Peak Energy
Americas first vertically integrated energy storage company.
Peak's Mission
Our Mission
At Peak Energy, we’re building the backbone of a stable, energy-independent future.
The grid is under pressure — aging infrastructure, volatile supply chains, and growing demand are exposing the limits of the system we rely on. What the U.S. needs isn’t just cleaner energy. It needs control over when and where energy is available. That’s why we exist.
We engineer, scale, and deploy the best energy storage system in the world — designed not in theory, but for real deployment today. That means solving the full value chain, using proven manufacturing, and eliminating the complexity that makes other systems fragile and slow to scale.
We focus on execution — building reliable systems at the speed and scale the grid requires. Our technology is mature, our supply chain is domestic, and our architecture is built for long-term operation. The opportunity ahead is large, and the requirements are clear: safe, simple, scalable storage that can be deployed now.
Peak's Vision
Who we are
Peak Energy is Americas first vertically Integrated
Energy Storage company.
Energy is Prosperity. Today, we need more energy than ever. To advance technology, ensure economic growth, and build abundance across all aspects of life - Energy is key.
We design, engineer, manufacture and deploy the best technology at the right time to achieve one goal: Accelerate the Growth of the Electricity Grid.
America’s Future Grid
Challenges and Solutions
Challenge
Solution
01
The grid is aging fast and power demand is accelerating.
The U.S. grid was designed for a different era — one dominated by centralized fossil generation, stable baseloads, and predictable industrial demand. Today, that model is breaking down. Electricity use is increasing rapidly as EVs, heat pumps, and data centers come online. Meanwhile, many parts of the transmission and distribution network are over 40 years old and are pushed to their limits every day.
01
We need infrastructure that installs in weeks, not decades.
Meeting this new demand curve will require technologies that expand usable capacity without waiting on long-lead-time assets. We need systems that can deploy at the edge of the grid, support load growth on short timelines, and adapt to shifting regional demand — all without disturbing the community around them.
02
Supply and demand no longer align.
Power generation is increasingly variable. Solar produces midday, wind often peaks at night, but demand surges occur in the late afternoon and evening. This mismatch leads to curtailment of clean energy, over-reliance on gas peakers, and growing instability during peak load events.
02
Storage brings them back in sync.
Storage adds flexibility by decoupling generation from consumption. It allows operators to shift energy across hours or days, absorbing oversupply and delivering power when it’s most valuable. As renewable penetration increases, this time-shifting becomes essential to grid balance and system-level reliability.
03
Infrastructure upgrades are too slow
Conventional grid upgrades — substations, lines, transformers — can take up to a decade to complete and often face permitting, land use, and community resistance. This mismatch between infrastructure planning timelines and real-time demand growth limits the pace of electrification & economic prosperity.
03
Batteries deploy fast
Energy storage provides a flexible, distributed upgrade path. Systems can be deployed in months, not years, and sited where capacity is needed most. They relieve overloaded nodes, support N-1 contingencies, and act as modular capacity that grows with local conditions — without deep grid reinforcement.
04
Legacy batteries were built for cars.
Lithium-ion cells were developed for consumer electronics and electric vehicles, where weight and energy density are paramount. But the grid has different requirements: long operational life, thermal stability, and minimal on-site servicing. Adapting EV batteries to grid applications requires over-engineering which creates complexity, cost, and reliability issues.
04
The grid needs its own solution.
Grid-scale storage demands a different class of technology — designed around uptime, operation in all climates, and long life. It needs to be safe without containment, efficient without cooling, and serviceable without intervention. Infrastructure should behave like infrastructure — not consumer tech with a warranty.
05
Energy security is national security.
The materials used in most storage systems — specifically lithium — are globally concentrated and geopolitically sensitive. Processing often occurs overseas, far from deployment sites. This creates exposure to price volatility, export controls, and geopolitical tension — all at odds with national infrastructure goals.
05
The grid needs domestically sourced, infrastructure-ready storage.
