Mass Spectrometry

Description

Mass spectrometry is an established analytical technique that identifies compounds by the mass (more correctly, mass to charge ratio) of the analyte molecule. Mass spectrometry is especially noteworthy among analytical techniques because the signals produced by a spectrometer are the direct result of chemical reactions such as ionization and fragmentation, rather than energy state changes that are typical of most other spectroscopic techniques. Because of this distinction, mass spectrometry is considered the only definitive analytical technique and detector.

The first general application of molecular mass spectrometry occurred in the early 1940s in the petroleum industry for quantitative analysis of hydrocarbon mixtures in catalytic crackers.

Coupling mass spectrometers with gas chromatographic systems allows separation and subsequent determination of components of highly complex mixtures with a high degree of certainty.

Recently, manufacturers of mass spectrometers, particularly spectrometers coupled with gas chromatographs, have significantly reduced their overall size and increased durability. This allows what was once a laboratory bench top instrument to perform field analysis.

Typical Uses

In the environmental field, mass spectrometers are typically used as detectors for gas chromatographs. Because of the increased durability of modern instruments, field gas chromatographs/mass spectrometers (GC/MS) are capable of the same analyses as fixed laboratory instruments. EPA approved SW846 methods are then capable with field GC/MS instruments. Some SW846 methods include:

• Semi-volatile organic chemicals (SVOC) Method 8270C
• Base-neutral acids Method 8270C
• Dioxins Method 8280
• MTBE Method 8260
• Volatile Organic Chemicals (VOC) Method 8240
• Halogenated VOC Method 8260B

Theory of Operation

An Electron beam of 20 electron volts (ev) is used to extract an electron from a molecule. Excess energy from the beam will further fragment the molecular ion to fragment (daughter) ions with lower mass to charge ratio (mass).

The positive ions produced by electron impact are attracted through the slits of the ion source and mass analyzer. These ions are mass analyzed for differentiation according to their mass-to-charge ratios.

The mass sorted ions are detected by an electron multiplier and the resulting signal is sent to a data system for processing. A display of the electron multiplier signal generated by the sorted molecular ions is displayed as the mass spectrum.

In the case of a coupled GC/MS, one type of data display is an integrated sum of signals generated by the molecular ions plotted as a function of elution time from the GC column. This representation is a total ions current (TIC) chromatogram. Mass spectra can be extracted from each chromatographic peak of the TIC.

The mass spectrum is in the form of a bar graph that relates the relative intensity of mass peaks to their mass-to-charge ratio. The largest peak in each spectrum is termed the base peak. The heights of the remaining peaks are computed as a percentage of the base peak height. The spectrum may be compared to a spectral library for identification of the compound based on fragmentation pattern and peak ratios.

The individual TIC and ion peak intensities are directly related to the concentration of analyte in the sample extract making GC/MS an extremely powerful analytical tool for positive identification and quantitation of organic compounds.

System Components

Mass spectrometers consist of four basic components; ion sources, sample inlet systems, mass analyzers, and a transducer. A brief description of various types of each component is presented below.

Ion Sources

The starting point for a mass spectrometric analysis is the formation of gaseous analyte ions. Ionization methods fall into two categories: gas phase sources and desorption sources. Gas phase ionization relies on first vaporizing the analyte then ionizing it. Desorption sources ionize the analyte in a solid or liquid state. Click here for a list of ionization sources

Sample Inlet Systems

The purpose of the inlet system is to permit the introduction of a representative sample into the ion source. Types of inlets include batch inlets, direct probe inlets, and chromatographic inlets. Again, mass spectrometers used for environmental analysis are essentially detectors for gas chromatographs. The flow rate from capillary chromatographic columns is generally low enough that the column output can be fed directly into the ionization chamber of the mass spectrometer. For packed or magabore capillary columns, a jet separator is used to eliminate most of the carrier gas from the analyte. The removal of carrier gas is critical because the MS is operated under high vacuum. Introduction of carrier gas, therefore, would disturb the high vacuum.

Mass Analyzers

The function of the mass analyzer is analogous to that of the grating in an optical spectrometer. In mass spectrometers, dispersion is based upon the mass-to-charge ratios of the analyte ions rather than upon the wavelength of photons. Mass spectrometers are therefore categorized based on the type of mass analyzer in the instrument.

Two types of mass analyzers are typically used for GC/MS analysis: (1) the quadrupole mass analyzer, and (2) magnetic sector analyzer. The quadrupole MS interfaced with capillary-column GC, is the most commonly used in an environmental laboratory and field analysis. The sample extract is injected onto the capillary column on the GC, where the individual compounds in the complex mixture are separated. The individual compounds elute through the column at different rates into the MS for detection.

