Precedent:** HPPTCL faces an uphill task as it must argue against the **Commission’s own past decisions** that disallowed similar claims. This indicates a potentially significant regulatory hurdle.
* **Impact on Tariff:** The outcome of this petition will determine the **transmission charges** that HPPTCL can levy on users (like HPSEBL) for using its three ISTS assets for the next five years (2024-29) and will settle accounts for the previous five years (2019-24).

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Summary:

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### **1. PROCEEDINGS & COMMISSION’S DIRECTIONS**

After hearing PGCIL’s representatives, the Commission issued the following procedural directions:

**A. Timeline for Submissions:**
1. **Respondents** (State Utilities) to file their **replies within two weeks**, with an advance copy to PGCIL.
2. **PGCIL** may file its **rejoinder within two weeks** thereafter.

**B. Specific Information Sought from PGCIL (on Affidavit within two weeks):**
The Commission directed PGCIL to provide detailed, asset-specific information for most petitions. The **common themes** across the data requests are:

1. **Detailed Cost Breakdowns:**
* **Item-wise unit cost** for claimed Additional Capital Expenditure (ACE) related to asset replacement.
* **Element-wise/Party-wise break-up** of capital costs (as on 31.3.2019) and claimed ACE.

2. **Historical Comparison & Justification:**
* **Comparison tables** showing ACE **allowed in previous tariff orders vs. claimed now** for 2019-24, with justifications for any variations.
* **Reconciliation of cost overruns** (e.g., Petition 525/TT/2025 notes a variation of ₹1117.53 lakh).

3. **Regulatory Form Compliance:**
* Submission of specific **Forms (e.g., Form-5, 7B, 9C, 9E, 13)** related to plant & machinery cost, depreciation, and tariff calculations for both 2019-24 and 2024-29 periods.

4. **Technical & Economic Justification for Future Capex (2024-29):**
* **Basis, technical justification, and cost-benefit analysis** for ACE/De-capitalization claimed under **Regulation 25(2) of the 2024 Tariff Regulations**.

5. **Supporting Documentation:**
* **Certificates of obsolescence** from OEMs or competent authorities for replaced equipment.
* **Minutes of relevant committee meetings** approving projects (e.g., NERPC/TCC for Kumarghat substation in Petition 539/TT/2025).
* **Liquidated damages recovery statements** and **initial spares discharge statements**.

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### **2. KEY BUSINESS & REGULATORY IMPLICATIONS**

* **Regulatory Scrutiny:** The Commission is conducting a **detailed, granular review** of PGCIL’s capital expenditures, both past (truing up) and future (tariff determination). The focus is on **prudence, justification, and cost-effectiveness**.
* **Focus on ACE:** A significant portion of the inquiry revolves around **Additional Capital Expenditure (ACE)**, indicating scrutiny of project cost overruns, replacements, and upgrades.
* **Transparency & Accountability:** The directives emphasize **transparency** through standardized formats (tables, forms), comparisons with past approvals, and demand for third-party certificates (OEM).
* **Procedure:** The process follows a standard regulatory timeline: **Petition → Hearing → Directions for Information → Respondent’s Reply → Rejoinder → Final Order**.
* **Subject Matter:** The petitions cover a wide range of transmission assets—from system strengthening schemes to project-specific systems—highlighting PGCIL’s ongoing role in national grid development and the subsequent periodic tariff resets.
* **Next Steps:** The matters are **reserved for order** after compliance with the above directions. The final tariff orders will determine the revenue PGCIL can recover from beneficiary states for using these transmission assets for the next five years.

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Summary:

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### **1. BACKGROUND & CONTEXT**

HAPL operates a manufacturing plant in Solapur, Maharashtra, and is an MSEDCL consumer (Consumer No. 341629059470). It had installed a **983 kW rooftop solar system** under a **Net Metering Agreement** with MSEDCL (executed August 2022). HAPL also entered into **Power Purchase Agreements (PPAs)** for captive renewable energy supply through open access.

The dispute arose because after availing **Open Access** for its offsite renewable power, MSEDCL **refused to allow Net Metering** for HAPL’s rooftop solar generation, instead treating it on a **Gross Metering basis** from November 2023 onward. This resulted in significant financial loss to HAPL.

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### **2. HAPL’S MAIN PRAYERS**

1. Direct MSEDCL to treat HAPL’s rooftop solar system under **Net Metering** arrangement.
2. Grant **retrospective adjustment** of amounts paid from the start of Open Access (November 2023) based on Net Metering.

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### **3. KEY ARGUMENTS OF HAPL**

– HAPL is eligible under **Regulation 3.2** of the Distribution Open Access (DOA) Regulations (Contract Demand > 1 MVA).
– The **DOA (Second Amendment) Regulations 2023** (effective 10 November 2023) **deleted the 8th proviso** that earlier mandated Gross Metering during Open Access.
– New **Regulation 3.4** explicitly permits simultaneous Open Access and Net Metering for eligible consumers.
– MSEDCL’s continued Gross Metering billing is **contrary to the amended regulations**.
– HAPL had repeatedly requested MSEDCL to allow Net Metering (Jan–July 2025) but received no response.
– MSEDCL’s reliance on its own **Clarification Petition (Case No. 232 of 2024)** is misplaced as the regulation is already in force.

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### **4. MSEDCL’S DEFENSE**

– At the time of commissioning (Nov 2022), the **DOA (First Amendment) Regulations 2019** applied, which required Gross Metering during Open Access.
– The 2023 Amendment is **prospective**, and HAPL did not apply for **Green Energy Open Access (GEOA)** through the proper **Nodal Agency (MSLDC)** as required.
– MSEDCL filed **Case No. 232 of 2024** seeking clarification on the interpretation of Regulations 3.3 and 3.4, which is still pending.
– Until clarity is provided, existing billing (Gross Metering) continues.
– HAPL’s failure to comply with GEOA procedure renders its claim invalid.

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### **5. MERC’S ANALYSIS & RULINGS**

#### **a) Regulatory Framework (Issue a)**
– The **8th proviso of the 2019 Regulations** (requiring Gross Metering during Open Access) was **deleted** in the 2023 Amendment.
– **Regulation 3.4** now explicitly allows **simultaneous Open Access and Net Metering**.
– Since HAPL’s Open Access started in **November 2023**, billing **must follow Net Metering** from 10 November 2023 onward.

#### **b) Compliance with Open Access Procedure (Issue b)**
– MSEDCL delayed implementing the 2023 Amendment until directed by MERC in **Case No. 129 of 2024** (Sept 2024).
– HAPL applied to MSEDCL (as Nodal Agency under earlier rules), and MSEDCL approved monthly Open Access.
– **MSEDCL’s own failure to implement the new system cannot deny HAPL its rightful benefit.**

#### **c) Overlap with MSEDCL’s Clarification Petition (Issue c)**
– In **Case No. 197 of 2024** (July 2025), MSEDCL had already **agreed to provide Net Metering adjustments** subject to the outcome of its clarification petition.
– MERC held that **MSEDCL cannot discriminate** between similarly placed consumers.
– The regulation is **in force**, and MSEDCL must comply.

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Summary:

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### **1. SCOPE OF WORK (SPD RESPONSIBILITIES)**
– **End-to-End Development**: Design, supply, installation, commissioning, O&M for 25 years.
– **Civil & Structural Works**: Roof strengthening, permanent ladders, drainage, waterproofing.
– **Grid Connectivity**: Evacuation up to BHEL’s substation, including transformers, cables, metering infrastructure.
– **Safety & Monitoring**: CCTV, monkey protection, SCADA, weather monitoring, RFID tagging of modules.
– **Compliance**: All statutory clearances, permits, labor laws, GST, insurance.
– **Water & Auxiliary Power**: Water provided by BHEL at chargeable rates; auxiliary power drawn from grid and netted off.
– **Site Handover**: After 25 years, SPD must either remove plant or hand over in working condition to BHEL at no cost.

