7 Renewable Energy Startups Leading the Way (Real Projects, Real Impact)

The race to decarbonize power, heat, and industry is no longer theoretical—it’s a practical engineering sprint. Across solar, geothermal, long-duration storage, green hydrogen, wave energy, rural electrification, and industrial heat, a new generation of startups is turning bold ideas into bankable projects. This article spotlights seven such companies and, for each, gives you a pragmatic, step-by-step playbook to evaluate, pilot, and scale their technologies. It’s written for energy leaders at utilities and IPPs, corporate sustainability and procurement teams, industrial operators, city planners, and investors who want actionable detail—not just headlines.

Quick note: This article is for general information only and isn’t investment, legal, or engineering advice. For any capital decisions, consult qualified professionals.

What you’ll learn:
How each startup’s technology works, the business case it unlocks, what you’ll need to get started, practical implementation steps, how to measure progress, and pitfalls to avoid.

Who this is for:
Organizations seeking near-term decarbonization at meaningful scale: grid operators planning for 24/7 clean power, manufacturers targeting zero-carbon heat, municipalities deploying resilient microgrids, and investors looking for differentiated clean-tech opportunities.

Key takeaways

• The frontier is already commercial. These seven companies have crossed key milestones—from first-of-a-kind plants to utility contracts—so you can build real projects, not just pilots.
• Integration is the value unlock. The winners pair technology with bankability: offtakes, tariffs, and partnerships that de-risk uptake and simplify procurement.
• Think portfolio, not silver bullet. Combine high-capacity-factor geothermal with perovskite solar, long-duration storage, and flexible loads for true 24/7 clean operations.
• Industrial decarbonization is here. Thermal batteries and green hydrogen shift gigawatt-hours into high-temperature heat and e-fuels—where emissions are toughest.
• Access matters. Mesh-grid innovation reduces capex and accelerates last-mile electrification, expanding markets while improving social outcomes.

1) Fervo Energy — Next-Generation Geothermal for 24/7 Clean Power

What it is & core benefits
Fervo Energy uses horizontal drilling, fiber-optic sensing, and stimulation techniques to create engineered geothermal systems (EGS) that unlock heat from hard rock. Unlike variable wind or solar, EGS can deliver around-the-clock carbon-free power and ancillary grid services. Recent projects demonstrate grid contribution and utility-scale offtakes, making geothermal a practical pillar for 24/7 clean energy strategies.

Requirements & prerequisites (with lower-cost alternatives)

• Site: High-temperature resources at depth; favorable geology; access for drilling.
• Grid & offtake: A buyer prepared for 24/7 carbon-free procurement or a utility tariff structure designed for firm clean power.
• Capital & skills: Upfront drilling capex, subsurface expertise, and permitting for wells and surface plant.
• Lower-cost alternative: If you lack suitable geology or drilling appetite, consider long-duration storage paired with wind/solar to mimic firmness, or contracted geothermal via a utility program.

Step-by-step for first deployment

1. Screen locations using heat flow maps, existing wells, and proximity to interconnection.
2. Engage early with the utility to align on tariff design or 24/7 carbon-free procurement.
3. Commission a pre-FEED: resource modeling, well design, water balance, microseismic risk analysis.
4. Secure offtake (PPA or clean-power tariff) to underwrite financing.
5. Drill and test pilot wells, verify flow rates and temperatures, then finalize plant design.
6. Phase build-out from pilot to multi-well commercial pads; embed fiber-optic monitoring to optimize output.
7. Stack services (capacity, regulation, black-start) where market rules allow.

Beginner modifications & progressions

• Beginner: Start with a small pad and single power block to validate resource characteristics.
• Scale up: Add additional producers/injectors, increase well spacing, and integrate demand-response for load shaping.

Recommended frequency/duration/metrics

• KPIs: Sustained flow rate (kg/s), wellhead temperature (°C), net capacity (MW), capacity factor (%), unplanned outage hours, $/MWh LCOE, induced seismicity thresholds.
• Cadence: Daily thermal/flow trending; monthly reservoir model updates; annual third-party performance audit.