A secure and scalable energy system starts with materials we can control. Grid storage must be based on abundant, non-critical inputs and manufactured at home. Domestic production not only strengthens resilience but unlocks compliance with long-term policy objectives — from sourcing to operation.
America’s Future Grid
Challenges and Solutions
01
The grid is aging fast and power demand is accelerating.
The U.S. grid was designed for a different era — one dominated by centralized fossil generation, stable baseloads, and predictable industrial demand. Today, that model is breaking down. Electricity use is increasing rapidly as EVs, heat pumps, and data centers come online. Meanwhile, many parts of the transmission and distribution network are over 40 years old and are pushed to their limits every day.
02
Supply and demand no longer align.
Power generation is increasingly variable. Solar produces midday, wind often peaks at night, but demand surges occur in the late afternoon and evening. This mismatch leads to curtailment of clean energy, over-reliance on gas peakers, and growing instability during peak load events.
03
Infrastructure upgrades are too slow
Conventional grid upgrades — substations, lines, transformers — can take up to a decade to complete and often face permitting, land use, and community resistance. This mismatch between infrastructure planning timelines and real-time demand growth limits the pace of electrification & economic prosperity.
04
Legacy batteries were built for cars.
Lithium-ion cells were developed for consumer electronics and electric vehicles, where weight and energy density are paramount. But the grid has different requirements: long operational life, thermal stability, and minimal on-site servicing. Adapting EV batteries to grid applications requires over-engineering which creates complexity, cost, and reliability issues.
05
Energy security is national security.
The materials used in most storage systems — specifically lithium — are globally concentrated and geopolitically sensitive. Processing often occurs overseas, far from deployment sites. This creates exposure to price volatility, export controls, and geopolitical tension — all at odds with national infrastructure goals.
Challenge
Solution
America’s Future Grid
Challenges and Solutions
Challenge
Solution
01
The grid is aging fast and power demand is accelerating.
The U.S. grid was designed for a different era — one dominated by centralized fossil generation, stable baseloads, and predictable industrial demand. Today, that model is breaking down. Electricity use is increasing rapidly as EVs, heat pumps, and data centers come online. Meanwhile, many parts of the transmission and distribution network are over 40 years old and are pushed to their limits every day.
01
We need infrastructure that installs in weeks, not decades.
Meeting this new demand curve will require technologies that expand usable capacity without waiting on long-lead-time assets. We need systems that can deploy at the edge of the grid, support load growth on short timelines, and adapt to shifting regional demand — all without disturbing the community around them.
02
Supply and demand no longer align.
Power generation is increasingly variable. Solar produces midday, wind often peaks at night, but demand surges occur in the late afternoon and evening. This mismatch leads to curtailment of clean energy, over-reliance on gas peakers, and growing instability during peak load events.
02
Storage brings them back in sync.
Storage adds flexibility by decoupling generation from consumption. It allows operators to shift energy across hours or days, absorbing oversupply and delivering power when it’s most valuable. As renewable penetration increases, this time-shifting becomes essential to grid balance and system-level reliability.
03
Infrastructure upgrades are too slow
Conventional grid upgrades — substations, lines, transformers — can take up to a decade to complete and often face permitting, land use, and community resistance. This mismatch between infrastructure planning timelines and real-time demand growth limits the pace of electrification & economic prosperity.
03
Batteries deploy fast
Energy storage provides a flexible, distributed upgrade path. Systems can be deployed in months, not years, and sited where capacity is needed most. They relieve overloaded nodes, support N-1 contingencies, and act as modular capacity that grows with local conditions — without deep grid reinforcement.
04
Legacy batteries were built for cars.
Lithium-ion cells were developed for consumer electronics and electric vehicles, where weight and energy density are paramount. But the grid has different requirements: long operational life, thermal stability, and minimal on-site servicing. Adapting EV batteries to grid applications requires over-engineering which creates complexity, cost, and reliability issues.
04
The grid needs its own solution.
Grid-scale storage demands a different class of technology — designed around uptime, operation in all climates, and long life. It needs to be safe without containment, efficient without cooling, and serviceable without intervention. Infrastructure should behave like infrastructure — not consumer tech with a warranty.