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### **2. BIDDING PROCESS & ELIGIBILITY**
– **Bid System**: Single-stage, two-envelope (Techno-Commercial & Financial).
– **Eligible Entities**: Indian companies, consortia, foreign companies (must form Indian SPV with ≥51% holding). LLPs not eligible.
– **Pre-Qualification Criteria**:
– **Technical**: Minimum 500 KWp rooftop/land solar plant installed and operational for ≥1 year in last 7 years.
– **Financial**:
– Net Worth ≥ ₹133.64 Lakhs.
– Avg. Annual Turnover ≥ ₹267 Lakhs (last 3 years) OR Line of Credit ≥ ₹167 Lakhs.
– **Experience**: Must provide PO/work completion certificate.
– **EMD**: ₹5 Lakhs (valid 6 months).
– **Performance Bank Guarantee**: ₹33.8 Lakhs (₹20.8L for Jhansi, ₹13L for Varanasi) before PPA signing.

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### **3. BID EVALUATION & SELECTION**
– **Techno-Commercial Evaluation**: Compliance with NIT, site visits, document verification.
– **Financial Bid**: Tariff quoted up to two decimals.
– **Reverse Auction**: E-auction for shortlisted bidders (BHEL may decide not to conduct).
– **Selection Criteria**: Lowest tariff (L1) selected; tie-breaker based on earlier bid timestamp.

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### **4. KEY CONTRACTUAL & COMMERCIAL TERMS**
– **Tariff**: Fixed for 25 years, inclusive of all taxes (except future Change in Law).
– **Change in Law**: Compensation mechanism via Appropriate Commission; excludes corporate tax changes.
– **Capacity Utilization Factor (CUF)**: Minimum CUF as per Annexure-J (declining from 16.85% in Year 1 to 13.50% in Year 25).
– **Generation Shortfall**: SPD pays compensation = (DISCOM tariff – PPA tariff) × shortfall energy.
– **Excess Generation**: BHEL may purchase excess unless refused; SPD cannot sell to third parties without BHEL’s written consent.
– **Commissioning Timeline**: 6 months from PPA effective date.
– **Delay Penalties**:
– Up to 1 month: 20% PBG encashed.
– 1–3 months: Remaining 80% PBG encashed.
– Beyond 3 months: BHEL may terminate PPA.
– **Financial Closure**: Within 3 months of PPA; delay charges @ ₹1000/MW/day + GST.

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### **5. LEGAL & STATUTORY HIGHLIGHTS**
– **GST Compliance**: Mandatory; invoices must match GSTR-2B for credit.
– **Statutory Duties**: PF, ESI, Bonus, Gratuity, Labour Welfare Fund, etc., as per BHEL norms.
– **Dispute Resolution**:
– First: Amicable settlement via BHEL’s Designated Engineer.
– Then: Conciliation as per BHEL Conciliation Scheme 2018.
– Arbitration: Through India International Arbitration Centre (IIAC), New Delhi (for disputes < ₹10 Cr).
– **Jurisdiction**: Exclusive courts in Jhansi/Varanasi.
– **Liability Cap**: Limited to contract price except for fraud, willful misconduct, or IP infringement.

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### **6. DOCUMENTATION & FORMATS**
– **Mandatory Formats Provided**:
– Covering Letter, Power of Attorney, Financial Requirement, PBG, Board Resolutions, Consortium Agreement, Technology Declaration, No Deviation Certificate, etc.
– **Submission**: Online via GePNIC portal; digital signature required.

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### **7. TECHNICAL SPECIFICATIONS**
– **Modules**: Must be from MNRE’s Approved List of Models & Manufacturers.
– **Warranty**: Modules – 90% output after 10 years, 80% after 25 years; Inverters – 5 years warranty.
– **Standards**: IEC/BIS compliance for modules, inverters, cables, connectors.
– **Monitoring**: SCADA, real-time data to BHEL, RFID tracking for modules.
– **Disposal**: E-waste rules compliance for end-of-life modules.

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HPCL issue Tender for Site Works for Solar Plant Installation

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In Short : Telangana has set an ambitious target of achieving 139 GW of power generation capacity by 2047 to support its vision of building a $3 trillion economy. The strategy focuses on expanding renewable energy, strengthening grid infrastructure, improving energy efficiency, and ensuring reliable power supply to drive industrial growth, urban development, and long-term economic sustainability.

In Detail : Telangana has outlined a long-term energy roadmap aimed at achieving 139 GW of installed power generation capacity by 2047, aligning with its broader vision of becoming a $3 trillion economy. This ambitious target reflects the state’s recognition that reliable and affordable electricity is a fundamental driver of economic growth, industrial competitiveness, and social development.

Rapid industrialization, urban expansion, digital transformation, and rising living standards are expected to significantly increase electricity demand in the coming decades. Sectors such as manufacturing, information technology, electric mobility, data centers, and infrastructure development will place growing pressure on the power system, making large-scale capacity expansion a strategic necessity.

Renewable energy is expected to form a major component of Telangana’s future power mix. The state plans to scale up solar, wind, and other clean energy sources to reduce dependence on fossil fuels and meet sustainability goals. This transition also aligns with national climate commitments and supports the shift toward a low-carbon development pathway.

Solar energy is likely to play a dominant role due to Telangana’s strong solar potential and favorable geographic conditions. Utility-scale solar parks, rooftop installations, and distributed generation systems are expected to expand rapidly, contributing significantly to the state’s long-term capacity targets and improving energy access across urban and rural areas.

In parallel, the state is expected to invest heavily in grid infrastructure and transmission capacity. Upgrading substations, expanding transmission corridors, and deploying smart grid technologies will be essential to handle higher power flows and integrate large volumes of renewable energy into the system efficiently and reliably.

Energy storage and flexible generation resources will also become increasingly important in achieving the 139 GW target. As renewable penetration rises, battery storage systems and hybrid projects will help balance supply and demand, manage intermittency, and ensure round-the-clock power availability for critical sectors.

From an economic perspective, the expansion of power capacity will act as a catalyst for industrial growth and investment. Reliable electricity supply reduces operational risks for businesses, attracts domestic and foreign investors, and supports the development of energy-intensive industries such as manufacturing, logistics, and digital services.

Policy support and regulatory reforms will play a key role in realizing this vision. Long-term planning, investor-friendly policies, transparent tariff mechanisms, and public-private partnerships will be necessary to mobilize capital and accelerate project development across conventional and renewable energy segments.

Overall, Telangana’s target of 139 GW power generation capacity by 2047 reflects a forward-looking and growth-oriented energy strategy. By aligning power sector development with economic ambitions, the state is positioning itself to build a resilient, sustainable, and globally competitive economy powered by a modern and diversified energy system.

In Short : Gujarat has emerged as India’s leading state in renewable energy capacity, according to Deputy Chief Minister Harsh Sanghavi. The state’s strong focus on solar, wind, and hybrid projects, supported by progressive policies and infrastructure development, has positioned Gujarat at the forefront of India’s clean energy transition and sustainable growth agenda.

In Detail : Gujarat has established itself as the leading state in renewable energy development in India, reflecting its long-standing commitment to clean and sustainable power generation. According to Deputy Chief Minister Harsh Sanghavi, the state now tops the country in renewable energy capacity, highlighting the success of its strategic investments and policy-driven approach.

The state’s leadership in renewable energy is driven primarily by large-scale deployment of solar and wind power. Gujarat’s geographic advantages, including high solar irradiation and strong wind corridors, have enabled it to develop some of the country’s largest renewable energy projects, making it a major contributor to India’s green power capacity.

Solar energy forms a central pillar of Gujarat’s renewable strategy. The state has promoted utility-scale solar parks, rooftop solar systems, and decentralized solar installations across urban and rural areas. These initiatives have not only increased generation capacity but also improved energy access and reduced dependence on conventional power sources.

Wind energy has also played a significant role in Gujarat’s renewable growth. The state has been an early mover in wind power development, with extensive onshore wind farms and increasing interest in hybrid wind-solar projects that optimize land use and grid connectivity. This diversified renewable portfolio strengthens overall system resilience.

Policy support has been a key enabler of Gujarat’s success. Investor-friendly regulations, streamlined approval processes, and long-term renewable energy policies have attracted private sector participation and accelerated project implementation. These measures have created a stable and predictable environment for renewable energy developers.

Infrastructure development has further supported the state’s clean energy expansion. Investments in transmission networks, substations, and grid integration technologies have enabled efficient evacuation of renewable power from generation sites to demand centers, ensuring minimal losses and improved system reliability.

