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Raman Spectroscopy Instrumentation: Overview01:26

Raman Spectroscopy Instrumentation: Overview

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A conventional Raman spectrophotometer includes a laser source, a sample holding system, a wavelength selector, and a detector.
The monochromatic laser source, typically using visible or near-infrared radiation, generates a highly focused beam of light. This light interacts with the molecules of the sample, scattering some of the light. Liquid and gaseous samples are usually tested in ordinary glass capillaries, while solids can be analyzed as powders packed in capillaries or as potassium...
604
Raman Spectroscopy: Overview01:20

Raman Spectroscopy: Overview

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The underlying principle of Raman spectroscopy is based on the interaction between light and matter, specifically molecules' inelastic scattering of photons. When a monochromatic beam of light, typically from a laser source, interacts with a sample, most scattered light has the same frequency as the incident light. This is known as Rayleigh scattering.
However, a small fraction of the scattered light exhibits a frequency shift due to the exchange of energy between the incident photons and...
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UV–Vis Spectrometers01:14

UV–Vis Spectrometers

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The absorbance of UV and visible (UV–visible) radiations is measured using a UV–visible spectrophotometer. Deuterium lamps, which emit UV radiation, and tungsten lamps, which produce radiation in the visible region, are used as light sources in UV–visible spectrophotometers. A monochromator or prism is used for diffraction grating, i.e., to split the incoming radiation into different wavelengths. A system of slits is used to focus the desired wavelength on the sample cell.
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IR Spectrometers01:25

IR Spectrometers

1.6K
There are two main infrared (IR) spectrophotometers: dispersive IR spectrometers and Fourier transform infrared (FTIR) spectrometers. In a dispersive IR spectrometer, a beam of infrared radiation produced by a hot wire is divided into two parallel equal-intensity beams using mirrors. One beam passes through the sample, while another is a reference beam. The beams then move through the monochromator, which separates the radiations into a continuous spectrum of different frequencies. The...
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Related Experiment Video

Updated: Oct 29, 2025

Non-contact, Label-free Monitoring of Cells and Extracellular Matrix using Raman Spectroscopy
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Non-contact, Label-free Monitoring of Cells and Extracellular Matrix using Raman Spectroscopy

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Cell-phone camera Raman spectrometer.

Dinesh Dhankhar1, Anushka Nagpal1, Peter M Rentzepis1

  • 1Department of Electrical and Computer Engineering, Texas A&M University, College Station, Texas 77843, USA.

The Review of Scientific Instruments
|July 10, 2021
PubMed
Summary
This summary is machine-generated.

A new cell-phone spectrometer enables in situ detection of chemicals and biological molecules using Raman and fluorescence spectroscopy. This portable device offers field applications for spectral analysis, including quantitative measurements and imaging.

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Area of Science:

  • Analytical Chemistry
  • Spectroscopy
  • Biotechnology

Background:

  • Raman and fluorescence spectroscopy are powerful analytical techniques.
  • Portable and in situ spectral analysis is highly desirable for field applications.
  • Existing spectroscopic equipment can be bulky and expensive.

Purpose of the Study:

  • To design, construct, and operate a cell-phone-based spectral detector.
  • To enable in situ detection, recording, and identification of chemicals, drugs, and biological molecules.
  • To demonstrate the system's capability for quantitative analysis and Raman imaging.

Main Methods:

  • Coupling a diffraction grating and cell-phone camera to create a spectrometer.
  • Utilizing Raman and fluorescence spectral measurements.
  • Employing a position scanning stage for Raman imaging.

Main Results:

  • Successfully recorded Raman spectra from various chemicals and biological molecules.
  • Obtained resonance-enhanced Raman spectra of carrots and bacteria.
  • Performed quantitative analysis of alcohol-water mixtures.
  • Constructed Raman images of samples.

Conclusions:

  • The cell-phone spectrometer system is effective for in situ Raman and fluorescence spectroscopy.
  • The compact and portable design is suitable for field applications.
  • This technology has the potential for integration into future cell-phones.