Safety, caveats & common mistakes

• Induced seismicity: Monitor microseismic events and adhere to traffic-light protocols.
• Water management: Close the loop; track losses and chemistry to avoid scaling.
• Permitting timelines: Start early; community engagement reduces risk.
• Mistake to avoid: Over-projecting capacity before long-duration well tests confirm stable flow.

Mini-plan (example)

• Month 1: Site screening + utility pre-read on tariff/offtake.
• Months 2–3: Pre-FEED and environmental scoping to reach a go/no-go on a pilot pad.

2) Oxford PV — Perovskite-on-Silicon Tandem Solar for Higher Output

What it is & core benefits
Oxford PV manufactures perovskite-on-silicon tandem solar cells and modules that push module efficiency beyond traditional silicon. Higher conversion means more watts per square meter and potentially lower BOS (balance-of-system) cost per watt at constrained sites (rooftops, carports, urban estates).

Requirements & prerequisites (with lower-cost alternatives)

• Use case: Space-limited rooftops, high-value estates, or premium modules where additional energy yield pays for itself.
• Procurement: Access to certified tandem modules and compatible inverters.
• Lower-cost alternative: If premium modules aren’t available, bifacial n-type silicon plus tracking can close part of the yield gap at lower cost.

Step-by-step for first deployment

1. Select a constrained site (e.g., HQ roof) where extra efficiency yields measurable value.
2. Model energy yield versus best-in-class n-type silicon; include thermal derate and soiling.
3. Confirm certifications, warranties, and degradation assumptions with the supplier.
4. Pilot a subsection (one roof zone or carport) with robust data logging.
5. Benchmark performance over several months; validate predicted kWh/kWp uplift.
6. Scale procurement into new roofs or PPA portfolios as supply ramps.

Beginner modifications & progressions

• Beginner: Retrofit a small carport with tandems and smart inverters for granular monitoring.
• Scale up: Deploy across portfolio roofs and pair with battery or EV fleet charging to capture on-site consumption value.

Recommended frequency/duration/metrics

• KPIs: kWh/kWp yield, performance ratio (PR), temperature coefficient impacts, BOS $/W, degradation rate (%/year), inverter clipping losses.
• Cadence: Daily SCADA check; monthly performance audits; annual warranty review.

Safety, caveats & common mistakes

• Bankability: Ensure product certifications and robust warranties during early scaling.
• Thermal management: Tandems can run warm; check mounting and airflow.
• Mistake to avoid: Assuming lab-grade efficiencies translate 1:1 to field PR—validate with a monitored pilot.

Mini-plan (example)

• Weeks 1–2: Feasibility + product qualification.
• Weeks 3–4: Install 100–200 kWp pilot; start a 6-month monitored trial.

3) Electric Hydrogen — Gigawatt-Scale Electrolyzers for Green Hydrogen

What it is & core benefits
Electric Hydrogen builds 100-MW class PEM electrolyzer plants designed to produce low-cost hydrogen at industrial scale. For refineries, chemicals, steel, e-fuels, and heavy transport hubs, that means substituting fossil-based H₂ with renewable hydrogen while leveraging maturing supply chains and standardized plant designs.

Requirements & prerequisites (with lower-cost alternatives)

• Power: Dedicated renewable PPAs or behind-the-meter wind/solar with grid backup.
• Water & balance of plant: Deionized water treatment, compression/storage, safety systems, and export connection to the end use.
• Permitting & offtake: Hazardous area classification, local codes, and binding offtake (e-fuels, hydrotreating, ammonia, etc.).
• Lower-cost alternative: If scale is premature, smaller PEM units or blue-H₂ contracts as interim steps—while planning for a 100-MW block at a mature site.

Step-by-step for first deployment

1. Define the end use (e.g., 30 t/day for e-methanol) and back-cast required electrical load.
2. Secure power supply (24/7 blend or matched renewables plus storage) to stabilize load factor.
3. Water & compression design: Size treatment, drying, and storage to the daily use profile.
4. Hazard studies: Conduct HAZID/HAZOP; align with local fire authority and insurance early.
5. Contracting: Standardized plant modules with EPC integration and commissioning plan.
6. Ramp production in phases (e.g., 50-MW increments) to derisk.
7. Digitize operations with continuous efficiency monitoring and demand-response participation where markets allow.