05
Energy security is national security.
The materials used in most storage systems — specifically lithium — are globally concentrated and geopolitically sensitive. Processing often occurs overseas, far from deployment sites. This creates exposure to price volatility, export controls, and geopolitical tension — all at odds with national infrastructure goals.
05
The grid needs domestically sourced, infrastructure-ready storage.
A secure and scalable energy system starts with materials we can control. Grid storage must be based on abundant, non-critical inputs and manufactured at home. Domestic production not only strengthens resilience but unlocks compliance with long-term policy objectives — from sourcing to operation.
Historical Grid
Historical Grid
The Future Grid
The Future Grid
Capacity must be overbuilt to handle rare demand peaks.
Storage absorbs peak load — reducing overbuild and unlocking latent capacity.
Grid upgrades follow slow, expensive, and location-dependent buildouts.
Storage can be sited flexibly — deferring upgrades and accelerating grid access.
Storage decouples generation from demand — buying time and flexibility for operators.apacity must be overbuilt to meet rare, short-duration peaks.
Power supply and demand must be balanced instantaneously at all times.
Reliability hinges on spinning reserve and fossil inertia.
Storage delivers fast frequency response and synthetic inertia — without fuel burn.
Infrastructure growth is limited by interconnection bottlenecks.
Storage eases congestion and supports non-wires alternatives — unlocking new capacity faster.
Grid expansion is slow, expensive, and tied to fixed infrastructure.
Storage is modular and deploys where it’s needed — accelerating capacity without hard assets.
Supply and demand must match in real time — or the system fails.
Storage decouples production from consumption — enabling flexible, dynamic power delivery.
Reliability depends on gas peakers and mechanical inertia.
Storage delivers instantaneous response and synthetic stability — without fuel.
Growth is limited by interconnection queues and system congestion.
Storage clears bottlenecks and supports non-wires alternatives — expanding usable grid space.
Phased Blueprint
Phased Blueprint
Key milestones from founding through product development, pilot deployment, and commercial launch.
Key milestones from founding through product development, pilot deployment, and commercial launch.
We offer a monthly All-Inclusive plan for unlimited creative possibilities
{01}
Phase 1
2023-2025
Prove Technology
Deploy Pilot Systems
Build Manufacturing Foundation
Secure Customer Partnerships
Phase 1
2023-2025
Prove Optimal Technology at Lowest TCO. Deployed ESS capacity: 0.5 GWh [2023-2026]
Deploy Pilot Systems
Build Manufacturing Foundation
Secure Customer Partnerships
{01}
Phase 1
2023-2025
Prove Technology
Deploy Pilot Systems
Build Manufacturing Foundation
Secure Customer Partnerships
{02}
Phase 2
2026-2028
Scale Up
Lowest TCO and Fastest to Deploy
Scale Domestic Cell Manufacturing
Deploy Systems at Scale
Phase 2
2026-2028
[2027-2029] Fast, De-Risked Scale Domestically. Deployed ESS capacity: 0.5 GWh
Lowest TCO and Fastest to Deploy
Scale Domestic Cell Manufacturing
Deploy Systems at Scale
{02}
Phase 2
2026-2028
Scale Up
Lowest TCO and Fastest to Deploy
Scale Domestic Cell Manufacturing
Deploy Systems at Scale
{03}
Phase 3
2028 +
Vertically Integrate Energy Storage Value Chain
Next Generation Cell
Ramp Domestic Supply Chain
Integrate Power Electronics & Generation
Phase 3
2028 +
[2029+ ] Consolidate Energy Storage Value Chain. Deployed ESS capacity: 50+ GWh
Next Generation Cell
Ramp Domestic Supply Chain
Integrate Power Electronics & Generation
{03}
Phase 3
2028 +
Vertically Integrate Energy Storage Value Chain
Next Generation Cell
Ramp Domestic Supply Chain
Integrate Power Electronics & Generation