Gujarat’s renewable leadership has also generated significant economic benefits. The sector has created employment opportunities, attracted domestic and foreign investment, and supported the growth of allied industries such as equipment manufacturing, engineering services, and clean technology innovation.

From an environmental perspective, the expansion of renewable energy has helped Gujarat reduce carbon emissions and improve air quality. Increased use of clean power supports national climate goals and contributes to India’s commitment to achieving long-term sustainability and energy security.

Overall, Gujarat’s position as the top renewable energy state reflects a comprehensive and future-oriented energy strategy. Through a combination of natural advantages, strong policy frameworks, and sustained investment, the state has emerged as a model for renewable energy development and a key driver of India’s clean energy transition.

In Short : Around 740 households in Tripura are earning additional income by selling surplus solar power to the electricity grid. The initiative highlights the success of rooftop solar adoption and net metering policies, enabling consumers to become energy producers, reduce electricity bills, and contribute to clean energy generation and decentralized power systems.

In Detail : Tripura has emerged as a promising example of decentralized renewable energy adoption, with around 740 households now earning income by selling excess solar power to the electricity grid. This development reflects the growing acceptance of rooftop solar systems and the effectiveness of supportive policies that encourage consumer participation in clean energy generation.

The households have installed rooftop solar photovoltaic systems under government-supported programs aimed at promoting renewable energy at the consumer level. These systems allow households to generate electricity for their own use and export surplus power to the grid, transforming consumers into “prosumers” within the energy ecosystem.

Net metering plays a central role in enabling this model. Through net metering mechanisms, electricity exported to the grid is measured and credited against the household’s power consumption, allowing users to receive financial compensation or bill reductions based on the amount of energy they supply.

This arrangement provides direct economic benefits to households by reducing monthly electricity expenses and creating a supplementary income stream. Over time, the savings and earnings can help recover the initial investment in solar installations, making rooftop solar a financially attractive option for residential consumers.

From a system perspective, decentralized rooftop solar reduces pressure on centralized power plants and transmission networks. Local generation helps lower peak demand, reduces transmission losses, and improves overall grid efficiency, especially in geographically dispersed or remote regions.

The initiative also contributes to environmental sustainability by increasing the share of clean energy in the state’s power mix. Each rooftop system reduces reliance on fossil fuel-based electricity, leading to lower carbon emissions and improved air quality at the local level.

The success of these households demonstrates the importance of policy support, financial incentives, and public awareness in driving renewable adoption. Subsidies, simplified approval processes, and technical assistance have played a crucial role in encouraging residents to invest in solar power.

Beyond individual benefits, the program supports broader socio-economic development. It promotes energy self-reliance, encourages community-level participation in clean energy, and builds local capacity in solar installation, maintenance, and technical services.

Overall, the experience of 740 households in Tripura earning income from rooftop solar power highlights the transformative potential of decentralized renewable energy. It shows how clean energy can simultaneously deliver economic empowerment, energy security, and environmental sustainability at the grassroots level.

In Short : Soaring silver prices are creating cost pressures for solar manufacturers, prompting efforts to reduce or replace silver usage in photovoltaic technologies. As silver is a critical input for solar cells, companies are exploring alternative materials, efficiency improvements, and new manufacturing processes to control costs while maintaining performance and supporting large-scale solar deployment.

In Detail : The sharp rise in global silver prices has become a growing concern for the solar industry, as silver is a key raw material used in photovoltaic cell manufacturing. Solar firms are increasingly facing higher production costs, which could impact project economics, equipment pricing, and long-term profitability if material dependency is not addressed.

Silver is primarily used in the conductive paste that forms electrical contacts in solar cells, enabling efficient flow of electricity. Although the amount of silver per cell has reduced over the years through technological improvements, the scale of global solar deployment means overall demand for silver continues to rise significantly.

With silver prices reaching multi-year highs, manufacturers are under pressure to optimize material usage. Rising input costs can reduce margins for module producers and increase capital expenditure for solar developers, particularly in price-sensitive markets where competitive tariffs leave little room for cost escalation.

To manage these risks, solar companies are investing in research and development to reduce silver content in solar cells. Techniques such as thinner conductive lines, improved cell architectures, and more precise manufacturing processes are helping minimize silver usage without compromising electrical efficiency.

Some firms are also exploring alternative materials to partially or fully replace silver. Copper, aluminum, and other conductive metals are being tested as potential substitutes, although challenges remain in terms of durability, efficiency, corrosion resistance, and long-term performance under harsh operating conditions.

Technological innovation is playing a crucial role in this transition. Advanced cell designs such as TOPCon, heterojunction, and back-contact technologies allow more efficient use of conductive materials, enabling manufacturers to achieve higher power output with lower precious metal consumption.

From a strategic perspective, reducing silver dependence is also about long-term supply security. Silver is used across multiple industries, including electronics, electric vehicles, and investment markets, making it vulnerable to supply constraints and speculative price movements that can disrupt solar manufacturing plans.

Policy and market dynamics further influence this shift. As governments push for rapid renewable energy expansion, keeping solar affordable is essential for achieving climate targets. Material cost control becomes a critical factor in maintaining the competitiveness of solar power compared to other energy sources.

Overall, the solar industry’s efforts to cut or replace silver usage reflect a broader trend toward material efficiency and technological resilience. By reducing reliance on expensive and volatile inputs, solar manufacturers can protect project economics, strengthen supply chains, and ensure the continued scalability of solar energy in a rapidly evolving global energy landscape.

In Short : Max Healthcare has signed a 4 MW solar power purchase agreement with Sunsure Energy, marking a significant step toward reducing its carbon footprint and improving energy sustainability. The partnership will enable Max Healthcare to source clean electricity for its operations, lower energy costs, and support India’s broader transition toward renewable energy in the healthcare sector.

In Detail : Max Healthcare’s decision to sign a 4 MW solar power purchase agreement with Sunsure Energy reflects the growing role of renewable energy in the healthcare sector. As hospitals and healthcare facilities operate round the clock and consume large amounts of electricity, shifting to clean energy sources has become both an environmental responsibility and a strategic business decision.

The agreement allows Max Healthcare to procure solar power through a long-term arrangement, ensuring access to reliable and cost-effective clean electricity. Such power purchase agreements provide stability in energy costs and protect organizations from future fluctuations in conventional power tariffs, which is particularly important for energy-intensive sectors like healthcare.

For Sunsure Energy, the partnership strengthens its presence in the commercial and industrial renewable energy segment. By supplying solar power to a leading healthcare provider, Sunsure demonstrates the viability of solar solutions for critical infrastructure that requires uninterrupted and dependable power supply.

The 4 MW solar capacity is expected to significantly reduce Max Healthcare’s carbon emissions by replacing a portion of conventional grid electricity with renewable power. This contributes directly to the company’s sustainability objectives and supports broader environmental, social, and governance commitments within the corporate healthcare ecosystem.

From an operational perspective, access to clean energy enhances long-term resilience for healthcare facilities. Solar power helps reduce dependence on fossil fuel-based electricity and improves energy security, which is especially important for hospitals where power reliability is directly linked to patient safety and service continuity.

The partnership also highlights a broader trend of private sector participation in India’s renewable energy transition. Increasingly, large institutions are adopting solar power through open access and corporate PPAs, creating new demand drivers beyond government-led renewable procurement programs.

In addition to environmental benefits, the agreement is likely to generate economic advantages. Lower energy costs over time can free up financial resources for healthcare providers, allowing them to reinvest savings into medical infrastructure, technology upgrades, and improved patient care services.

Policy support and regulatory frameworks have played a key role in enabling such partnerships. Open access regulations, renewable energy incentives, and supportive state policies have made it easier for corporate consumers to directly source green power from renewable energy developers.

Overall, the solar power purchase agreement between Max Healthcare and Sunsure Energy represents a meaningful step toward sustainable healthcare operations. It demonstrates how clean energy adoption can align environmental responsibility with economic efficiency, while contributing to India’s long-term goals of decarbonization and energy transition.

In Short : Stäubli has announced a €10 million investment to scale up its solar connector manufacturing capacity in Bengaluru. The expansion aims to meet rising demand from India’s fast-growing solar sector, strengthen local supply chains, enhance production efficiency, and support the country’s renewable energy ambitions through advanced electrical connectivity solutions.

