01 — QUEST · Solid-state Li-metal

QUEST — Ultra-high energy density SSB.

QpiVolta Ultra-high Energy-density SSB Technology — quasi-solid-state lithium-metal pouch cells, built on the equipment that already manufactures the world's lithium-ion batteries.

01QUESTSolid-state Li-metal 02QUANTSodium-ion 03QOREDiscovery engine 04QUBE-SSulphide SSB · 2027

Performance

The numbers, at the cell.

Specific energy450 Wh/kgProjected · NMC composite

10 → 80% charge15 min

Cycle life1,000+Gen 2 target · Q2 2028

Operating windowUp to 70 °C

Landscape

The energy / safety frontier.

Every prior chemistry trades one for the other — gain density, lose safety, and vice versa. Quasi-solid-state lithium-metal moves the boundary itself, opening territory no liquid-electrolyte cell can reach.

Plot scale approximate · based on UL 9540A, NREL, and published cell-level data, 2023–2026.

02 — Technology

A cell, reconceived from its chemistry up.

Three breakthroughs, in series. Together they unlock the energy density step-change the industry has spent two decades pursuing — without the manufacturing dead-ends that derailed earlier solid-state efforts.

Quasi-solid electrolyte

A proprietary polymer-ceramic matrix replaces volatile liquid electrolyte — non-flammable, room-temperature-stable, and printable on conventional roll-to-roll lines.

Lithium-metal anode

We replace graphite with pure lithium, the highest-density anode chemistry physically possible. Two times the gravimetric energy in the same form factor.

Drop-in manufacturable

Cells are built on existing pouch lines — no exotic vacuum, sintering, or solid-electrolyte deposition. The path to scale is already paved.

Anatomy

Five layers.One drop-in cell.

Scroll to open the cell — every layer is engineered to be made on the equipment that already builds the world's lithium-ion batteries.

01Anode current collectorCopper foil with QpiVolta surface treatment for uniform Li plating.

02Ultra-thin lithium-metal anode10× the theoretical capacity of graphite, at a fraction of the thickness. Stable where conventional Li-metal fails.

03Quasi-solid electrolyteCeramic-polymer composite. Suppresses dendrites without the cost of a true solid stack.

04Composite cathodeNMC / LFP / LMFP — high-nickel chemistries blended with proprietary catholyte for room-temperature ion transport.

05Cathode current collectorAluminum foil — drop-in compatible with existing roll-to-roll lines.

Open the cell

02 — The cell

Built for the world it’s going into.

Three automotive-grade form factors, all in production today. Drop-in compatible with existing pack architectures from EV platforms to grid storage.

Hover a cell to inspect— —

QpiVolta cells

Each cell is built on the same quasi-solid-state platform — different geometries, identical chemistry.

Capacity—

Voltage—

Cycle life—

Stage—

QPV / CELLSREV. 04 — 20263 FORM FACTORSSCALE 1:1

Roadmap

QUEST to commercialization, Gen by Gen.

From first 2 Ah sample to 20 Ah commercial cell — released on the same quasi-solid-state platform, validated on our pilot line.

2027Sample
QUEST_Gen 1
Pouch · sample stage
Capacity
2 Ah
Cycles
750
Notes
Validation phase
First QUEST cells off the pilot line — sample units for OEM evaluation and characterization.
Q2 2028Scale
QUEST_Gen 2
Pouch · scale-up
Capacity
20 Ah
Cycles
1,000
Notes
Pilot production
10× capacity step, full pouch format for automotive and eVTOL platforms. 1,000-cycle validated life.
Q3 2028Launch
QUEST_Gen 2 SSB Commercialization
Pouch · commercial
Capacity
20 Ah
Cycles
1,000+
Notes
GWh factory
Commercial release alongside QpiVolta GWh factory development. Volume shipments to lead partners.