Solar Energy Storage Solutions

A new battery is rising — and it works by dropping 50-ton blocks into old mine shafts to light up the grid. Around the world, renewable energy is gaining momentum, but there’s still a problem no one has solved completely — storage. Solar and wind energy aren’t always available when demand is high, and lithium-ion batteries, while helpful, come with environmental downsides and a limited lifespan. Enter a radically different concept that uses no chemicals, no flames, and no lithium: gravity. The idea is surprisingly elegant. You lift a huge weight when there’s extra energy on the grid — storing potential energy. When energy is needed later, the weight is dropped, spinning a generator as it falls. That motion produces electricity on demand. It’s a battery that charges by lifting and discharges by dropping. This principle is already used in pumped hydroelectric stations, but gravity batteries don’t need lakes or rivers. They just need height and mass — things like steel blocks and vertical shafts. This makes them far more flexible. They can be placed in old buildings, custom towers, or even underground. Scotland’s Gravitricity is leading this field. In a recent test, they used a 250 kW system to lift and drop 50-ton weights, successfully powering machinery with precision. Their next step? Transforming abandoned mine shafts into vertical energy storage systems. These shafts — once used for coal — could now help store wind and solar energy. Because these systems rely on simple mechanical parts, they don’t degrade like batteries. They last decades. There’s no risk of fire, no chemical leakage, and no rare-earth metals required. In a world trying to reduce waste, that’s a massive advantage. This is renewable energy storage that doesn’t fight nature — it works with it.

This spring, California hit a new milestone: battery storage delivered more than 10 GW of instantaneous electricity—2 GW more than last year. Last week, on June 17th, we were even close to 11 GW with 10.9 GW of batteries discharged at 8:00pm. Even more striking: during those peak hours, batteries became the largest single source of electricity on the grid, outpacing gas, solar, and wind. Is that good news? Yes… and no. ✅ Yes, because batteries are stepping in when solar drops off in the evening, helping avoid additional gas-fired generation. They store excess solar energy during the day and release it when demand peaks—exactly how a clean grid should work. ⚠️ But there’s a catch. As summer heats up, air conditioning demand rises, and there’s less surplus solar left to charge the batteries. That’s why we often see the biggest battery discharges in spring or fall, not in July or August. So while solar + batteries is a big part of the solution, it shouldn't be the only one. To get the most out of battery assets—both for the grid and for returns—accurate solar generation and price forecasts are essential, along with smart optimization across markets. Gone are the days when the playbook was simple: charge at midday, discharge in the evening. In today’s market, battery dispatch is anything but routine. And building those tools is an exciting challenge!

Revolutionizing Energy Storage: Exowatt’s Heat Battery Tech Alex Wilhelm and Exowatt's Hannan P. discuss Exowatt’s innovative energy solution for data centers and industrial use. • Modular Power System: Each unit, the size of a 40-ft shipping container, collects solar energy through custom lenses and stores it as high-temperature heat. • Breakthrough Heat Battery: Unlike traditional lithium-ion batteries, Exowatt’s solid-state heat battery stores energy cheaply, without chemical reactions or degradation, maintaining efficiency over time. • Game-Changing Cost: This system enables 24-hour renewable power dispatch at a fraction of the cost—targeting the elusive 1 cent per kilowatt-hour goal. A transformative approach to powering the energy-intensive future of AI and data centers.

California generates more solar power than it can use. The challenge isn’t making clean energy—it’s storing it. The state’s battery capacity jumped from 500 megawatts in 2018 to nearly 16,000 megawatts in 2025. During peak solar hours, California often produces excess electricity that would otherwise go to waste. Now those giant batteries scattered across the Mojave Desert capture that surplus and release it when the sun sets. This couldn’t come at a better time. Data centers powering AI are consuming electricity at unprecedented rates, while electric vehicle adoption is reshaping energy patterns. At peak times, stored solar power supplies up to 30% of California’s electricity. We’ve figured out how to bottle sunshine—but energy demand continues to rapidly increase and more solutions like this are needed to keep our grid resilient. Post edit: incredible how much interest this post got! It looks like there was a hiccup in the picture regarding nuclear generation, don’t want to miss that, find the updated image in the comments below:! #SolarEnergy #EnergyStorage #AI #ElectricVehicles

Nanoramic, Inc. isn’t just their name—it’s their blueprint. They’re zooming in on the atomic scale while taking a panoramic view of the energy landscape. This isn’t tinkering at the edges of battery tech; it’s a complete redesign of how energy is stored, managed, and deployed. With their proprietary Neocarbonix® technology, they’ve pulled off a balancing act that’s eluded the industry for decades: higher energy density, faster charging, and lower costs without cutting corners on sustainability. The $44M raised in this latest funding round isn’t just capital—it’s fuel for a mission. General Motors Ventures and Catalus Capital lead a roster of backers who see the bigger picture. GM’s involvement underscores that this isn’t about experimentation—it’s about scaling for global impact, with applications ready to roll out in #EV, #energygrids, and beyond. Samsung Ventures, Top Material, Fortistar, and Windsail Partners round out a coalition that understands how to move disruptive tech into mainstream adoption. What sets Nanoramic apart isn’t just what they’re solving—it’s how. For years, battery innovation has been boxed in by trade-offs: speed or capacity, affordability or sustainability. Neocarbonix® erases those lines, delivering batteries that perform better while cutting out harmful chemicals like #PFAS and #NMP solvents. This isn’t just a win for manufacturers—it’s a seismic shift for the entire supply chain. Cleaner production, safer materials, and lower costs mean this tech doesn’t just meet the moment—it defines it. John Cooley, a Massachusetts Institute of Technology trained visionary, has steered Nanoramic with precision, aligning breakthrough science with real-world demands. Partnerships with some of the world’s largest automotive OEMs are already in motion, proving that their technology isn’t just viable—it’s inevitable. This isn’t a startup chasing hype; it’s a company carving out a path to make batteries more scalable, sustainable, and essential. But the real power here isn’t just in the tech—it’s in the timing. As industries from automotive to energy grids scramble to adapt to electrification, Nanoramic is delivering the tools to make it possible. Energy density and thermal management aren’t just technical challenges; they’re the keys to unlocking the future. And with Neocarbonix®, that future doesn’t look theoretical—it looks unstoppable. When you build a platform that eliminates compromise and accelerates progress, you’re not just participating in a transition; you’re driving it. Every battery they touch, every partnership they forge, pushes the boundaries of what energy storage can achieve. #Startups #StartupFunding #Energy #CleanEnergy #DeepTech #Batteries #BatteryTech #Sustainability #VentureCapital #Technology #Innovation #Manufacturing #SupplyChain #TechEcosystem #StartupEcosystem

