Advanced Instrumentation for Resonance-Based Material Measurement

Quamitry Labs develops the Resonance Tracing Instrument (RTI)™, a new class of measurement metrology for probing internal structure through time-domain resonance behavior.

Alongside RTI, Quamitry Labs is advancing additional programs including LithoLock Membrane, a solid-state battery interface concept for stabilizing lithium metal cells, and other resonance-informed materials technologies now in development.

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What RTI Measures

RTI actively interrogates materials using controlled resonant excitation and measures how that resonance returns through:

Time-domain delay and re-lock behavior
Phase coherence and dispersion
Directional and boundary-dependent response

These signals are fused to infer internal structural organization not accessible through conventional amplitude- or frequency-only methods.

Why This Matters

Existing measurement techniques typically observe surface response, averaged bulk properties, or single-domain signals. RTI introduces a boundary-first, time-domain approach that treats resonant delay itself as a structural signal.

This enables investigation of internal organization, transition regions, and failure boundaries using a fundamentally different measurement modality.

RTI introduces a boundary-first, time-domain approach that treats resonant delay itself as a structural signal, rather than an artifact to be averaged or filtered out.

Current Status

RTI development is underway. Phase 0 activities are complete, including instrument assembly, excitation tuning, baseline noise characterization, and failure-informed material selection.

Applications

Semiconductor inspection and validation
Advanced materials characterization
Non-destructive internal structure analysis
Research laboratories and instrumentation partners

LithoLock Membrane

LithoLock Membrane™ is a solid-state battery interface concept developed by Quamitry Labs to stabilize lithium metal cells by engineering the interphase as a functional membrane. In practical terms, this targets the failure modes that repeatedly limit scale-up: rising interfacial resistance, contact loss during stripping, void formation, and localized growth that can trigger shorts. Our first target chemistry is lithium metal with garnet-type solid electrolytes (LLZO family).

The internal architecture, called the IonGate Stack™, is a multilayer interphase approach designed around role separation: support low impedance ion transport while suppressing pathways that lead to instability. LithoLock also includes a formation method that treats formation as training, with a defined “stable interface” acceptance signature based on measurable electrochemical behavior.

If you are working on lithium metal or solid-state interfaces and want to evaluate a focused pilot, we can share a non-confidential pilot brief immediately and provide deeper technical details under NDA.