Nuclear magnetic resonance (NMR) is a physical phenomenon where a weak oscillating magnetic field perturb nuclei in a strong static magnetic field. These nuclei respond by producing an electromagnetic signal with a frequency characteristic of the nucleus’s magnetic field. Spectrometers that can specifically read Boron NMR ratings are needed in a number of industries. In fact, portable NMR machines are used in the field on construction projects and engineering endeavors.
Lead architects who design state of the art fire safe materials to be used in museums and cathedrals. In fact, there are museums across the world that rely on very specific kinds of engineering readings that a Boron NMR can provide. From mock coal mines in a museum that shows how coal burns and how are use of this fossil fuel affects the planet. Having a greater understanding of the important roles that they play in the world will help them determine the effect that they will have on the future.
NMR Spectrometers Can Help Improve Workflow Patterns
In our complicated and digital world it should come as no surprise that the employment of medical lab technologists and technicians is expected to grow by 13% by the year 2026. And in a time when drug discovery is a multi-billion dollar industry and chemists play an integral role in many points on the drug discovery roadmap, the use of technical instruments like Boron NMRs will always be needed. Consider these facts and figures about the technology that will help frame the future we will live:
- NMR is one of the top analytical methods, and in modern chemistry is one of the most useful.
- Richard Ernst first demonstrated Fourier transform nuclear magnetic resonance FT NMR in the year 1966, and this technology quickly replaced most prior techniques used for scanning.
- Hydrogen nuclei is the number one most studied nuclei.
- The first commercial spectrometers were created and quickly became a key tool for research chemists in the 1950s.
- The superconducting magnet had been largely adopted by chemists in the 1960s, even though the first commercial spectrometers were based on conventional electromagnets and permanent magnets.