Graphite furnace atomic absorption spectroscopy (GFAAS), also called electrothermal atomic absorption spectroscopy (ETAAS), is a type of spectrometry that uses a graphite-coated furnace to vaporize samples for elemental analysis. The method relies on free atoms absorbing characteristic light at specific wavelengths. Samples are deposited in a graphite or pyrolytic carbon coated tube, heated to produce free atoms, whose absorption relates to analyte concentration. While the Beer-Lambert law is difficult to apply directly due to matrix effects, calibration with standards allows accurate quantification. GFAAS offers advantages like ppb-level detection limits, reduced interferences, and the capability to analyze various elements across diverse sample matrices.
System components
GFAA spectrometry instruments have the following basic features: 1. a source of light (lamp) that emits resonance line radiation; 2. an atomization chamber (graphite tube) in which the sample is vaporized; 3. a monochromator for selecting only one of the characteristic wavelengths (visible or ultraviolet) of the element of interest; 4. a detector, generally a photomultiplier tube (light detectors that are useful in low-intensity applications), that measures the amount of absorption; 5. a signal processor-computer system (strip chart recorder, digital display, meter, or printer).
Mode of operation
Most currently available GFAAs are fully controlled from a personal computer that has Windows-compatible software. The software easily optimizes run parameters, such as ramping cycles or calibration dilutions. Aqueous samples should be acidified (typically with nitric acid, HNO3) to a pH of 2.0 or less. GFAAs are more sensitive than flame atomic absorption spectrometers, and have a smaller dynamic range. This makes it necessary to dilute aqueous samples into the dynamic range of the specific analyte. GFAAS with automatic software can also pre-dilute samples before analysis. After the instrument has warmed up and been calibrated, a small aliquot (usually less than 100 microliters (μL) and typically 20 μL) is placed, either manually or through an automated sampler, into the opening in the graphite tube. The sample is vaporized in the heated graphite tube; the amount of light energy absorbed in the vapor is proportional to atomic concentrations. Analysis of each sample takes from 1 to 5 minutes, and the results for a sample is the average of triplicate analysis. Faster graphite furnace techniques have been developed utilising the injection of samples into a pre-heated graphite tube.1
Standards
- ASTM E1184-10: "Standard Practice for Determination of Elements by Graphite Furnace Atomic Absorption Spectrometry."
- ASTM D3919-08: "Standard Practice for Measuring Trace Elements in Water by Graphite Furnace Atomic Absorption Spectrophotometry."
- ASTM D6357-11: "Test Methods for Determination of Trace Elements in Coal, Coke, & Combustion Residues from Coal Utilization Processes by Inductively Coupled Plasma Atomic Emission, Inductively Coupled Plasma Mass, & Graphite Furnace Atomic Absorption Spectrometry."
See also
- EPA Analytic Technology Encyclopedia Archived 2010-01-15 at the Wayback Machine
- Research Group of Atomic Spectrometry Archived 2018-06-17 at the Wayback Machine
References
J. At. Spectrom., 1989,4, 257-260 ↩