Neutron spectroscopy is a technique used in condensed matter physics and materials science to study the dynamics and structure of materials at the atomic and molecular levels. It utilizes neutrons, which are neutral particles found in atomic nuclei, to probe the properties of various materials.

The Nephelauxetic effect refers to the phenomenon where the presence of certain ligands in coordination complexes reduces the bond strength and the energy separation between the d-orbitals of a metal ion. This effect is commonly observed in transition metal complexes. Specifically, when a metal ion is coordinated to ligands, the electrostatic repulsion between the electron clouds of the ligands and the d-electrons of the metal is lessened.

Spectral bands refer to specific ranges of wavelengths within the electromagnetic spectrum where light or other forms of electromagnetic radiation can be analyzed or measured. These bands are utilized in various fields, including remote sensing, telecommunications, astronomy, and more.

Multivariate optical computing (MOC) is an advanced computing paradigm that uses optical systems to perform computations, leveraging the unique properties of light. It involves the simultaneous processing of multiple variables or data dimensions, making it particularly well-suited for tasks that require handling complex, multidimensional data sets. ### Key Features of Multivariate Optical Computing: 1. **Optical Processing**: MOC uses light (usually lasers) to manipulate data.

Multipass spectroscopic absorption cells, also known as multipass cells or multipass absorbers, are optical devices used in spectroscopy to enhance the measurement of absorbance by increasing the path length of light passing through a sample medium. This is particularly useful in applications where the concentration of the absorbing species is very low, making detection challenging.

Multiangle light scattering (MALS) is a technique used to characterize the size, shape, and molecular weight of macromolecules in solution, such as proteins, polymers, and nanoparticles. This method is based on the scattering of light at multiple angles as it interacts with particles suspended in a liquid.

Shape resonance is a phenomenon that occurs in quantum mechanics, particularly in the study of scattering processes. It refers to a temporary trapping of wave function density in a potential well created by the shape of a potential barrier. When particles (such as electrons or nuclei) interact with this potential, certain conditions can lead to an increased likelihood of scattering at specific energies. In a more detailed context, shape resonance happens when the incoming quantum particle has an energy that allows it to temporarily occupy a quasi-bound state.

Molecular vibration refers to the oscillatory motion of atoms within a molecule around their equilibrium positions. This phenomenon occurs because molecular bonds can be thought of as springs that can stretch and compress, allowing the atoms to move closer together or further apart. During vibration, different types of motions can occur, including: 1. **Stretching**: This can be further divided into: - **Symmetric stretching**: Both bonds are elongated or shortened simultaneously.

Molecular term symbols are a notation used in molecular spectroscopy and quantum chemistry to describe the electronic states of molecules. These symbols provide important information about the energy levels and symmetries of molecular states which are pivotal in understanding electronic transitions, bonding characteristics, and other physical properties of molecules. A molecular term symbol generally follows the notation of: \[ ^{2S+1}L_J \] where: - **S** is the total spin angular momentum quantum number.

Molecular electronic transition refers to a process in which a molecule absorbs or emits energy, resulting in a change in its electronic energy state. This typically occurs when electrons in certain molecular orbitals move from a lower energy state (such as a ground state) to a higher energy state (an excited state) or vice versa. These transitions are fundamental to understanding various phenomena in chemistry and physics, including spectroscopy, photochemistry, and the behavior of materials when exposed to light.

"Discoveries" by Guillaume Le Gentil is a comprehensive work that is often associated with his role as an astronomer and explorer in the 18th century. Le Gentil is best known for his observations of the transit of Venus, which he attempted to record from various locations around the world. His work contributed to improvements in the understanding of the solar system, particularly in determining the distance between the Earth and the Sun.

Multi-parametric surface plasmon resonance (MP-SPR) is an advanced technique used to study biomolecular interactions and physical properties at interfaces with high sensitivity and specificity. It is an extension of traditional surface plasmon resonance (SPR) technology, which measures changes in refractive index near metal surfaces caused by biomolecular binding events.

Motional narrowing is a phenomenon observed in nuclear magnetic resonance (NMR) and electron paramagnetic resonance (EPR) spectroscopy. It refers to the reduction in the linewidth of spectral peaks when the motion of the molecules or particles under investigation occurs at a rate that is fast compared to the interaction timescale associated with the magnetic environment.

Micro-spectrophotometry is an analytical technique used to measure the absorbance, transmittance, or reflectance of very small samples, often at the microscopic scale. This method utilizes the principles of UV-Vis (ultraviolet-visible) spectroscopy, allowing scientists to study the optical properties of materials or biological samples with minimal sample consumption.

Belevitch's theorem is a result in the field of control theory and systems engineering, particularly related to the study of linear time-invariant (LTI) systems. The theorem provides a characterization of linear systems in terms of their input-output behavior, specifically concerning the transfer function representation of these systems.

The McCumber relation, named after Eric McCumber, is an important concept in the field of quantum optics and quantum information. It describes the relationship between the noise and the signal in quantum systems, particularly in the context of the measurement process. The relation is often used in discussions of quantum measurements and the trade-offs between the information gained and the disturbance caused by the measurement.

Maxwell–Wagner–Sillars (MWS) polarization is a phenomenon that occurs in heterogeneous materials, particularly in dielectric materials, where different phases or components have distinct electrical properties. This type of polarization arises due to the accumulation of charges at interfaces between different materials, leading to the creation of polarization charges. The MWS effect is characterized by two main aspects: 1. **Heterogeneous Media**: The materials involved have different dielectric constants and conductivities.

Matrix isolation is a powerful experimental technique used in chemistry and physics to study reactive species, such as free radicals, small molecules, and unstable compounds, in a controlled environment. The fundamental idea behind matrix isolation is to trap these species at very low temperatures (typically in the range of 10 to 20 K) within an inert solid matrix, such as rare gas (like argon or neon) or other inert solids.

Belarusian biophysicists are scientists from Belarus who specialize in biophysics, a field that combines principles and methods from physics with biological systems. This interdisciplinary area of study focuses on understanding the physical principles underlying biological processes, including areas like molecular biology, genetics, and biochemistry. Research conducted by Belarusian biophysicists may involve studying the structures and functions of biomolecules, the mechanics of cells, or the interactions between biological systems and physical forces.

Littrow expansion, named after the Austrian physicist Heinrich Littrow, is a method used in optics and diffraction-grating theory. It specifically pertains to the analysis of light diffraction by a grating at a specific angle, known as the Littrow angle. In the context of a diffraction grating, the Littrow expansion occurs when the incoming light is focused so that the angle of incidence equals the angle of diffraction for one of the diffracted orders.