Beginner modifications & progressions

• Beginner: Co-locate a smaller electrolyzer at an existing industrial facility with an immediate H₂ sink.
• Scale up: Expand to 100-MW blocks, add waste-heat recovery, and integrate thermal storage or e-fuel synthesis.

Recommended frequency/duration/metrics

• KPIs: kWh/kg H₂ (system), stack utilization (%), uptime, $/kg LCOH, water consumption (L/kg), capacity factor, safety incidents.
• Cadence: Continuous SCADA; monthly energy and O&M reconciliation; annual stack health audit.

Safety, caveats & common mistakes

• Hydrogen safety: Ventilation, leak detection, zoning, and emergency response plans are non-negotiable.
• Power quality: Voltage dips and harmonics can damage stacks—specify grid code compliance and ride-through.
• Mistake to avoid: Underestimating water purity management and downstream compression costs.

Mini-plan (example)

• Quarter 1: Confirm offtake + power.
• Quarter 2: FEED and permitting.
• Quarter 3: Order long-lead equipment; finalize EPC.

4) Energy Dome — Long-Duration “CO₂ Battery” for Firm, Multi-Hour Storage

What it is & core benefits
Energy Dome’s CO₂-based thermodynamic cycle stores electricity by compressing carbon dioxide into a liquid at ambient temperature and later expands it to generate power. The system targets 10-hour class storage with common materials and no reliance on scarce lithium—an appealing option for utilities seeking cost-effective long-duration storage (LDES).

Requirements & prerequisites (with lower-cost alternatives)

• Site: Space for storage vessels, compressors/turbines, and standard grid interconnection.
• Use case: Capacity shifting, evening peaks, renewables firming, and reliability services.
• Lower-cost alternative: For shorter durations, 4-hour lithium-ion may still be optimal. For ultra-long durations, consider power-to-gas or flow batteries.

Step-by-step for first deployment

1. Identify a load pocket with frequent multi-hour ramps or curtailed renewables.
2. Model the storage portfolio (4-hour vs. 8–10-hour vs. seasonal) to find least-cost mix.
3. Develop an offtake (resource adequacy, capacity contracts, or utility tariff) and site land.
4. Conduct grid studies for interconnection and ancillary services eligibility.
5. Contract a standard module (e.g., tens of MW, hundreds of MWh) with phased commissioning.
6. Integrate dispatch optimization with day-ahead and real-time markets.
7. Measure service revenues (capacity, arbitrage, grid support) against model.

Beginner modifications & progressions

• Beginner: Pilot a single standard module in a high-curtailment region.
• Scale up: Build a multi-module storage park with co-located solar or wind.

Recommended frequency/duration/metrics

• KPIs: Round-trip efficiency (%), equivalent full-cycle count, availability, $/kW-month capacity revenue, $/MWh arbitrage margin, degradation trend.
• Cadence: Daily dispatch review; monthly model-vs-actual true-ups; annual asset health inspection.

Safety, caveats & common mistakes

• Pressure systems: Strict adherence to pressure vessel codes and operator training.
• Market design: Ensure that capacity accreditation and duration rules recognize the full value of 8–10-hour storage.
• Mistake to avoid: Sizing only for arbitrage—capacity and reliability value often drive the business case.

Mini-plan (example)

• Weeks 1–3: Site + interconnection screening.
• Weeks 4–8: Capacity contract discussions; proceed to procurement of a standard module.

5) Eco Wave Power — Onshore Wave Energy for Ports & Breakwaters

What it is & core benefits
Eco Wave Power mounts wave energy converters on existing marine structures (breakwaters, jetties, piers). By avoiding offshore moorings and subsea cabling, it cuts installation complexity and maintenance cost. It’s an attractive fit for ports seeking visible clean power and coastal municipalities pursuing diversified, resilient generation.