The second type of mass analyzer typically used in mass spectrometers is the magnetic sector. Magnetic sector mass spectrometers, also known as high resolution mass spectrometers, are significantly more sensitive than the quadrupole. For example, magnetic sector spectrometers detect dioxins at parts per trillion (ppt) levels in soil and parts per quadrillion (ppq) in water. Typically, high resolution MS is not used for field-based environmental analysis because of size and stability requirements of the instrument.

Transducers

Like an optical spectrometer, a mass spectrometer contains a transducer that converts the beam of ions into an electrical signal that can be processed, stored in computer memory, and presented in graphical form. Transducers commercially available for mass spectrometers include electron multipliers and the Faraday Cup. The electron multiplier is the transducer of choice for most spectrometers. Less common detection systems include photographic plates and scintillation counters.

Mode of Operation

Mass spectrometers are operated under high vacuum to remove atmospheric interferences that would affect the ionization process. All MS have safety devices so that ion source cannot become operational until high vacuum is attained. Because most MS are operated in conjunction with a gas chromatography, the removal of carrier gas is critical because the MS is operated under high vacuum. Introduction of carrier gas, therefore, would disturb the high vacuum.

Computers and microprocessors are integral in modern mass spectrometers. A characteristic of a mass spectrum is the wealth of structural data that it provides. For structural determination of a molecule, the heights and mass-to-charge ratios of each fragmentation peak in a spectrum is determined, stored, and displayed. Because the amount of information is so large, rapid acquisition and processing is essential. The microprocessor is essential for mass spectrometric data acquisition and manipulation. Several instrumental variables are controlled and monitored during data collection. First, the computer serves as the instrument controller. Operating parameters are set through communication via the keyboard. Secondly, the computer controls programs responsible for data manipulation and output.

The digitized ion-current signal is processed prior to display. The peaks are normalized, that is, the height of each peak relative to a reference peak is calculated. The largest peak in the spectrum, the base peak, is arbitrarily assigned a peak height of 100 (sometimes 1000). The mass to charge (m/z) value for each peak must also be determined. This assignment is frequently based on the time of the peak's appearance and the scan rate. Data are acquired as intensity versus time during a controlled scan of the magnetic or electric fields. Conversion from time to m/z requires careful periodic calibration. Calibration, or often called tuning, is achieved with perfluorotri-n-butylamine (PFTBA). For high resolution analysis, the standard may be added with the sample. The computer is programmed to recognize and use the peaks of the standard as references for mass assignments. For low resolution instruments, the calibration is obtained separately from the sample due to the possibility of peak overlap.

Mass spectrometry has been widely applied to the quantitative determination of one or more components of complex organic systems encountered in studies of environmental problems, as well as the petroleum and pharmaceutical industries. Currently, analyses are performed by passage of the sample through a chromatographic column and into the spectrometer. With the spectrometer set at a suitable mass-to-charge (m/z) ratio, the ion current is recorded as a function of time. This technique is called selected ion monitoring. Generally, the areas are directly proportional to the component concentrations. In this type of analysis, the mass spectrometer simply serves as a sophisticated selective detector for quantitative analysis.

In another type of quantitative mass spectrometry for molecular species, analyte concentrations are obtained directly from the heights of the mass spectral peaks. For simple mixtures, it may be possible to find peaks at unique m/z values for each component. Under these circumstances, calibration curves of peak heights versus concentration are constructed and used for analysis of unknowns. More accurate results can be achieved by incorporating a fixed amount of an internal standard substance in both samples and calibration standards. The ratio of peak intensity of the analyte species to that of the internal standard is then plotted as a function of analyte concentration. The internal standard reduces uncertainties in sample preparation and introduction.

Target Analytes

• Semi-volatile organic chemicals (SVOC)
• Base-neutral acids
• Dioxins
• Volatile Organic Chemicals (VOC)
• Halogenated VOC
• Pesticides and PCBs

Performance Specs

Performance specs include information on detection limits, calibration, and quality control.

Detection Limits

Part per billion detection limits have been reported for quadrupole mass spectrometers. Magnetic sector mass spectrometers, also known as high resolution mass spectrometers, are significantly more sensitive than the quadrupole. For example, magnetic sector spectrometers detect dioxins at parts per trillion (ppt) levels in soil and parts per quadrillion (ppq) in water.

Calibration

Analyses are performed by passage of the sample through a chromatographic column and into the spectrometer. With the spectrometer set at a suitable mass-to-charge (m/z) ratio, the ion current is recorded as a function of time. This technique is called selected ion monitoring. Generally, the areas are directly proportional to the component concentrations. In this type of analysis, the mass spectrometer simply serves as a sophisticated selective detector for quantitative analysis.