In Detail : Stäubli’s decision to invest €10 million in expanding solar connector production in Bengaluru reflects growing confidence in India’s renewable energy market. As solar capacity continues to rise rapidly across the country, demand for high-quality electrical components has increased, making localized manufacturing a strategic priority for global technology providers.

Solar connectors play a critical role in photovoltaic systems by ensuring safe, efficient, and reliable electrical connections between modules, inverters, and other system components. High-performance connectors are essential for minimizing power losses, improving system reliability, and enhancing the overall safety of large-scale solar installations.

By scaling up production in Bengaluru, Stäubli aims to strengthen its presence in India’s clean energy ecosystem. The expansion will allow the company to better serve domestic solar developers, engineering firms, and equipment manufacturers while reducing dependence on imports and improving supply chain responsiveness.

The investment also aligns with India’s broader manufacturing and industrial development goals. Local production of advanced solar components supports the “Make in India” initiative, encourages technology transfer, and contributes to building a robust domestic renewable energy supply chain.

From an operational perspective, the expanded facility is expected to adopt modern manufacturing processes, automation, and quality control systems. These enhancements will help improve production efficiency, maintain international quality standards, and ensure consistent performance of solar connectors under diverse operating conditions.

The growing deployment of utility-scale solar parks, rooftop systems, and hybrid renewable projects is creating sustained demand for reliable connectivity solutions. As projects become larger and more complex, the importance of standardized, certified, and durable components becomes even more critical for long-term system performance.

Stäubli’s investment is also likely to generate economic benefits at the local level. The expansion may create new employment opportunities, support skill development, and strengthen Bengaluru’s position as a key hub for renewable energy manufacturing and engineering expertise.

From a strategic standpoint, increasing domestic production capacity allows Stäubli to respond more effectively to India’s evolving regulatory and market requirements. Proximity to customers enables faster customization, improved technical support, and stronger collaboration with project developers and system integrators.

Overall, Stäubli’s €10 million investment in Bengaluru represents more than a manufacturing expansion. It signals long-term commitment to India’s solar industry and highlights the importance of high-quality electrical infrastructure in enabling the country’s transition toward a reliable, scalable, and sustainable renewable energy future.

In Short : Telangana is planning a major transformation of its power sector by targeting a 50% green energy mix and expanding battery storage capacity as electricity demand is projected to exceed 100,000 MW by 2047. The strategy focuses on renewable integration, grid modernization, storage deployment, and sustainable infrastructure to ensure long-term energy security and economic growth.

In Detail : Telangana is preparing for a significant shift in its energy landscape as electricity demand in the state is expected to cross 100,000 MW by 2047. Rapid urbanization, industrial expansion, digital infrastructure growth, and rising living standards are driving a sharp increase in power consumption. To meet this demand sustainably, the state has outlined a long-term strategy centered on renewable energy and energy storage.

A key pillar of Telangana’s plan is achieving a 50% green power mix in its overall electricity portfolio. This involves scaling up solar, wind, and other renewable sources to reduce dependence on fossil fuels and minimize carbon emissions. The transition is aligned with national clean energy goals and reflects Telangana’s ambition to position itself as a leader in sustainable development.

Solar energy is expected to play a dominant role in this transition due to Telangana’s high solar potential and availability of land for large-scale projects. Rooftop solar, utility-scale solar parks, and solar integration in industrial and commercial zones are being promoted to decentralize generation and reduce transmission losses. Wind and hybrid renewable projects are also expected to complement solar generation.

As renewable energy penetration increases, grid stability becomes a critical challenge. Intermittent power generation from solar and wind creates variability that must be managed effectively. To address this, Telangana is planning significant investments in battery energy storage systems to balance supply and demand, ensure reliability, and support round-the-clock power availability.

Battery storage is being positioned as a strategic enabler of the green transition. Large-scale storage systems will allow excess renewable energy generated during peak periods to be stored and dispatched during high-demand or low-generation hours. This not only improves grid resilience but also reduces curtailment of renewable power and enhances overall system efficiency.

Grid modernization is another central component of the state’s energy roadmap. Upgrading transmission infrastructure, deploying smart grid technologies, and integrating digital monitoring systems will enable real-time demand management and efficient power distribution. These measures are essential for accommodating large volumes of distributed renewable energy and storage assets.

The expansion of green power and storage is also expected to have strong economic implications. It will attract private investment, create employment opportunities, and stimulate the growth of clean energy industries within the state. Manufacturing of solar equipment, batteries, and related technologies could emerge as new industrial clusters.

From a policy perspective, Telangana’s strategy requires coordinated planning between government agencies, utilities, regulators, and private developers. Supportive policies, long-term power purchase agreements, financial incentives, and regulatory reforms will be necessary to accelerate renewable deployment and make storage systems commercially viable.

Overall, Telangana’s vision of achieving a 50% green power mix with large-scale battery storage represents a forward-looking approach to energy planning. By proactively addressing future demand growth and sustainability challenges, the state is building a resilient, low-carbon power system that supports economic growth while contributing to national and global climate goals.

In Short : Uttar Pradesh is exploring strategic cooperation with Japan’s Yamanashi Prefecture to advance its green energy ambitions. The partnership focuses on renewable technologies, hydrogen development, energy efficiency, and sustainable infrastructure. This collaboration aims to promote technology transfer, investment, and innovation, supporting Uttar Pradesh’s transition toward a low-carbon economy and long-term energy security.

In Detail : Uttar Pradesh is taking a significant step toward strengthening its clean energy ecosystem by exploring green energy collaboration with Japan’s Yamanashi Prefecture. This initiative reflects the state’s growing focus on international partnerships to accelerate renewable energy deployment and adopt advanced technologies for sustainable development. The engagement highlights Uttar Pradesh’s ambition to position itself as a key player in India’s energy transition.

Japan’s Yamanashi Prefecture is internationally recognized for its leadership in renewable energy research, particularly in hydrogen technologies, solar power, and smart energy systems. By engaging with Yamanashi, Uttar Pradesh aims to benefit from Japan’s technological expertise, innovation models, and policy frameworks that support low-carbon growth and energy efficiency.

A central area of cooperation is expected to be hydrogen energy, which is increasingly viewed as a critical component of future clean energy systems. Yamanashi has been actively developing hydrogen-based infrastructure and mobility solutions, and this experience could help Uttar Pradesh explore hydrogen production, storage, and utilization across industrial, transport, and power sectors.

Solar energy also forms a key pillar of the proposed collaboration. Uttar Pradesh, with its large land availability and high electricity demand, offers strong potential for utility-scale solar projects. Through knowledge exchange with Yamanashi, the state can adopt advanced solar technologies, improve grid integration, and enhance the efficiency of photovoltaic systems.

Energy efficiency and smart grid technologies are additional areas of mutual interest. Japan’s expertise in digital energy management, smart metering, and demand-side optimization can support Uttar Pradesh in modernizing its power infrastructure. These technologies can help reduce transmission losses, improve reliability, and enable better integration of renewable energy sources.

The partnership is also expected to encourage investment and industrial collaboration. Japanese companies may explore opportunities to invest in renewable energy projects, battery manufacturing, green hydrogen facilities, and electric mobility infrastructure in Uttar Pradesh. Such investments can strengthen the state’s clean energy supply chain and generate high-quality employment.

From a policy perspective, the collaboration promotes international knowledge sharing and best practices in energy governance. Exposure to Japan’s regulatory frameworks, financing models, and public-private partnerships can help Uttar Pradesh design more effective policies for renewable energy adoption and sustainable infrastructure development.

The engagement with Yamanashi also aligns with India’s broader national objectives of achieving energy security, reducing carbon emissions, and meeting climate commitments. Sub-national partnerships like this play a crucial role in translating national targets into actionable regional strategies supported by global expertise.

Overall, Uttar Pradesh’s exploration of green energy ties with Japan’s Yamanashi Prefecture represents a forward-looking approach to clean energy development. By combining international technology, investment, and policy learning, the state is strengthening its pathway toward a resilient, low-carbon, and innovation-driven energy future.