Requirements & prerequisites (with lower-cost alternatives)

• Site: Port or breakwater with suitable wave climate; access for installation and O&M; grid interconnection onshore.
• Permitting: Maritime authorities, local municipalities, and environmental impact coordination.
• Lower-cost alternative: If local wave climate is weak, harbor solar canopies plus storage may be more cost-effective.

Step-by-step for first deployment

1. Wave resource assessment using local buoy data and hindcasts; define capacity factor expectations.
2. Port partner alignment on siting, safety zones, and aesthetic considerations.
3. Grid and interconnection plan onshore, with clear metering and SCADA.
4. Pilot array (e.g., a small set of modules) for technology familiarization.
5. Operational trial across seasons to validate survivability and maintenance cadence.
6. Scale along the breakwater in stages, co-optimizing with port operations.

Beginner modifications & progressions

• Beginner: Demonstration at a protected breakwater segment with easy access.
• Scale up: Extend along the structure and pair with harbor microgrids for resilience.

Recommended frequency/duration/metrics

• KPIs: Capacity factor, module availability, maintenance hours per MWh, OPEX $/MWh, weather downtime days, public-safety incidents.
• Cadence: Weekly mechanical checks; seasonal storm readiness drills; annual overhaul.

Safety, caveats & common mistakes

• Safety around the waterline: Lock-out/tag-out and port traffic coordination are paramount.
• Storm survivability: Engineer for extreme seas; ensure rapid module retraction procedures where applicable.
• Mistake to avoid: Overestimating wave resource at sheltered sites—validate with actual data.

Mini-plan (example)

• Quarter 1: Port MoU + resource study.
• Quarter 2: Install a small module set; operate through a high-wave season.

6) Okra Solar — Mesh-Grids for Last-Mile, Productive Power Access

What it is & core benefits
Okra Solar enables modular “mesh-grids” that interconnect rooftop solar-battery kits across neighboring homes. Power travels over safe, low-voltage DC cabling between roofs, so communities can start small and upgrade capacity as incomes and loads grow. The approach can achieve Tier 4 energy access levels suitable for appliances and productive use, while reducing distribution capex versus traditional poles-and-wires.

Requirements & prerequisites (with lower-cost alternatives)

• Community selection: Dense village layouts, roofs suitable for panels, and local demand for productive loads (cold chain, irrigation, mills).
• Local partners: Developers or co-ops capable of installation, fee collection, and maintenance.
• Regulatory: Mini-grid rules and smart-metering approval.
• Lower-cost alternative: Where density is very low, standalone solar kits may be a pragmatic first step.

Step-by-step for first deployment

1. Load survey & willingness-to-pay: Map households, appliances, and anchor loads (shops, clinics).
2. Design the mesh: Start with a cluster, size PV and batteries per household, and plan trunk connections.
3. Install smart nodes & billing: Prepay or pay-as-you-go models reduce default risk.
4. Commission & train local operators; instrument the system for per-household data.
5. Scale cluster-by-cluster as demand grows; upgrade breakers and cabling as needed.

Beginner modifications & progressions

• Beginner: Single-cluster pilot (a few dozen homes) with one anchor load like a cold room.
• Scale up: Add income-generating appliances, expand to schools and clinics, and integrate productive financing (e.g., loans for freezers or pumps).

Recommended frequency/duration/metrics

• KPIs: Connections, uptime (%), average daily kWh/household, non-technical losses (%), revenue collection rate, service response time, productive-use adoption.
• Cadence: Daily remote monitoring; monthly tariff review; quarterly hardware audits.

Safety, caveats & common mistakes

• Electrical safety: Standardize on robust DC connectors and fusing; enforce safe wiring practices.
• Tariff design: Set tariffs that recover OPEX and debt while protecting low-income users.
• Mistake to avoid: Over-sizing storage before demand materializes—grow in increments.

Mini-plan (example)

• Month 1: Community engagement + load survey.
• Month 2: Install 25–50 home cluster; add a shared productive appliance.

