LaMotte SMART Spectro Spectrophotometer User Manual

SMART Spectro Operator’s Manual 2.11

11

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AN INTRODUCTION TO COLORIMETRIC ANALYSIS &

SPECTROSCOPY

Most test substances in water are colorless and undetectable to the human

eye. To test for their presence we must fi nd a way to “see” them. The LaMotte

SMART Spectro can be used to measure any test substance that is itself colored

or can be reacted to produce a color. In fact a simple defi nition of colorimetry is

“the measurement of color” and a colorimetric method is “any technique used

to evaluate an unknown color in reference to known colors”. In a colorimetric

chemical test the intensity of the color from the reaction must be proportional

to the concentration of the substance being tested. Some reactions have

limitations or variances inherent to them that may give misleading results. Many

such interferences are discussed with each particular test instruction. In the

most basic colorimetric method the reacted test sample is visually compared to

a known color standard. However, accurate and reproducible results are limited

by the eyesight of the analyst, inconsistencies in the light sources, and the

fading of color standards.
To avoid these sources of error, a colorimeter or spectrophotometer can be used

to photoelectrically measure the amount of colored light absorbed by a colored

sample in reference to a colorless sample (blank).
White light is made up of many different colors or wavelengths of light. A

colored sample typically absorbs only one color or one band of wavelengths

from the white light. Only a small difference would be measured between white

light before it passes through a colored sample versus after it passes through

a colored sample. The reason for this is that the one color absorbed by the

sample is only a small portion of the total amount of light passing through the

sample. However, if we could select only that one color or band of wavelengths

of light to which the test sample is most sensitive, we would see a large

difference between the light before it passes through the sample and after it

passes through the sample.
The SMART Spectro uses a quartz halogen lamp as the source of white light.

The white light passes through an entrance slit and is focused on a ruled grating

consisting of 1200 lines/mm. The grating causes the light to be dispersed into

various component wavelengths. The monochromator design allows the user to

select which specifi c wavelength of interest will be passed through the exit slit

and through the sample. The use of mirrors and additional fi lters prevents light

of undesired wavelengths (overtones, stray light) from making it to the sample. A

photodetector measures the amount of light which passes through the sample.
The difference in the amount of monochromatic light transmitted through a

colorless sample (blank) and the amount of monochromatic light transmitted

through a test sample is a measurement of the amount of monochromatic

light absorbed by the sample. In most colorimetric tests the amount of

monochromatic light absorbed is directly proportional to the concentration of

the test factor producing the color and the path length through the sample.

However, for a few tests the relationship is reversed and the amount of

monochromatic light absorbed is inversely proportional to the concentration of

the test factor.