In Short : India Power Corporation Limited is set to develop a 70 MW solar power project in Bhutan, strengthening cross-border clean energy cooperation between the two countries. The project supports Bhutan’s renewable energy goals while enhancing regional energy security, promoting sustainable power generation, and reinforcing India’s role in driving South Asia’s green energy transition.

In Detail : India Power Corporation Limited’s plan to develop a 70 MW solar project in Bhutan marks a significant milestone in regional renewable energy collaboration. The project reflects growing efforts by Indian power companies to expand their clean energy portfolios beyond national borders while contributing to sustainable development in neighboring countries. This initiative strengthens energy cooperation between India and Bhutan.

Bhutan has traditionally relied heavily on hydropower for its electricity generation, which has played a central role in its economic and environmental strategy. However, seasonal variations and climate-related uncertainties have highlighted the need to diversify energy sources. The introduction of solar power provides an opportunity to complement hydropower and improve overall energy resilience.

For India Power Corporation Limited, the Bhutan project represents a strategic step in expanding its international renewable energy presence. By investing in overseas solar infrastructure, the company enhances its project portfolio, gains access to new markets, and strengthens its position as a regional clean energy player. Such projects also support long-term business growth aligned with sustainability goals.

The 70 MW solar plant is expected to contribute significantly to Bhutan’s clean energy capacity. Solar generation can help meet rising electricity demand, reduce dependency on single-source generation, and provide greater stability to the national grid. The project also aligns with Bhutan’s broader commitment to maintaining carbon neutrality and promoting environmentally responsible development.

Cross-border renewable energy projects like this play an important role in regional energy integration. By sharing expertise, investment, and technology, countries can collectively strengthen energy security and reduce reliance on fossil fuels. The collaboration between India Power Corporation Limited and Bhutan reflects a shared vision of sustainable growth and low-carbon development.

From a technological perspective, the project is likely to adopt modern photovoltaic systems with high efficiency and advanced monitoring capabilities. These technologies improve generation performance, reduce operational costs, and ensure long-term reliability. The integration of digital tools can further enhance plant performance and grid compatibility.

The solar project is also expected to generate economic benefits for Bhutan, including employment opportunities, local infrastructure development, and skill enhancement in renewable energy operations. Such investments contribute to capacity building and support the growth of a domestic clean energy workforce.

For India, the project reinforces its role as a regional leader in renewable energy deployment. Indian companies developing projects abroad strengthen diplomatic ties, promote sustainable infrastructure, and demonstrate the country’s technical and financial capabilities in the clean energy sector. This supports India’s broader energy diplomacy objectives.

Overall, the development of a 70 MW solar project in Bhutan by India Power Corporation Limited represents more than a single infrastructure investment. It symbolizes deeper regional cooperation, diversification of renewable energy sources, and a shared commitment to building a resilient, low-carbon energy future for South Asia.

In Short : ACME Solar has signed a 25-year power purchase agreement with NHPC for a 250 MW firm and dispatchable renewable energy project. The agreement ensures reliable round-the-clock clean power by combining renewable sources with storage solutions, supporting grid stability, enhancing renewable integration, and advancing India’s transition toward a low-carbon and resilient power system.

In Detail : ACME Solar’s signing of a 25-year power purchase agreement with NHPC for a 250 MW firm and dispatchable renewable energy project represents a significant development in India’s clean energy sector. The long-term nature of the agreement highlights growing confidence in hybrid renewable models that can deliver consistent and reliable power.

Firm and dispatchable renewable energy projects are designed to overcome the intermittency challenges associated with solar and wind generation. By integrating multiple renewable sources along with energy storage systems, FDRE projects ensure continuous power supply that closely matches conventional baseload generation profiles.

The partnership between ACME Solar and NHPC reflects an important shift in India’s renewable energy strategy. Rather than focusing solely on installed capacity, the emphasis is increasingly on reliability, availability, and grid integration. This approach supports the evolving needs of utilities and industrial consumers that require dependable power.

Energy storage plays a critical role in the success of FDRE projects. Battery storage systems or other forms of storage allow excess renewable energy to be stored during periods of high generation and released during peak demand. This improves grid stability and reduces dependence on fossil fuel-based peaking plants.

The 25-year duration of the power purchase agreement provides long-term revenue visibility for ACME Solar, enhancing the financial viability of the project. Such long-term contracts help attract investment, reduce financing costs, and support large-scale deployment of advanced renewable technologies.

For NHPC, the agreement strengthens its clean energy portfolio and aligns with its broader diversification strategy beyond hydropower. By procuring firm renewable power, NHPC can offer more reliable green electricity to its customers while supporting national renewable energy targets.

From a system perspective, FDRE projects contribute to better grid planning and operations. Dispatchable renewable power can support load balancing, reduce transmission congestion, and enhance the integration of variable renewable energy across regional and national grids.

The project also reflects India’s evolving regulatory and market framework for renewable energy. Policy support for hybrid and storage-based projects encourages innovation and accelerates the transition from capacity-driven targets to performance-driven energy solutions.

Overall, ACME Solar’s 250 MW FDRE project under a long-term agreement with NHPC represents a key milestone in India’s clean energy journey. It demonstrates how renewable energy, when combined with storage and smart planning, can deliver reliable, scalable, and sustainable power for the future.

In Short : Designing an effective strategic stockpiling system for critical minerals involves securing reliable supplies, managing geopolitical risks, and ensuring long-term industrial resilience. A well-structured framework balances national security, economic stability, and sustainability by integrating policy coordination, diversified sourcing, transparent governance, and dynamic inventory management to protect against supply disruptions and market volatility.

In Detail : 2025 was the year when the risks of highly concentrated critical minerals supply chains materialised at scale

The IEA has long warned of the potential security risks associated with the high concentration of critical mineral supply chains. In 2025, these risks became a reality, marking a major turning point for global economic security. The rare earths export controls announced by China in October 2025 posed major national and economic security risks across the world, with potentially severe impacts for a range of strategic sectors including energy, automotive, defence, aerospace, AI and semiconductors. Earlier export controls introduced in April had already resulted in some automotive factories around the world being forced to cut utilisation rates or even temporarily shut down.

Beyond rare earths, export controls have also been imposed on a range of strategic minerals including gallium, germanium, graphite and tungsten, which play a crucial role in strategic applications such as semiconductors, batteries, aerospace and defence. The Global Critical Minerals Outlook 2025 highlighted that China is the leading refiner for 19 out of the 20 strategic minerals closely tracked by the IEA, with an average market share of around 70%. Moreover, over half of these minerals are already subject to some form of export controls. These developments underscore that concentration risks in mineral supply chains are no longer a theoretical concern but pose tangible and growing threats to countries’ economic and national security. Moreover, IEA analysis underlines that the market share of the largest suppliers of key critical minerals, particularly for refining, has been increasing in recent years.

Stepping up global action on critical minerals security has never been more urgent. A clear priority is to develop diversified sources of supply for key critical minerals. However, inevitably, it takes time to develop new projects in both mining and refining. Strategic stockpiling of critical minerals can serve as an important protective measure to safeguard countries from supply shocks and disruptions while they develop new, diversified sources of supply. Strategic stockpiles provide a way for countries to strengthen economic and national security, while also helping to deter future export controls and limiting their impact.

Strategic stocks are an insurance policy against short-term disruptions

Strategic stocks – held specifically for emergency purposes with the involvement of the government – have demonstrated effectiveness across various sectors. A notable example is the oil market, where stockpiles have played an important role in mitigating severe economic impacts for decades. After the oil shock of 1973, IEA member governments established a mechanism to build up and pool emergency oil stocks to protect them from being held to ransom via oil supplies in the future. Since then, the IEA has coordinated five collective responses to major oil supply disruptions, helping to limit the economic impacts of shocks caused by natural disasters or geopolitical strife, most recently in 2022 following Russia’s invasion of Ukraine.

Critical mineral markets operate in a very different context from oil markets. The diversity of critical minerals, each with distinct market contexts, means that stockpiling is not a catch-all solution and its suitability can vary by mineral. It is also not a substitute for efforts to develop diversified supply sources that deliver fundamental security benefits. However, stockpiles can still play an important role in providing emergency supply and protecting industries and jobs. Strategic mineral stockpiles also bring several additional benefits. Even when they are not used, they send a signal to markets that sudden supply shocks or export restrictions need not immediately cripple the system. Some IEA Member countries such as Japan, Korea, and the United States hold strategic stockpiles of critical minerals that have protected industries from supply disruptions.

