What is the Difference Between Photometry and Spectrophotometry?
🆚 Go to Comparative Table 🆚The main difference between photometry and spectrophotometry lies in the way they measure light intensity. Here are the key differences between the two:
- Photometry measures the total brightness or intensity of light as seen by the human eye. It is only applicable to the visible light range and provides a single value for the intensity of light at a specific wavelength.
- Spectrophotometry quantifies the intensity of light that is either transmitted or reflected per wavelength. It is applied to the whole electromagnetic spectrum and provides values for different wavelengths. Spectrophotometers often comprise a monochromator to separate the various wavelengths of light and a scanning device.
In terms of applications, photometers are well-suited for measuring parameters at certain wavelengths, such as water (1.94 microns) or oil (1.72 microns). Spectrophotometers, on the other hand, can distinguish between various components being tested for, such as different kinds of alcohols or saturated and unsaturated fats. They also offer benefits over photometers when dealing with more challenging applications, such as salt, sugar, ash, and so on.
Photometers are generally less costly, simpler to calibrate, and easier to use for inexperienced personnel than spectrophotometers. If a photometer fulfills your measurement requirements, it is a superior option for on-line, at-line, and laboratory measurements. However, spectrophotometers are more suitable for applications that require precise measurements at specific wavelengths.
Comparative Table: Photometry vs Spectrophotometry
Here is a table comparing the differences between photometry and spectrophotometry:
Photometry | Spectrophotometry |
---|---|
Measures the intensity of light | Measures the intensity of light at specific wavelengths |
Used to measure the amount of light that passes through a sample material | Used to measure the amount of light that passes through a sample material and identify a compound or determine its concentration |
Does not provide information about the wavelengths of light absorbed or transmitted by the sample | Provides information about the wavelengths of light absorbed or transmitted by the sample, allowing for the identification of compounds and determination of their concentrations |
Can be used in various fields, but does not have the same level of specificity as spectrophotometry | Widely used in fields such as physics, biochemistry, material and chemical engineering, clinical applications, and industrial applications due to its specificity |
May be less accurate and precise than spectrophotometry due to the lack of wavelength information | More accurate and precise than photometry because it measures light intensity at specific wavelengths, allowing for better calibration and standardization |
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