"Spectroscopy Applications in the Environment" by Avantes is a comprehensive guide highlighting the crucial role of spectroscopy in protecting our planet during a time when environmental preservation ...

Raman spectroscopy has emerged as a cutting-edge, non-invasive technique that deciphers the molecular composition of plants by measuring the inelastic scattering of light. This method offers rapid, ...

In this interview, Kevin Broadbelt of Thermo Fisher Scientific discusses the small molecule applications of process Raman spectroscopy. How do cell therapies differ in complexity compared to ...

The measurement of samples in the transmission configuration presents opportunities that conventional backscattering coupling with a microscope cannot address. Although not a recent innovation, ...

Raman spectroscopy is built on inelastic photon scattering and reveals individual molecular fingerprints. The article explores how it delivers precise details through peak position, shift, intensity, ...

The surge in popularity and acceptance of Fourier transform infrared (FTIR) spectrometers for use in quality assurance (QA) laboratories and on production floors is one of the major developments ...

Recent advancements in educational methodologies have incorporated spectroscopy and optical instrumentation to provide students with hands-on experiences in the fundamental principles of analytical ...

Spectroscopy isn’t just for scientists in lab coats—it’s a toolkit anyone can learn to use for uncovering the hidden architecture of molecules. By combining NMR, IR, and other techniques, chemists can ...

“Plasma” refers to a gas with a significant proportion of ionized molecules, which produce various excited ions, atoms, and molecules. Electrons liberated from ions and atoms are highly energetic and ...

Designated April 26, 2011, at Stony Brook University in Stony Brook, New York, and April 8, 2011, at Agilent Technologies in Santa Clara, California. MRI (magnetic resonance imaging) has become a ...

Periodic signal analysis enhances optics and photonics experiments using lock-in amplifiers and boxcar techniques.

AES operates on the principle of the Auger effect, named after the French physicist Pierre Auger. When a material's surface is bombarded with a beam of high-energy electrons or photons, it causes the ...