The build-up of critical minerals stockpiles and the need for stock rotation can also support diversification efforts by sourcing materials from projects outside the dominant suppliers, while also enhancing market transparency by providing governments with insights into pricing.

Strategic stockpiles should primarily serve to ensure business continuity and provide a buffer during supply disruptions, rather than to manage price volatility or influence market dynamics. Clear and transparent principles for stockpile releases, focused on addressing acute and short-term supply interruptions, can help prevent market distortion and maintain healthy investment signals that drive market development.

Designing effective stockpiling systems involves addressing a range of strategic questions including material form, governance model, costs, and financing

Amid mounting risks to mineral supply chains, many countries are showing growing interest in establishing stockpiling systems for critical minerals. In doing so, they need to address a range of strategic questions, including the choice of materials to stockpile, governance models, associated costs and financing mechanisms. Critical minerals vary widely in their physical forms, end-use sectors, market sizes, levels of pricing transparency, warehousing needs, and supply chain complexity. Each material therefore needs to be analysed individually, with stockpiling governance models tailored to its specific characteristics.

As part of the Critical Minerals Security Programme, the IEA has examined these issues in detail and developed a comprehensive database and model covering over 30 forms of strategic minerals that are used in the energy sector and have critical applications in AI, advanced technology, aerospace, and defence. This work involved developing an assessment framework to evaluate the supply and strategic risks for each material across multiple dimensions, exploring potential governance models, understanding warehousing requirements posed by the diverse forms that minerals take along their value chains, building cost models to estimate the expenses associated with stockpiling and examining possible financing mechanisms.

The IEA Critical Minerals Stockpiling Assessment Framework evaluates risks and warehousing needs

To determine which materials should be prioritised for stockpiling, the IEA Critical Minerals Stockpiling Assessment Framework was developed to analyse risks and challenges for each material across multiple dimensions: supply risk, the availability of alternative supply routes, strategic importance and the feasibility of stockpiling.

When evaluating supply risks, the level of supply concentration in both mining and refining is a key factor, as relying on few dominant suppliers means that any disruption can immediately flip markets into shortfall. For gallium, graphite, manganese and rare earths, the top refiner, China, accounts for over 90% of global supply. High price volatility further complicates the development of new supply: for example, lithium, vanadium, rare earths and cobalt have exhibited much higher volatility than oil and gas. Many high-risk minerals are already affected by some form of export restrictions, such as rare earths, gallium, and tungsten, straining their supply chain. These restrictions highlight the supply risks but also indicate the procurement challenges of building strategic stocks for these materials.

The availability of alternative supply routes is another important consideration. For some materials, there are limited options for substitute materials, such as chromium for stainless steel, titanium for alloys requiring a high strength-to-weight ratio, and germanium for high-performance fibre optics, heightening the risks from supply disruptions. Additionally, many materials are produced as co- or by-products alongside other minerals, making their supply less responsive to demand or price signals. For example, gallium is mainly recovered as a by-product of zinc and aluminium production, tellurium from copper and lead, and germanium from zinc and coal.

The strategic importance of each material depends on the sectors in which it is used. When materials have applications in strategic sectors such as semiconductors or defence, their security of supply becomes a crucial factor for economic and national security. While strategic importance can be assessed at the global level, each country should also consider domestic vulnerabilities and dependencies to assess potential impacts on its overall security and resilience.

The feasibility of stockpiling varies by material as each mineral takes different forms along its supply chain. The form most suitable for stockpiling is generally the imported form – most exposed to disruption risks – that can be directly used domestically in case of a disruption, without the need for further processing abroad. A broad assessment of the properties of strategic materials that are imported by IEA Member countries highlights a number of warehousing challenges for certain critical minerals such as hygroscopicity (sensitivity to humidity), reactivity, hazardousness and fragility. For example, lithium hydroxide is highly sensitive to humidity and degrades quickly in air, reducing its shelf life to around six months, while lithium carbonate can be stored for much longer. Gallium has a melting point of around 30°C. These warehousing challenges can be overcome, for example through controlling temperature and humidity of warehouses, using advanced packaging to minimise contact with air and moisture, and rotating stocks of materials with short shelf life. However, these additional requirements increase the cost and complexity of stockpiling.

Stockpiling governance models balance roles between government and industry

There is a spectrum of stockpiling governance models, with suitability varying by country and material. Governance models can be grouped into two broad categories based on where the minerals are physically stored: ‘government-held’ or ‘industry-held’, each with two main options. For government-held (centralised) stockpiling models, the government owns and manages the stockpile, either directly or through a public agency acting on its behalf. Industry-held (decentralised) models require companies to store strategic stocks in addition to their existing commercial inventories. For industry-held stockpiles, stocks may be industry-owned, where the government sets a mandate for a volume to be reserved for emergency use, or government-owned, where industry manages the stocks which are owned and purchased by the government. Companies that participate in these models may receive public support. Governments could also consider leveraging the expertise and assets of commodity traders to manage stockpiles more efficiently.

Most existing strategic critical mineral stockpiling systems are government-held and managed through public agencies. Japan’s mineral stockpiles are managed by its public agency; Japan Organization for Metals and Energy Security (JOGMEC), Korea’s stockpiles are handled through the Korea Mine Rehabilitation and Mineral Resources Corporation (KOMIR) and the Public Procurement Service (PPS), and the United States’ National Defence Stockpile is managed by the Defence Logistics Agency (DLA). China also has major stockpiles of critical minerals, but unlike the others, utilises a combination of governance models with material stored and managed by both government and industry.

Operating costs underpin total stockpiling costs, with financing, warehousing, and discounting as the largest components

The costs of stockpiling are comprised of two primary components: the material purchase cost and the operating cost. The material purchase cost is the significantly larger upfront expense; however, this is a capital cost that is converted into an asset (the stockpile), and the capital is recuperated when stocks are released or during stock rotation (when selling the stock back to the market before reaching the end of their shelf life). The net costs of stockpiling are therefore determined by the operating costs. Stockpiling costs are sometimes misconstrued with an overemphasis on the material purchase cost, whereas operating costs form the actual costs borne over time. The operating cost components include financing, warehousing, discount, logistics, material loss and administrative costs. Financing costs refer to the cost of using debt or equity to purchase the material, warehousing refers to the cost of storing the material, and discount costs reflect the loss in market value when selling the stockpiled material to the market after a period of storage.

Our analysis indicates that financing, warehousing, and discount account for the largest share of total stockpiling operating costs, but there are major differences in the share of each component by material. Financing costs are the largest cost component for high-value, lower volume materials such as gallium and germanium, while warehousing costs become more significant for larger volume, lower-value materials such as synthetic graphite and nickel sulphate. Stricter warehousing requirements can triple warehousing costs per tonne compared with standard metals; however, financing costs remain dominant for many materials, even those with the strictest storage requirements such as lithium hydroxide and rare earth permanent magnets. Materials with shorter shelf lives incur more significant discount costs under government-held models due to more frequent stock rotation. Industry-held governance models reduce these discounts as companies use the stocks directly rather than needing to sell them back to the market.

Stockpiling critical minerals entails relatively modest costs compared with the potential economic impacts of supply disruptions

Analysis of stockpiling costs at the aggregate IEA level indicates that the total net cost of stockpiling most critical minerals is relatively modest, particularly for many high-priority strategic materials such as gallium and germanium, which often involve low volumes. According to our analysis, for all IEA countries to stockpile six months of their exposed imports of gallium metal from the top supplier, the total operating costs of stockpiling would be around USD 800 000. By comparison, costs of stockpiling the same months of exposed imports of rare earth permanent magnets would be almost USD 90 million. For material used in much larger volumes such as lithium hydroxide, the costs only grow to just under USD 300 million.

