Spectrometry packs
PARTNERING BETWEEN IDIL & OCEAN OPTICS
Our Pack Spectrometers provide users with useful tools for setting major spectroscopy techniques. They are ideal for educational institutions, research labs and individuals seeking a complete solution for hands-on experiments in fields including physics, chemistry, biology, and environmental science. Each pack provides the essential components — spectrometer, light source, optical fiber and sampling accessories — required for performing a wide range of spectroscopic experiments, making it a valuable tool for learning and research.
What sets us apart?
Absorbance provides information about the chemical composition of materials in all states of matter. Use absorbance as a qualitative technique to identify substances or as a quantitative technique to determine the concentration of a molecule in solution.
Color is a human perception of the properties of the world formed by the interaction of light reaching the eye and interpreted by the brain. As a first step in color analysis, we can quantify the eye’s response by measuring the light that reaches the eye either directly or after it interacts with matter. Accurate color measurement requires precise spectroscopic characterization of illuminants and the reflectance or transmittance of the material being measured.
Fluorescence is a high-sensitivity technique in which molecules typically absorb a lower wavelength of incident light from one direction and emit a higher wavelength of light in all directions. With a known incident light wavelength, samples can be identified by their fluorescent emission spectra.
Irradiance is the flux per unit area striking a surface. Relative irradiance determines whether there’s more power at one wavelength than another, but not by how much. To calculate those values requires a spectrometer calibrated against a lamp of known spectral power output.
Plasma is an energized, gas-like state where a fraction of the atoms have been excited or ionized to form free electrons and ions. As the electrons of excited neutrals return to the ground state, the plasma emits light at wavelengths specific to the atoms present in the plasma. The spectral profile of the emitted light is used to determine the composition of the plasma. Plasma is formed using a range of high energy methods to ionize the atoms including heat, high powered lasers, microwaves, electricity and radio frequency.
Raman spectroscopy uses the scattering of laser light to probe molecular structure. Of every million photons scattered, a single photon interacts with the vibrational states of a sample molecule and emits light of a different wavelength. Raman can be used to measure various solids, liquids, and powders.
Optical Thin Film Measurement Systems is based on the measuring principle of spectroscopic reflectometry. By knowing the optical properties (n&k) of transparent or semi-transparent layers, their thin film thickness can be measure from 10 nm to 100 µm with 0.1 nm accuracy. This technique is a very fast, non-destructive and highly precise measuring method, suitable for ex and in-situ lab or industrial applications.
Go easily on a measurement campaign with the cabine-size case that contains all the measurement equipment and the battery. The harness option allows it to be transported in a backpack version.
