Nuclear Magnetic Resonance (Nmr)

Nuclear Magnetic Resonance (Nmr) - absorption and transmission of high-frequency radio radiation by the nuclei of molecules when they are placed in a strong magnetic field. This effect is especially evident in places where hydrogen nuclei are most concentrated inside each molecule, which is used in the analysis of various biological materials. This effect is widely used in non-invasive diagnostic examination methods (see Nuclear magnetic resonance. Magnetic resonance spectroscopy).

Nuclear Magnetic Resonance is a physical effect that involves the absorption and transmission of high-frequency radio radiation by the nuclei of molecules when they are placed in a strong magnetic field. This method is widely used in medicine to diagnose and treat diseases.

Nuclear magnetic resonance can be used to analyze various biological materials, such as blood, urine, cerebrospinal fluid and others. It is based on the fact that the hydrogen nuclei inside each molecule absorb and emit radio waves at a certain frequency. This allows scientists to determine the structure of molecules and identify various diseases.

One of the main applications of nuclear magnetic resonance is magnetic resonance spectroscopy. It allows you to obtain information about the molecular structure of substances and determine the presence of various compounds in the tissues of the body. This is important for diagnosing various diseases such as tumors, infections and other pathologies.

In addition, nuclear magnetic resonance is used in other fields of science and technology, such as chemistry, physics, biology and materials science. It is one of the most accurate methods for studying the structure and properties of molecules.

Thus, nuclear magnetic resonance is an important tool for the study of biological materials and has wide application in medicine and other sciences.

Nuclear Magnetic Resonance: Modern Application “NMR Resonance” (nuclear magnetic resonance) is the effect of absorption and transmission of high-frequency radio waves by the nuclei of moving molecules under the influence of an external magnetic field. An increase in the strength of the magnetic field leads to an increase in the frequency of vibrations of nuclear spins, which causes the phenomenon of NMR. This makes it possible to determine the composition and structure of molecules, as well as to quantify their concentration in the sample under study.

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