India’s Deepening Duck Curves Highlight Urgent Need for Storage and Demand-Side Solutions The January and April duck curves below reveal India’s growing net demand gap: solar generation floods the grid during the afternoon, but demand surges again in the evening—just as solar fades. The chart shows average hourly demand (solid black lines) and net demand (demand minus variable renewables, in colored lines) from 2019 to 2027 (actuals through 2025; projections for 2026–2027). By 2025, India had become energy sufficient across the day, but increasingly peak deficient. Key insights: ✅ Surplus solar during midday ⚠️ Steep evening ramps stressing thermal generators 🔥 ~50 GW higher nighttime demand in April vs January—likely due to cooling loads This growing mismatch creates operational challenges for thermal power plants and raises the risk of evening shortfalls, especially during hot months. Energy storage is now essential—to shift solar generation from afternoon to evening and maintain grid reliability. Just as important are demand-side strategies, including energy-efficient cooling, time-of-day pricing, and demand response programs. These can help flatten the curve, reduce system costs, and enhance reliability. India’s duck curve is no longer a future—it’s already here. Now is the time to act. #DuckCurve #EnergyStorage #IndiaEnergyTransition #CoolingDemand #GridFlexibility #Renewables #EnergyEfficiency #DemandResponse #EnergySecurity Amol Phadke Shruti Mahajan Deorah Neelima Jain Umed Paliwal Soonee Sushil Kumar Narasimhan S.R. Samir Chandra Saxena India Energy & Climate Center (IECC) Ministry of New and Renewable Energy (MNRE) Grid Controller of India Limited

Battery costs have dropped more than 75% since 2015, unlocking a key driver of the energy transition. By storing excess solar and wind power when supply is high and delivering it when demand peaks, batteries help balance an increasingly renewable grid. As costs continue to fall and production scales up, cheaper batteries will play a critical role in decarbonizing transportation and the power sector. The energy transition is driven by markets, and lower battery prices are making renewable energy more competitive than ever. International Energy Agency (IEA): https://lnkd.in/daHnUBHB

What happens when more than 28 GW of the ERCOT fleet goes out on extended maintenance at the same time, including a large number of the fast-ramping gas peaking units? Nothing. When you have 10 GW of dispatchable energy storage to back it up. Today, Net Load + Thermal Outages peaked at 71.7 GW! Fortunately, there is now ~10 GW of battery energy storage operating on the grid on a daily basis. Peak dispatch today of these units was 4.5 GW, which at the time was 9.7% of all dispatching units and of net load requirements. Up from 0% 24 months ago. Why only 4.5 GW out of 10 GW? Because as a group they deployed for many hours, optimized based on traders and AI algorithms. In addition, there were another ~4-5 GW of battery storage units in the ancillary markets. Why does this matter? Because having instant-ramping battery energy storage backing up the system in the ancillary markets helps CREATE additional gas capacity by ensuring that gas units can participate in the energy market and not just sit in reserve. Ancillary markets are critical for the safe operation of the grid by providing instant backups when unforeseen events occur. By allowing technology-appropriate optimization of the whole system and battery storage to provide backup services, new gas capacity has been created that now is able to focus on energy markets during tight days like today. Today is the epitome of what actual resource adequacy (RA) and Reliability looks like, and highlights the negligent approaches to RA and Reliability that classical approaches like rote ELCC calculations wantonly avoid. Today also highlights why it would be sheer lunacy to use DRRS as a reliability product without the inclusion of 4-hour battery energy storage, given that the thermal fleet is a massively-correlated systemic risk to the system during the periods when it must take planned outages for maintenance. Reliability and Resource Adequacy must be defined by clear and objective technical operating criteria to promote technological innovation and the addition of new uncorrelated resource types - rather than discriminating against specific resources. When the thermal fleets have to go on maintenance, the power still needs to flow. If market participants hadn't built 10 GW of battery energy storage in 36 months, then 4.5 GW wouldn't have been available at the peak moment of net load, and the PRC would have dropped from ~7 GW down to 2.5 GW. Today would have been an EEA 2 event with prices at the market cap of $5000/MWh without the billions of dollars invested in the construction of battery energy storage built in the last 36 months. #ERCOT #ResourceAdequacy #DispatchablePower #Powermarketdesign #energystorage