Government-owned governance models have lower financing costs while industry-led models have lower discount costs and greater efficiencies

The appropriate stockpiling governance model varies considerably by material and depending on domestic context and supply chain structures. Government-owned operating models with access to lower interest rates are most cost efficient for high-value materials, such as gallium or germanium. Lower-volume materials with fewer specifications such as upstream concentrates or midstream rare earth oxides may be more suitable for centralised government-led models, if there are domestic facilities able to process them. However, materials with a wide variety of company-specific specifications, such as graphite anode material or rare earth permanent magnets, or with short shelf lives, such as lithium hydroxide, are often better suited to industry-held governance models, where companies can store the specific materials, they need and undergo stock rotation more efficiently. Government-owned, industry-held governance models combine some of the advantages of both models: reduced financing costs, greater logistical efficiencies and reduced discount costs.

Beyond material characteristics and cost considerations, stockpiling can also support the development of diversified projects. Government-led stockpiling operating models are better suited to procuring material from specific strategic projects, providing offtakes that enhance project viability. In industry-led models, it is harder to control where material is purchased from, but the government could still have a role in aggregating demand. Ultimately, the most suitable stockpiling governance model depends strongly on national circumstances. A hybrid solution using a mixture of governance models for different materials may be optimal for many countries.

There are multiple ways to finance strategic stockpiling, which depend on the governance model and domestic circumstances

In the case of direct management of government-held stocks, purchase and operational costs are typically financed directly from the general budget or through a special purpose fund. In case the government chooses to use a public agency to manage the stocks, it can provide loan guarantee for the initial stock purchase and cover the agency’s operational costs. In an industry-held model, most of the costs are borne by companies, but governments could contribute through several instruments, such as direct loans or loan guarantees, public subsidies, tax breaks or direct equity investments. In the government-owned, industry-held hybrid model, the government would typically cover purchasing and financing costs, while operating costs could be shared through an agreement between government and industry.

The IEA Critical Minerals Security Programme is a key platform for international cooperation on critical minerals stockpiling

The urgency of today’s challenges facing critical mineral supply chains calls for strong international collaboration to achieve greater economic and national security, and stockpiling is a key tool that countries are considering implementing or expanding. While the objective of stockpiles is to strengthen security of domestic supply, coordination with international partners can be beneficial to achieve greater security more efficiently and faster. Coordination on the timing for stockpile purchases and principles for releases could help ensure markets are not distorted. When procuring stocks, countries could also agree to support strategic projects that would increase global diversification or consider aggregating demand. When compatible with domestic policies, countries could also consider to co-locate stocks for greater efficiencies, especially for low-volume materials, or reserve production in countries with production infrastructure to be dedicated to emergency use. Close dialogue among partners also helps transferring knowledge on efficient stockpile management.

The IEA Critical Minerals Security Programme is a key international platform helping countries to explore strategic questions around developing domestic stockpiling systems and opportunities to strengthen international coordination. The Programme will continue to support IEA Members in their efforts on reviewing strategic stockpiling as a tool to enhance preparedness to supply shocks.

Seven recommendations for developing domestic strategic stockpiles of critical minerals

When developing or expanding domestic strategic stockpiles of critical minerals, governments should consider:

1. Assessing value chains to identify bottlenecks and determine the material portfolio, prioritising those materials with the highest supply risks for a specific country or region.
2. Stockpiling the form of the material imported to a country or region to enable rapid deployment during disruptions.
3. Preparing for potential future disruptions by considering materials exposed to major risks that are not yet subject to export restrictions.
4. Tailoring the stockpiling governance model to the materials of choice, for an overall stockpiling system that optimises cost and benefits.
5. Setting clear transparent principles for stockpile releases to respond to acute short-term supply disruptions, while maintaining robust investment signals for market development.
6. Closely involving industry across upstream and downstream sectors to design feasible and effective stockpiling systems and ensure their operational viability.
7. When compatible with domestic policies, leveraging international collaboration to optimise multiple domestic systems for greater efficiencies.

In Short : Indian researchers have developed a self-charging solar energy storage device that integrates energy harvesting and storage into one unit. Designed as a photo-supercapacitor, the system captures sunlight and stores power simultaneously, eliminating the need for separate solar panels and batteries. The technology promises efficient, low-cost solutions for portable and off-grid energy needs.

In Detail : An innovative sunlight-powered supercapacitor called photo-capacitor developed by scientists can both capture and store solar energy in a single integrated device.

This could be a remarkable step towards clean and self-sustaining energy storage systems paving the way for efficient, low cost, and eco-friendly power solutions for portable, wearable, and off grid technologies.

Traditionally, solar energy systems rely on two separate units: solar panels for energy capture and batteries or supercapacitors for energy storage. While such hybrid systems are widely implemented from large-scale solar farms to portable electronics, they rely on additional power management electronics to regulate voltage and current mismatches between the energy harvester and the storage unit. This requirement increases system complexity, cost, energy losses, and device footprint, which becomes particularly detrimental for miniaturised and autonomous devices.

This new photo-rechargeable supercapacitor, developed by the Centre for Nano and Soft Matter Sciences (CeNS), Bengaluru, an autonomous institute under the Department of Science and Technology (DST), Government of India. seamlessly combined both processes converting sunlight into electrical energy and storing that energy for later, thus simplifying design and minimising energy loss during conversion and storage.

Under the guidance of Dr. Kavita Pandey, innovated with the help of binder-free use of nickel-cobalt oxide (NiCo2O4) nanowires, which have been uniformly grown on nickel foam using a simple in situ hydrothermal process.

These nanowires, only a few nanometres in diameter and several micrometres long, form a highly porous and conductive 3D network that efficiently absorbs sunlight and stores electrical charge. This unique architecture allowed the material to act simultaneously as a solar energy harvester and a supercapacitor electrode.

When tested, the NiCo2O4 electrode exhibited a remarkable 54% increase in capacitance under illumination, rising from 570 to 880 mF cm-2 at a current density of 15 mA cm-2. This exceptional performance stems from the efficient generation and transfer of light-induced charge carriers within the nanowire network. Even after 10,000 charge-discharge cycles, the electrode retained 85% of its original capacity, demonstrating its long-term stability, an essential feature for practical applications.

To evaluate its real-world applicability, the researchers prepared an asymmetric photo-supercapacitor using activated carbon as the negative electrode and NiCo2O4 nanowires as the positive electrode. The device delivered a stable output voltage of 1.2 volts, maintained 88% of its capacitance retention even after 1,000 photo-charging cycles, and operated efficiently under varying sunlight conditions-from low indoor illumination to intense 2 sun intensity. This stability indicates that the nanowire structure can endure both mechanical and electrochemical stress over extended periods of use.

By integrating sunlight harvesting and energy storage in a single device, the team developed self-charging power systems that can function anywhere even in remote regions without access to an electrical grid.

Such technology can substantially reduce dependence on fossil fuels and conventional batteries, paving the way for a sustainable and green energy future. In addition to the experimental, theoretical study was carried out to understand why the NiCo2O4 nanowire system performs so efficiently.

This study revealed that nickel substitution in the cobalt oxide framework narrows the band gap to approximately 1.67 eV and induces half metallic behavior. This means the material behaves as a semiconductor for one type of electron spin while remaining metallic for the other: a rare dual property that enables faster charge transport and higher electrical conductivity. Such spin dependent conductivity is particularly valuable for photo-assisted charge storage applications.

Integrating sunlight capture and charge storage in a single architecture has been a long-standing goal in sustainable energy research.

This study also demonstrates the synergy between experimental and theoretical insights in materials research. While experiments confirmed enhanced capacitance and durability, theoretical simulations revealed the atomic-level mechanisms driving these improvements. Together, they provide a comprehensive understanding of how nanostructured materials can be optimized for light-responsive energy storage.

This work, published in Sustainable Energy & Fuels (Royal Society of Chemistry Journal), introduces a new class of smart, photo-rechargeable energy storage devices. Overall, this research represents a paradigm shift in renewable energy storage. With further development, such systems could play a pivotal role in achieving India’s clean energy ambitions and inspiring similar innovations worldwide.

Tender for Balance of System for 700 MW (AC) Solar PV Power Plant at Radha Nesda, Banaskantha, Gujarat, India.

Tender No: SECI/C&P/OP/11/023/2025-26

ETS ID: SECI-2026-TN000001

CPPP ID: 2026_SECI_825234_1

Revised Bid Submission Deadline: 19.02.2026 (Thursday, 1400 Hrs.)

Revised Bid Opening Timeline: 19.02.2026 (Thursday, 1600 Hrs.)