7) Rondo Energy — Thermal Batteries for Zero-Carbon Industrial Heat

What it is & core benefits
Rondo Energy deploys brick-based thermal batteries that convert cheap renewable electricity into high-temperature heat and steam on a 24/7 basis. For chemicals, food, paper, and materials plants, this can electrify process heat and cut fuel emissions without overhauling core equipment, since the output is familiar steam or hot air.

Requirements & prerequisites (with lower-cost alternatives)

• Site: Space near boilers/steam headers; electrical capacity for charging; interlocks with existing process control.
• Load profile: Steady steam or thermal demand; willingness to shift charging to low-cost periods.
• Lower-cost alternative: Where temperatures are modest, industrial heat pumps may be more efficient.

Step-by-step for first deployment

1. Thermal audit: Map temperature levels, pressure, and 24-hour demand curves.
2. Sizing study: Determine battery capacity to ride through peak hours and maintain continuous steam.
3. Interconnection & controls: Integrate with steam headers and plant DCS; define charge/discharge logic tied to renewable or time-of-use signals.
4. Safety case: Validate materials, enclosures, and emergency venting.
5. Pilot line: Start with a single production line or utility header before site-wide rollout.
6. Procurement: Lock in renewable PPAs or behind-the-meter solar to feed the battery.

Beginner modifications & progressions

• Beginner: Partial-load retrofit to one boiler at a time to prove steam quality and reliability.
• Scale up: Add modules to serve multiple headers, integrate with electrolyzers or e-boilers for hybrid flexibility.

Recommended frequency/duration/metrics

• KPIs: Steam quality and pressure stability, round-trip efficiency, charge window utilization, OPEX savings vs. gas, avoided CO₂ (t/year), payback.
• Cadence: Weekly performance reports; quarterly energy market true-ups; annual refractory inspection.

Safety, caveats & common mistakes

• High-temperature handling: Ensure proper enclosures, interlocks, and maintenance procedures.
• Grid impacts: Charging can be power-intensive—coordinate with utility to avoid demand charges.
• Mistake to avoid: Under-sizing storage relative to peak thermal demand, which can force backup fuel use.

Mini-plan (example)

• Weeks 1–4: Thermal audit + pre-FEED.
• Weeks 5–12: Pilot install on one header; monitor for 8–12 weeks before fleet rollout.

Quick-Start Checklist

• Define your objective clearly: 24/7 clean electricity? Industrial heat? Rural access? Port decarbonization?
• Match tech to need:
  • Firm baseload → Geothermal or LDES.
  • Space-limited solar → Tandem perovskite-silicon.
  • Industrial H₂ → 100-MW PEM electrolyzer plant.
  • Coastal power + visibility → Onshore wave.
  • Last-mile access → Mesh-grid.
  • High-temp process heat → Thermal batteries.
• Secure the offtake & tariff: Align early with utilities, regulators, or customers who will pay for the attributes (firmness, duration, heat).
• Run a targeted pilot: Instrument everything; compare model vs. actual monthly.
• Plan staged scaling: Build in increments; enforce QA/QC and independent M&V.

Troubleshooting & Common Pitfalls

• The model looked great—performance lags.
  Fix: Recalibrate with real-world losses: temperature coefficients (solar), parasitics (storage), and downtime (marine or drilling). Update dispatch logic and O&M routines.
• Permits are taking forever.
  Fix: Start environmental and community engagement on day one. Provide visualizations and traffic/noise plans. Tie benefits to local jobs and resilience.
• Tariff misalignment kills the business case.
  Fix: Co-design a clean power tariff or capacity contract with the utility. For industrial heat, anchor the economics with time-of-use arbitrage and fuel savings.
• Supply chain delays on critical components.
  Fix: Standardize modules; pre-qualify secondary suppliers; place long-lead orders early and stage delivery with construction milestones.
• Community skepticism.
  Fix: Offer site tours, third-party monitoring dashboards, and transparent benefit-sharing (e.g., local hiring, health clinics for mesh-grid rollouts).

