GD-MS & LA-ICP-MS

Q: Can you quantify at ultra-low levels?

Often yes, but achievable limits depend on the matrix, elements, and measurement plan . Share your required limits and material type for method selection.

Q: Should I choose GD-MS or LA-ICP-MS for supplier qualification?

If the requirement is bulk purity , GD-MS is often the best fit. If you suspect localized contamination or inclusions, LA-ICP-MS adds crucial spatial evidence.

What Is GD-MS & LA-ICP-MS?

GD-MS (Glow Discharge Mass Spectrometry) and LA-ICP-MS (Laser Ablation–Inductively Coupled Plasma–Mass Spectrometry) are powerful techniques for multi-element trace analysis—especially when you need very low detection limits, broad elemental coverage, and strong materials insight.

GD-MS is primarily used for bulk and depth-resolved elemental analysis of solid, conductive (and some semi-conductive) materials. A glow discharge sputters atoms from the surface, which are then measured by mass spectrometry—making GD-MS highly effective for ultra-trace impurities and high-purity materials verification (sample-dependent).
LA-ICP-MS uses a focused laser to ablate microscopic amounts of material from a solid sample. The aerosol is carried into an ICP-MS for detection, enabling micro-area (localized) elemental analysis and elemental mapping—ideal for inclusions, particles, coatings, and heterogeneity investigations (project-dependent).

What These Methods Are Used For

Common goals

High-purity material qualification (supplier comparison, incoming QC, release support)
Trace contamination troubleshooting (unexpected metals causing corrosion, discoloration, catalyst poisoning, electrical leakage, etc.)
Process excursion investigations (tool wear, cross-contamination, carryover)
Failure analysis support (linking trace elements to defects, deposits, inclusions)

When to choose which

Choose GD-MS when you need bulk ultra-trace impurity levels in a solid and strong overall purity verification.
Choose LA-ICP-MS when you need spatial information: spot checks, line scans, maps, inclusions, or layered structures.

Why GD-MS / LA-ICP-MS (vs. Solution ICP-MS)?

Traditional solution ICP-MS requires digestion (acid prep), which can:

introduce contamination risk,
be slow for certain refractory materials,
lose spatial information.

GD-MS and LA-ICP-MS can reduce these limitations by:

analyzing solids directly (method-dependent),
enabling localized analysis (LA-ICP-MS),
supporting faster iteration for some investigations.

Sample Types We Support

GD-MS (sample-dependent)

High-purity metals and alloys (e.g., Al, Cu, Ni, Ti—project-dependent)
Sputtering targets and electronic materials (project-dependent)
Conductive ceramics or specialty solids (project-dependent)

LA-ICP-MS (project-dependent)

Metals, alloys, and specialty materials
Ceramics, glasses, minerals
Coatings and layered structures (thickness/feature dependent)
Polymers with fillers/inclusions (project-dependent)
Particles, inclusions, weld/HAZ regions, defect sites
Semiconductor and battery-related solids (project-dependent)

Best practice: include a reference/control sample (known-good lot) for side-by-side comparison.

Typical Workflows

Ultra-Trace Purity Verification (GD-MS)

Best for: supplier qualification, high-purity specifications

Multi-element impurity panel
Lot-to-lot comparison and trend summary
Pass/fail reporting vs your limits (if provided)

Localized Contamination Hunt (LA-ICP-MS)

Best for: inclusions, defects, “where is it coming from?”

Targeted spot analysis on ROI (region of interest)
Optional line scans or maps (project-dependent)
Correlate with microscopy (e.g., SEM-EDS) when useful

Root Cause Package (GD-MS + LA-ICP-MS)

Best for: high-impact excursions

Bulk purity check (GD-MS) + localized confirmation (LA-ICP-MS)
Clear separation of bulk background vs localized contaminant hotspots
Actionable conclusion and next-step verification plan

What You Receive

Multi-element results table with units and reporting limits (method-dependent)
Measurement notes: calibration/QC approach, sample prep/handling summary
Comparison summary (reference vs suspect), including key deltas and likely significance
For LA-ICP-MS projects: spot list, ROI images, and optional maps/line scans (scope-dependent)
Clear conclusions: what’s present, what changed, likely source pathways, and next steps

Sample Submission Guidelines

Please provide

Material type, form (coupon/target/pellet/part), and application context
The question: purity verification, contamination source, mapping, or comparison
Any required spec limits and target elements (if applicable)
Lot/batch IDs and process history (tool changes, suppliers, handling, cleaning steps)
A reference/control sample whenever possible

Typical sample amounts

GD-MS: solid coupons/targets sized for mounting (dimensions project-dependent)
LA-ICP-MS: small coupons/sections; for mapping, provide enough area for multiple ROIs

Packaging tips

Use clean containers and gloves; avoid metal-to-metal rubbing
Label orientation and ROI; include photos if defects/inclusions are localized
If ultra-trace is critical, use cleanroom-style packaging where possible (project-dependent)