TOF-SIMS

Q: Can TOF-SIMS identify organic contamination (e.g., silicone, mold release, surfactants)?

Yes. TOF-SIMS is particularly strong for organic fragments and can often differentiate classes of contaminants using characteristic ion patterns and imaging.

Q: Can you quantify concentration?

TOF-SIMS is usually not absolutely quantitative without calibration standards due to matrix effects. Most projects focus on relative comparison and strong qualitative identification.

Q: How is TOF-SIMS different from XPS?

Both are surface techniques. XPS provides elemental composition and chemical states with quantitative capabilities (nm-scale depth). TOF-SIMS provides richer molecular fragment information and higher-resolution chemical imaging , often with greater sensitivity to trace organics and ions.

What is TOF-SIMS?

TOF-SIMS (Time-of-Flight Secondary Ion Mass Spectrometry) is an ultra-surface-sensitive technique that analyzes the top 1–3 nm of a material. A pulsed primary ion beam sputters the surface and generates secondary ions, which are separated by a time-of-flight mass analyzer to produce detailed spectra of elements, isotopes, and molecular fragments.

TOF-SIMS is especially powerful for detecting trace surface contamination, identifying organic films and additives, and performing high-resolution chemical imaging on complex materials.

What TOF-SIMS Can Help You Solve

Surface contamination identification (organic films, ionic residues, trace metals)
Cleaning effectiveness verification and process change comparison (before/after)
Root-cause support for adhesion loss, delamination, corrosion initiation, or electrical drift
Additive and residue analysis on polymer surfaces (mold release, plasticizers, surfactants)
Chemical imaging of particles/defects to locate and classify contaminants
Depth profiling (optional) to study layered structures, diffusion, and interfacial chemistry

Typical Applications

Semiconductor & electronics: organic/inorganic residues, mobile ions (Na/K), surface films, defect mapping
Thin films & coatings: surface chemistry, interfacial contamination, layer comparison
Polymers & adhesives: surface additives, migration/blooming, contamination films affecting bonding
Batteries & energy materials: surface films and degradation-related species (project-dependent)
Metals & corrosion studies: oxide/hydroxide species, inhibitors, trace contaminants
Particles/foreign materials: chemical mapping to identify source and composition

Capabilities & What You Receive

Key Measurement Modes (project-dependent)

Positive/negative ion spectra: broad chemical fingerprinting
High-mass-resolution spectra: molecular fragment identification and peak assignment support
2D chemical imaging: spatial distribution of selected ions (surface maps)
3D imaging / depth profiling (optional): ion intensity vs sputter time, and reconstructed volumes
Region-of-interest (ROI) analysis: compare spectra from defect vs non-defect areas

Deliverables

Full mass spectra (positive/negative as applicable)
Selected ion lists and peak assignment summary (project-dependent)
2D ion images / chemical maps (and 3D outputs if requested)
Depth profile plots for selected ions (if included)
Clear comparison conclusions (sample A vs B, before vs after process)

Sample Requirements

Sample types: wafers, flat coupons, thin films, coated parts, polymers, metals, small components (vacuum compatible)
Surface condition: clean and dry; avoid fingerprints, tape residue, and dust
Size & mounting: flat samples are preferred; provide dimensions and any mounting restrictions
Vacuum compatibility: samples must be stable under high vacuum (provide SDS if needed)
Reference/control sample: strongly recommended for contamination or process comparison
Information to provide: target species (e.g., Na/K/Li, F/Cl, hydrocarbons, silicone), process history, and the exact question (identify film, compare cleaning, map defect, etc.)

Workflow

Requirement review (surface survey vs imaging vs depth profiling; target ions; acceptance criteria)
Method planning (polarity, analysis area, imaging resolution, sputter plan if needed)
Sample handling & mounting using clean procedures
Measurement (spectra + imaging; depth profiling optional)
Data interpretation (peak assignment, ROI comparison, interference checks, normalization)
Report delivery (plots/images + findings + recommended next steps)

FAQs

How surface-sensitive is TOF-SIMS?

TOF-SIMS is extremely surface sensitive, typically probing only the top few nanometers. This makes it ideal for surface films and contamination that other bulk techniques may miss.

Can TOF-SIMS identify organic contamination (e.g., silicone, mold release, surfactants)?

Yes. TOF-SIMS is particularly strong for organic fragments and can often differentiate classes of contaminants using characteristic ion patterns and imaging.

Can you quantify concentration?

TOF-SIMS is usually not absolutely quantitative without calibration standards due to matrix effects. Most projects focus on relative comparison and strong qualitative identification.

Is TOF-SIMS destructive?

Surface analysis uses very low dose and may be minimally destructive, but depth profiling/3D requires sputtering and is destructive in the analyzed area.

How is TOF-SIMS different from XPS?

Both are surface techniques. XPS provides elemental composition and chemical states with quantitative capabilities (nm-scale depth). TOF-SIMS provides richer molecular fragment information and higher-resolution chemical imaging, often with greater sensitivity to trace organics and ions.

Have additional questions?