Search: atomic absorption spectroscopy

Zinc in wort is measured using the AAS technique by directly aspirating the diluted sample into an acetylene oxygen flame or through electrothermal atomization; the measurement is made at 213.9 nm.

Copper in wort is measured using AAS by directly aspirating the diluted sample into an air-acetylene flame or by electrothermal atomization; the measurement is made at 324.7 nm.

The hydride technique is used to determine the concentration of antimony ions in the water sample. In this process, antimony ions are reduced by sodium tetrahydroborate in an acidic medium. This compound is then transferred using an inert gas into a heated quartz cuvette, is pyrolyzed and measured using AAS.

The absorbance is determined at a wavelength of 217.6 nm, and the antimony concentration is calculated using a reference curve.

The hydride technique is used to determine the concentration of arsenic ions in the water sample. In this process, arsenic ions are reduced by sodium tetrahydroborate in an acidic medium to arsine. This compound is then transferred using an inert gas into a heated quartz cuvette, is pyrolyzed and measured using AAS.

The absorbance is determined at a wavelength of 193.7 nm, and the arsenic concentration is calculated using a reference curve.

The lead content is determined by employing a flameless method which utilizes graphite furnace atomic absorption spectrophotometry. This technique is suitable for determining the lead content of water with very little lead contamination. Any matrix effects can be eliminated by using the standard additions calibration technique.

An aliquot of the sample is dosed into a graphite tube and is subsequently subjected to a program comprising a three-step temperature regime through electrothermic resistance heating. As the temperature increases in each step, the consecutive steps include drying, matrix pyrolysis (incineration) and thermal dissociation into free atoms (atomization). These can be carried out separately. During the analysis, the graphite tube is under an inert gas atmosphere (argon).

Also important for graphite furnace AAS is background correction, which can be achieved using a continuum radiation source (deuterium) or through the Zeemann effect. Background correction with the Zeemann effect is used for particularly difficult sample matrices.

A hollow-cathode lamp or an electrodeless discharge lamp, which contains the relevant element in gaseous state, usually serves as the light source.

The cadmium content is determined by employing a flameless method which utilizes graphite furnace atomic absorption spectrophotometry. This technique is suitable for determining the cadmium content of water with very little cadmium contamination. Any matrix effects can be eliminated by using the standard additions calibration technique.

An aliquot of the sample is dosed into a graphite tube and is subsequently subjected to a program comprising a three-step temperature regime through electrothermic resistance heating. As the temperature increases in each step, the consecutive steps include drying, matrix pyrolysis (incineration) and thermal dissociation into free atoms (atomization). These can be carried out separately. During the analysis, the graphite tube is under an inert gas atmosphere (argon).

Also important for graphite furnace AAS is background correction, which can be achieved using a continuum radiation source (deuterium) or through the Zeemann effect. Background correction with the Zeemann effect is used for particularly difficult sample matrices.

A hollow-cathode lamp or an electrodeless discharge lamp, which contains the relevant element in gaseous state, usually serves as the light source.