How to Measure Progress (Team-Level Scorecard)

Track these quarterly:

• Carbon-free hours (%): Share of operating hours supplied by verified carbon-free sources.
• Firm clean capacity (MW): Geothermal + LDES accredited capacity.
• Energy yield (kWh/kWp): For premium modules vs. baseline PV.
• Storage value stack ($/kW-month + $/MWh): Capacity + arbitrage + ancillary.
• Industrial heat decarbonized (%): Share of steam/heat from thermal batteries or electrified systems.
• Access outcomes: Connections energized, uptime, productive-use adoption (mesh-grid).
• Unit costs: LCOE/LCOH, OPEX/MWh, payback (years).
• Safety: TRIR, near misses, and compliance audits passed.

A Simple 4-Week Starter Plan (Portfolio Evaluation)

Week 1 — Framing & shortlisting

• Clarify your decarbonization objective (24/7 power, heat, access).
• Shortlist 2–3 technologies that map directly to that need.
• Identify 1–2 candidate sites per tech; gather load and resource data.

Week 2 — Feasibility sprints

• Run back-of-the-envelope techno-economics per site (CAPEX, OPEX, $/MWh or $/kg H₂, payback).
• Pre-consult with permitting and grid teams; begin offtake conversations.

Week 3 — Pilot definition

• Select one pilot per tech with clear success criteria, metering plan, and owner.
• Draft risk register (supply, permit, community, interconnection) and mitigation.

Week 4 — Governance & go-no go

• Present pilots to executive steering group with budget ranges and milestones.
• Green-light engineering studies; prepare long-lead procurement strategy.

FAQs

1. Which of these technologies delivers the biggest immediate carbon impact for a large data center?
   If you need 24/7 carbon-free power, pair enhanced geothermal (for firm baseload) with long-duration storage and existing wind/solar. Layer in a clean tariff or PPA that recognizes firmness.
2. Are perovskite-silicon tandem modules bankable yet?
   They’re moving from record-setting to early commercial products. For now, pilot on space-constrained roofs with strong warranties and measured PR. Use data from your pilot to inform broader procurement.
3. Is long-duration storage worth it if I already have lithium batteries?
   Yes—if your grid or site experiences multi-hour ramps or you value capacity accreditation. LDES complements 4-hour lithium by covering longer peaks and improving renewable utilization.
4. What hydrogen purity do industrial users typically require?
   Most refining/chemical processes require high-purity hydrogen; PEM systems are well-suited. Confirm specs (pressure, dryness, purity) with your offtaker and design compression/treatment accordingly.
5. How risky is EGS drilling for induced seismicity?
   Risk is manageable with traffic-light systems, microseismic monitoring, and conservative stimulation designs. Select sites away from sensitive faults and communicate transparently with communities.
6. Do wave energy systems survive storms?
   Modern onshore systems are designed for harsh seas and can be retracted or safeguarded during extremes. Still, site selection and engineering for worst-case wave loads are critical.
7. What’s the fastest route to impact for rural electrification?
   Start with one mesh-grid cluster anchored by a productive load (e.g., cold storage). Instrument everything, then replicate cluster-by-cluster using standardized kits and local technicians.
8. Can thermal batteries fully replace gas boilers?
   For many processes, yes—especially where steam or hot air is the main need and you can charge when power is cheapest. Validate temperature/pressure requirements and interlock with existing controls.
9. How do I evaluate 24/7 clean power claims?
   Demand hourly matching proof, solid M&V, and transparent dispatch data. Look for utility tariffs or PPAs structured to deliver round-the-clock carbon-free supply, not annual averages.
10. What are the first three hires for an industrial decarbonization program?
    A systems engineer (integration), a project finance lead (tariffs, PPAs, incentives), and a community & permitting lead (stakeholder engagement and approvals).
11. How do I keep pilots from stalling?
    Set time-boxed milestones, predefine go/no-go criteria, and secure executive sponsorship. Build standard modules you can replicate quickly.
12. What incentives matter most?
    It depends on jurisdiction. Generally, look for investment tax credits, manufacturing credits, clean hydrogen production incentives, capacity payments, and grant programs tied to domestic manufacturing or regional development.