In another type of quantitative mass spectrometry for molecular species, analyte concentrations are obtained directly from the heights of the mass spectral peaks. For simple mixtures, it may be possible to find peaks at unique m/z values for each component. Under these circumstances, calibration curves of peak heights versus concentration are constructed and used for analysis of unknowns. More accurate results can be achieved by incorporating a fixed amount of an internal standard substance in both samples and calibration standards. The ratio of peak intensity of the analyte species to that of the internal standard is then plotted as a function of analyte concentration. The internal standard reduces uncertainties in sample preparation and introduction.

Quality Control

Method blanks are periodically analyzed to monitor laboratory and instrument-induced contaminants. A method blank must not contain any analyte in a concentration higher than the practical quantitation limit.

Matrix spike and matrix spike duplicate samples are analyzed to evaluate the efficiency of the sample preparation, precision of the analysis, and matrix effect.

Laboratory control samples are used to evaluate the accuracy of the analysis. The control samples are obtained from outside sources and contain known amounts of analytes. The values obtained by analysis of the control samples are compared with the known true values. The supplier of the control samples usually provides control limits. The results obtained should fall within the published range of acceptance values.

Advantages

• Mass spectrometry provides definitive compound identification.
• As a GC detector, identification of compounds that cannot be achieved by GC-PID, GC-FID, or GC-ECD is possible.
• Field portable quadrupole mass spectrometers are now available.

Limitations

• Instrumentation is relatively expensive.
• Instrumentation operation requires a higher degree of expertise than most other instrumentation.

Cost Data

Mass spectrometer costs vary significantly. Instrument design and accessories affect instrument prices. Manufacturers listed below should be contacted directly for cost information.

Verification/Evaluation Reports

Verification of the performance of site characterization and field analytical technologies is conducted through a variety of programs. Evaluation and verification reports from EPA's Superfund Innovative Technologies Evaluation (SITE) Measuring and Monitoring Program, EPA's Environmental Technology Verification Program (ETV) program, along with links to certification statements from California EPA's (CalEPA) California Environmental Technology Certification Program, are provided below.

Superfund Innovative Technologies Evaluation (SITE) Measuring and Monitoring Program
The SITE Demonstration Program encourages the development and implementation of innovative treatment technologies for (1) remediation of hazardous waste sites and (2) monitoring and measurement. In the SITE Demonstration Program, the technology is field-tested on hazardous waste materials. Engineering and cost data on the innovative technologies are gathered so that potential users can assess the technology's applicability to a particular site. Data collected during the field demonstration are used to assess the performance of the technology, the potential need for pre- and post-treatment processing of the waste, applicable types of wastes and waste matrices, potential operating problems, and approximate capital and operating costs. The following reports from the measuring and monitoring program are available for mass spectrometry:

No reports available for this technology

EPA's Environmental Technology Verification (ETV) Program
EPA's Environmental Technology Verification (ETV) Program verifies the performance of innovative technologies. ETV was created to substantially accelerate the entrance of new environmental technologies into the domestic and international marketplaces. ETV verifies commercialized, private sector technologies. After the technology has been tested, the companies will receive a verification report that they can use in marketing their products. The results of the testing also are available on the Internet. The following reports from the ETV program are available for mass spectrometry:

• Bruker-franzen Analytical Systems, Inc Model EM640TM was verified for measurement of volatile organics in soil, water, and soil gas. The verification documents available consist of a verification report and verification statement.
  
  
• Inficon, Inc. - HAPSITE with Headspace Sampling Accessory was verified for measurement of chlorinated volatile organic compounds in water. The verification documents available consist of a verification report and verification statement.
  
  
• Viking SpectraTrakTM 672 was verified for measurement of volatile organics in soil, water, and soil gas. The verification documents available consist of a verification report and verification statement.

California EPA's California Environmental Technology Certification Program
CalEPA's environmental technology certification program is a voluntary program that provides participating technology developers, manufacturers, and vendors an independent, recognized third-party evaluation of the performance of new and mature environmental technologies. Developers and manufacturers define quantitative performance claims for their technologies and provide supporting documentation; CalEPA reviews that information and, when necessary, conducts additional testing to verify the claims. The technologies, equipment, and products that are proven to work as claimed are given official state certification. The certification program is voluntary and self-supporting. Companies participating in the program pay the costs of the evaluation and certification of their technologies.

Technologies that have been certified through this program are listed below. Links are provided to the web sites that provide the Certified Environmental Technology Transfer Advisory and Certification Notice for the technologies.

No reports available for this technology.

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Page Last Modified: November 30, 2006