Proton Ori-Energy — Safe, Clean, Long-Duration Energy for a Changing World

The Energy Gap

Three Critical Gaps in the
Energy Transition

The world has deployed massive renewable capacity. But three structural gaps remain — they matter enormously for grid stability, access and security.

Long-Duration Storage Cost

Lithium-ion batteries work well for 2–6 hours. For 12-hour-plus durations, no clean technology has yet to compete with diesel on total cost of ownership at scale.

Cost gap

Safety in Critical Scenarios

Mines, islands, extreme-climate sites and data centers need power that is safe and stable in conditions where pressurised or liquid hydrogen creates unacceptable risk.

Safety gap

Affordable Access in Global South

1.3 billion people remain off-grid or diesel-dependent. Serving them requires technology that is deployable without heavy infrastructure, specialists or complex logistics.

Access gap

"The transition is real. But it is uneven — and the gaps that remain are not engineering details. They are structural barriers to a stable, equitable energy system."

Technology Case

Why Hydrogen.
Why Solid-State.

Hydrogen Is the Right
Long-Duration Vector

Hydrogen carries 33 kWh per kilogram — roughly 100× the energy density of a lithium-ion battery by weight. It does not degrade over months of storage. It can store seasonal surpluses and dispatch on demand. For long-duration and cross-season energy storage, no other medium comes close.

Li-ion battery

2–6 h

Flow battery

~12 h

Compressed H₂

Days – weeks

Solid-State H₂

Seasonal

Theoretical discharge duration capability →

Solid-State Overcomes
Conventional Hydrogen's Limits

High-pressure gas and liquid hydrogen are effective in industrial settings — but complex, expensive infrastructure makes deployment difficult in remote or harsh environments.

Near-Atmospheric Pressure

Stored at ≤ 0.1 MPa. No high-pressure vessels. No catastrophic failure mode. Deployable indoors, underground or in populated areas.

Wide Thermal Operating Range

−40 °C to +60 °C. Designed for Arctic mining operations, tropical islands, desert solar farms and everything in between.

Modular, Stackable Architecture

From kW to MW scale. Deployable by standard logistics. No specialized cryogenic equipment or high-pressure safety infrastructure required.

Rapid Charge / Discharge Cycles

Absorbs and releases hydrogen efficiently. Compatible with intermittent renewable inputs. No thermal runaway risk during rapid cycling.

The POE System

What POE Changes

Most hydrogen players focus on one layer. We deliver the full stack — from alloy science to energy-as-a-service.

L1

Advanced Alloy Materials

PKU-origin metal hydride alloys with optimized hydrogen capacity, kinetics and cycle life

Materials Science

↓

L2

Solid-State Storage Modules

Standardized, modular canisters at near-atmospheric pressure. Scalable from portable to grid-scale

Hardware

↓

L3

Integrated Power Generation Systems

Fuel cell + storage systems engineered as complete power infrastructure solutions

Integration

↓

L4

AI-Driven Control Platform

Predictive dispatch, remote monitoring, thermal management and lifecycle optimization

Intelligence

↓

L5

HaaS — Hydrogen as a Service

Capacity-based contracts. No upfront capex. Deployment, O&M and performance guarantees included

Business Model

vs. Battery Storage Longer duration, no degradation over months, no thermal runaway

vs. Compressed H₂ No pressure infrastructure, wider temperature range, simpler logistics

vs. Liquid H₂ No cryogenic equipment, no boil-off losses, no specialized training required

vs. Diesel Generators Zero emissions, silent operation, lower long-term TCO in target scenarios

Where We Deploy

Designed Around Real
Energy Challenges

Solid-state hydrogen systems were purpose-built for scenarios where conventional solutions fail on safety, logistics or cost.

Grid Infrastructure

Long-Duration Storage for Renewable Power Plants

Challenge: Solar and wind generate intermittently; batteries can't bridge days of low generation at viable cost.

POE: Store surplus renewable hydrogen across days and seasons; dispatch on-demand at near-atmospheric pressure.

→

Off-Grid

Green Energy Islands & Off-Grid Microgrids

Challenge: Islands and remote communities depend on costly diesel with no clean alternative that fits their logistics.

POE: Modular, ship-ready systems requiring no special infrastructure. Deploy, run, expand.

→

Heavy Industry

Mines & Heavy Industrial Sites

Challenge: Underground and remote mines need safe power in extreme temperatures where pressurised gas is prohibited.

POE: Near-atmospheric solid storage operates safely underground; wide thermal range covers Arctic to equatorial sites.

→

Mobile Systems

Drones, Robotics & Mobile Systems

Challenge: Battery-limited flight time and range constrain autonomous operations in defense, survey and logistics.

POE: High-energy-density, safe solid-state cartridges extend endurance without high-pressure refueling infrastructure.

→

Critical Infrastructure

Backup Power for Data Centers & Critical Infrastructure

Challenge: Diesel backup in urban data centers faces emission mandates, regulation and fuel supply risk.

POE: Clean, silent, indoor-safe backup power. Long shelf-life without degradation. AI-monitored readiness.

→

Hydrogen Economy

Green Hydrogen Storage, Transport & Distributed Delivery

Challenge: High-pressure tubes and liquid tanks make last-mile hydrogen delivery complex, expensive and risky.

POE: Safe solid-state cartridges enable truck, rail or drone delivery to industrial users, refueling stations and remote communities.

→

All Application Scenarios →

Foundation

Built on Science.
Designed for Deployment.

Research Origin

Rooted in Peking University Science

Our core alloy science originates from PKU's Weihai Institute of Ocean Research Hydrogen Energy Center and the Laboratory for New Energy Transformation, Center for Applied Superconductivity Research. Peer-reviewed research underpins our material performance claims.

Safety Architecture

Engineered for Zero Catastrophic Failure

Near-atmospheric-pressure storage eliminates the primary hazard of hydrogen systems. Thermal management and AI monitoring ensure safe operation from Arctic mines to tropical microgrids without specialized safety infrastructure.

Global Adaptability

Designed for the Underserved 70%

Global South markets, island nations, off-grid industrial sites and remote communities are not afterthoughts — they are the primary design context. Our systems require no grid connection, no hydrogen pipeline and no specialist infrastructure.

Ecosystem

Build the Next Clean Energy
Ecosystem Together.

We are not building a technology showcase. We are building a global deployment network with governments, utilities, developers and industrial operators.

Research Partner

PKU Weihai Institute of Ocean Research — Hydrogen Energy Center

Joint R&D on metal hydride alloy development. Source of core IP and materials science validation for commercial-grade storage modules.

Research Partner

PKU Center for Applied Superconductivity Research, Laboratory for New Energy Transformation

Collaborative research on hydrogen generation, storage and fuel cell integration. Foundation for system-level performance benchmarks.

International Deployment Partner

Qair — Global Renewable Energy Developer

Joint feasibility studies and pilot deployments for green hydrogen integration in utility-scale renewable energy projects across emerging markets.

Seeking Partners

Governments & Development Finance Institutions

Pilot programs, energy access mandates, and climate finance mechanisms for off-grid and island-nation deployments in the Global South.

Ready to Co-Create the Next Era of Green Energy?

We partner with developers, governments, industrial operators and investors who prioritize long-duration & clean energy as a strategic imperative.

Explore Partnership Models Get in Touch

Safe, Clean, Long-Duration Energy for a Changing World

Three Critical Gaps in theEnergy Transition