What is Mass Spectrometry?
What Is Mass Spectrometry?
Mass spectrometry (MS) is an analytical technique that measures the mass-to-charge ratio (m/z) of ions derived from a sample — providing molecular mass, structural information, elemental composition, and quantitative concentration data for a vast range of chemical species. It is one of the most powerful and sensitive analytical tools available, capable of detecting and identifying molecules at concentrations of parts per trillion and below, and is central to analytical chemistry in the materials, electronics, environmental monitoring, and life sciences industries.
How Mass Spectrometry Works
Step 1 — Ionisation
The sample must be converted to gas-phase ions before mass analysis. The ionisation method is critical and determines what types of samples can be analysed:
- Electron Ionisation (EI): Energetic electrons fragment molecules in the gas phase — producing characteristic fragmentation patterns for organic compound identification. Standard for GC-MS of volatile organics.
- Electrospray Ionisation (ESI): Charged droplets from a liquid spray produce multiply-charged ions from large biomolecules without fragmentation — enabling intact protein, polymer, and drug analysis by LC-MS.
- Matrix-Assisted Laser Desorption/Ionisation (MALDI): Laser pulses desorb the sample from a UV-absorbing matrix — producing intact ions of large biomolecules and synthetic polymers.
- Inductively Coupled Plasma (ICP): High-temperature argon plasma atomises and ionises all elements — the basis of ICP-MS for trace elemental analysis.
Step 2 — Mass Separation
Ions are separated by their mass-to-charge ratio (m/z) using electric and/or magnetic fields in the mass analyser:
- Quadrupole: Four rod electrodes with oscillating RF/DC fields filter ions sequentially — most common type, compact, affordable, and widely used in GC-MS and LC-MS
- Time of Flight (TOF): Ions are accelerated and their flight time to the detector is measured — higher mass ions arrive later, providing very high mass resolution and a wide mass range
- Orbitrap: Ions orbit an electrode with frequencies proportional to 1/√m — highest available mass resolution (>100,000), used in proteomics and pharmaceutical analysis
- Magnetic Sector: Combines magnetic and electric fields — used in isotope ratio MS and high-resolution elemental analysis
Step 3 — Detection
A detector (typically an electron multiplier, Faraday cup, or microchannel plate array) counts the arriving ions and generates a signal proportional to ion abundance. The resulting mass spectrum plots ion intensity vs. m/z.
Industrial Applications of Mass Spectrometry
Materials Characterisation — SIMS and MALDI
Secondary Ion Mass Spectrometry (SIMS) bombards a solid surface with primary ions and analyses the secondary ions sputtered from the surface — providing elemental and molecular depth profiles of thin films, interfaces, and dopant distributions in semiconductors and coatings. MALDI-TOF characterises synthetic polymer molecular weight distributions and end-group chemistry — complementing GPC/SEC.
Environmental Analysis — GC-MS
GC-MS is the gold standard for organic pollutant analysis in environmental samples — identifying and quantifying polycyclic aromatic hydrocarbons (PAHs), volatile organic compounds (VOCs), pesticide residues, and pharmaceutical compounds in water, soil, and air per EPA methods (8270D, 8260B, 8081A).
Electronics — ICP-MS for Ultra-Pure Chemical Qualification
As covered in Blog 16 of this series, ICP-MS determines trace metal contamination in semiconductor process chemicals at ppt levels — critical for wafer fabrication yield control.
Failure Analysis — GCMS and MALDI
GC-MS identifies organic contamination (silicone residues, plasticiser migration, flux residues) on failed electronic assemblies and bonded joints — as discussed in the adhesion failure analysis context. MALDI characterises polymer degradation products in aged materials.
Conclusion
Mass spectrometry is one of the most powerful, sensitive, and versatile analytical techniques for chemical characterisation, enabling identification and quantification of compounds at trace to ultra-trace levels. By combining advanced ionisation methods with high-resolution mass analysers, MS provides detailed insights into molecular structure, elemental composition, and concentration across a wide range of materials.
From environmental monitoring and semiconductor contamination control to polymer analysis and failure investigation, mass spectrometry is an indispensable tool in modern analytical science, supporting research, quality control, and regulatory compliance across industries.
Why Choose Infinita Lab for Mass Spectrometry Analysis?
Infinita Lab offers comprehensive Mass Spectrometry testing services, a Comprehensive lab network, project management, confidentiality, and rapid turnaround. Trust Infinita Lab for your material testing needs, Faster test results, cost savings, and reduced administrative workload.
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Frequently Asked Questions (FAQs)
What is mass spectrometry used for? Mass spectrometry is used to identify chemical compounds, determine molecular weight, analyse elemental composition, and quantify trace-level contaminants. It is widely applied in research, quality control, failure analysis, and environmental testing.
What does m/z mean in mass spectrometry? The term m/z stands for mass-to-charge ratio. It represents the ratio of an ion’s mass to its electrical charge and is the fundamental parameter used by the mass analyser to separate and identify ions.
What are the main types of ionisation methods? The main ionisation methods used in mass spectrometry include Electron Ionisation (EI) for volatile organic compounds, Electrospray Ionisation (ESI) for biomolecules and polymers, MALDI for large molecules such as proteins and synthetic polymers, and ICP ionisation for trace elemental analysis.
What are the common types of mass analysers? Common mass analysers include the quadrupole, which is widely used for routine analysis, Time of Flight (TOF) for high-speed and wide mass range applications, Orbitrap for ultra-high resolution measurements, and magnetic sector analysers for isotope and high-precision elemental analysis.
How sensitive is mass spectrometry? Mass spectrometry is extremely sensitive and can detect compounds at parts per billion (ppb), parts per trillion (ppt), and in some advanced systems even lower concentrations, depending on the sample type and instrument configuration.