Conclusion

The clean-energy transition is no longer about waiting for breakthroughs—it’s about deploying what’s working now and wiring it together intelligently. The seven startups profiled here are moving the needle where it counts: firming the grid, decarbonizing heat, bringing power to new customers, and squeezing more electrons from every square meter.

Your next move: pick one technology that directly serves your objective, run a tightly scoped pilot with clear KPIs, and scale in modular steps.

CTA: Ready to run a pilot? Shortlist your site, define the offtake, and kick off a 30-day feasibility sprint today.

References

• A first-of-its-kind geothermal project is now operational, Google, November 28, 2023. https://blog.google/outreach-initiatives/sustainability/google-fervo-geothermal-energy-partnership/
• NV Energy seeks new tariff to supply Google with 24/7 carbon-free power from Fervo, Utility Dive, June 21, 2024. https://www.utilitydive.com/news/google-fervo-nv-energy-nevada-puc-clean-energy-tariff/719472/
• Fervo Energy announces 31 MW power purchase agreement with Shell Energy North America, Fervo Energy, April 15, 2025. https://fervoenergy.com/fervo-energy-announces-31-mw-power-purchase-agreement-with-shell-energy/
• Fervo Energy’s record-breaking production results showcase rapid scale-up of enhanced geothermal, Fervo Energy, September 10, 2024. https://fervoenergy.com/fervo-energys-record-breaking-production-results-showcase-rapid-scale-up-of-enhanced-geothermal/
• Fervo and FORGE report breakthrough test results signaling more progress for enhanced geothermal, Journal of Petroleum Technology (SPE), September 16, 2024. https://jpt.spe.org/fervo-and-forge-report-breakthrough-test-results-signaling-more-progress-for-enhanced-geothermal
• Oxford PV debuts residential solar module with record-setting 26.9% efficiency, Oxford PV, June 19, 2024. https://www.oxfordpv.com/news/oxford-pv-debuts-residential-solar-module-record-setting-269-efficiency
• Oxford PV and Fraunhofer ISE develop full-sized tandem PV module with record efficiency of 25 percent, Fraunhofer ISE, January 31, 2024. https://www.ise.fraunhofer.de/en/press-media/press-releases/2024/oxford-pv-and-fraunhofer-ise-develop-full-sized-tandem-pv-module-with-record-efficiency-of-25-percent.html
• Oxford PV achieves solar panel world-record with 26.6% efficiency, Solar Power Portal, July 2024. https://www.solarpowerportal.co.uk/solar-pv/oxford-pv-achieves-solar-panel-world-record-with-26-6-efficiency
• Electric Hydrogen announces gigafactory in Devens, Massachusetts to enable ultra-low-cost green hydrogen production, Business Wire, May 4, 2023. https://www.businesswire.com/news/home/20230504005309/en/Electric-Hydrogen-Announces-Gigafactory-in-Devens-Massachusetts-to-Enable-Ultra-Low-Cost-Green-Hydrogen-Production
• Electric Hydrogen receives $18.3M transferable DOE tax credit for its gigafactory in Massachusetts, Electric Hydrogen, April 4, 2024. https://eh2.com/electric-hydrogen-receives-18-3m-transferable-doe-tax-credit-for-its-gigafactory-in-massachusetts-bringing-total-department-of-energy-support-to-65m/
• U.S. Department of Energy awards Electric Hydrogen $46.3M grant for electrolyzer manufacturing, Electric Hydrogen, March 14, 2024. https://eh2.com/u-s-department-of-energy-awards-electric-hydrogen-46-3m-grant-for-electrolyzer-manufacturing-under-the-bipartisan-infrastructure-laws-clean-electrolysis-program-2/
• Electric Hydrogen marks the opening of its electrolyzer gigafactory in Devens, Electric Hydrogen, December 2024. https://eh2.com/gigafactory-ribbon-cutting/
• Energy Dome signs first U.S. contract with Alliant Energy for commercial-scale deployment of its CO₂ Battery, Energy Dome, October 23, 2024. https://energydome.com/energy-dome-signs-first-u-s-contract-with-alliant-energy-for-commercial-scale-deployment-of-its-co2-battery/