Summary:

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### **1. Overview and Context:**
– **Date of Hearing:** 13th January 2026.
– **Common Petitioner:** Power Grid Corporation of India Limited (PGCIL).
– **Subject:** Multiple petitions (listed below) for **truing up of tariffs for the 2019-24 period** and **determination of tariffs for the 2024-29 period** for various transmission assets across India.
– **Regulatory Framework:** Petitions filed under the relevant tariff regulations (e.g., CERC Tariff Regulations, 2019).

### **2. List of Petitions & Key Respondents:**
The petitions involve transmission schemes across different regions. Key respondents are primarily the state power distribution companies (DISCOMs) of the respective beneficiary states.

| Petition No. | Scheme/Project Name | Region | Key Respondent(s) |
| :— | :— | :— | :— |
| **924/TT/2025** | Integration of Pooling Stations in Chhattisgarh… | Western | MPPMCL & 5 Others |
| **926/TT/2025** | System Strengthening XXVI | Southern | TANGEDCO/TNPDCL & 13 Others |
| **921/TT/2025** | System Strengthening Scheme-XIII | Southern | TANGEDCO/TNPDCL & 13 Others |
| **920/TT/2025** | Transmission System for Pavagada Solar Park Phase-I | Southern | TANGEDCO/TNPDCL & 13 Others |
| **962/TT/2025** | Substation works beyond Vemagiri | Southern | TANGEDCO/TNPDCL & 14 Others |
| **964/TT/2025** | WR-NR Corridor for Chhattisgarh IPPs | Northern | UPPCL & 21 Others |
| **413/TT/2025** | North Eastern Region Strengthening Scheme-IV | North Eastern | APDCL & 6 Others |
| **435/TT/2025** | Inter-Regional Strengthening (WR & NR Part-A) | Inter-Regional | MPPMCL & 5 Others |
| **411/TT/2025** | Raipur-Rajnandgaon TL for Chhattisgarh IPPs | Western | MPPMCL & 8 Others |
| **518/TT/2025** | Transmission for Phase-I Gen Projects in Odisha | Western | MPPMCL & 5 Others |
| **420/TT/2025** | Western Region System Strengthening Scheme-V | Western | MPPMCL & 5 Others |
| **731/TT/2025** | *(Details not fully specified in snippet)* | *Not Specified* | *Not Specified* |

### **3. Proceedings and Core Issue:**
– PGCIL, as the Central Transmission Utility (CTU), is seeking **regulatory approval for the final tariffs** for its transmission assets.
– The process involves two key steps for each asset:
1. **Truing Up (2019-24):** Final reconciliation of actual capital expenditure (CAPEX) and operational costs against earlier estimates to determine the final payable tariff for the past period.
2. **Tariff Determination (2024-29):** Setting the approved tariff for the next regulatory period based on the trued-up capital cost and normative operational parameters.

### **4. Business & Regulatory Implications:**

– **For PGCIL:** This is a critical, routine regulatory process to **secure revenue recovery** for its vast transmission investments. Timely and accurate submission of the voluminous data is essential to avoid delays in tariff approval and cash flow.
– **For Respondent DISCOMs:** They have the opportunity to **review and challenge** PGCIL’s cost claims. Their scrutiny is vital to ensure that only prudent and efficient costs are passed through to the end consumers via tariffs.
– **For End Consumers:** The outcome of these petitions will ultimately influence the **transmission component of electricity bills** for consumers in the beneficiary states.
– **For the Power Sector:** The process underscores the **regulated, cost-plus nature of transmission tariffs** in India. It ensures transparency and allows recovery of investments for critical national grid infrastructure.

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For more information please see below link:

Summary:

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**1. Official Details of the Amendment:**
– **Regulation Name:** Telangana Electricity Regulatory Commission (Licensee’s Duty for Supply of Electricity on Request) Second Amendment Regulation, 2026.
– **Regulation No.:** 01 of 2026.
– **Date of Notification:** 17th January 2026.
– **Effective From:** The date of its publication in the Telangana Gazette.
– **Amends:** The Principal Regulation (No. 4 of 2013) and its First Amendment (No. 1 of 2015).

**2. Primary Objective:**
– To **simplify and expedite** the process for releasing **new LT connections** and **additional loads** in electrified areas.
– To introduce **uniform, objective, and load-based Service Line Charges**, eliminating the need for individual site inspections and case-by-case estimations.

**3. Key Amendments Introduced:**

**A. New Service Line Charges (SLC) for Overhead Line Connections (Clause 7.1):**
– Applies to new/additional **LT connections** (excluding LT-VIII: Temporary supply & Electrification of Layouts) within **1 km of an electrified network**.
– Charges are **per kW of contracted load** and vary by consumer category.
– **Excludes** cost of terminal and metering arrangements (borne by licensee).
– **Distribution Licensee must supply and erect the Distribution Transformer at its own cost and maintain it.**

**B. Category-wise Service Line Charges (Rs./kW):**

| Category | Load Bracket | Service Line Charges |
| :— | :— | :— |
| **LT-I: Domestic** | Up to 1 kW | ₹500 |
| | Above 1–5 kW | ₹500 + ₹600/kW |
| | Above 5–20 kW | ₹2,900 + ₹1,500/kW |
| | Above 20 kW | ₹10,000/kW |
| **LT-II: Non-Domestic/Commercial, LT-VI (Street Lights), LT-VII (General)** | Up to 1 kW | ₹1,000 |
| | Above 1–5 kW | ₹1,000 + ₹1,200/kW |
| | Above 5–20 kW | ₹5,800 + ₹2,000/kW |
| | Above 20 kW | ₹10,000/kW |
| **LT-III: Industries** | Up to 20 kW | ₹4,000/kW |
| | Above 20 kW | ₹10,000/kW |
| **LT-IV: Cottage Industries** | All loads | ₹1,000/kW |
| **LT-V: Agriculture** | All loads | ₹1,000/kW (No ORC from farmers) |
| **LT-IX: EV Charging Stations** | Up to 1 kW | ₹1,000 |
| | Above 1–20 kW | ₹1,000 + ₹1,200/kW |
| | Above 20 kW | ₹8,000/kW |

**Important Note for Apartments/Complexes:** Combined contracted load of the building is considered for levying SLC.

**C. Revised Rules for Development Charges & Transformers (Clause 8.3):**
– **For dedicated transformers** in commercial complexes/apartments **NOT covered under the new SLC system**, the licensee recovers the **full transformer cost**, owns and maintains it, and cannot supply other consumers from it. **No Development Charges** are levied.
– **For connections COVERED under the new SLC system (Clause 7.1):**
– **Load ≤ 20 kW** (individual or combined for buildings): Pay **Development Charges** (as per Schedule) **plus SLC**.
– **Load > 20 kW** (individual or combined for buildings): Pay **SLC only**. **No Development Charges**.

**D. New Clauses Added:**
– **Clause 13:** Empowers the Commission to issue **orders and practice directions** for implementing this regulation.
– **Clause 14:** Grants the Commission the power to **amend, suspend, or repeal** any provision of this regulation in the future.

**4. Business Implications:**
– **For Consumers (Applicants):**
– **Predictable Costs:** Transparent, upfront Service Line Charges based on load and category.
– **Faster Processing:** Simplified process eliminates individual estimations and inspections for standard cases.
– **Lower Cost for Agriculture & Cottage Industries:** Fixed low rate of ₹1,000/kW.
– **EV Charging Support:** Separate, slightly lower tariff slab to promote EV infrastructure.
– **No Transformer Cost:** Licensee bears the cost and maintenance of the distribution transformer for connections under the new SLC system.

– **For Distribution Licensees (DISCOMs):**
– **Streamlined Operations:** Uniform charges reduce administrative burden.
– **Revenue Clarity:** Clear framework for recovering connection costs.
– **Asset Ownership & Maintenance:** Responsible for transformers under the new SLC system.
– **Proposal Right:** Can file for revision of Service Line Charges periodically.

– **For the Regulatory Framework:**
– **Standardization:** Moves away from discretionary site-specific estimates.
– **Promotes Electrification:** Simplified and subsidized rates for key sectors (Agriculture, Cottage Industries, EV).
– **Future Flexibility:** Commission retains power to issue directives and amend rules as needed.

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