It would be used in any branch of engineering involving the analysis of chemicals, such as chemical engineering, petroleum engineering etc.
It could also be used to indentify various lubricants or fuels used by engineers, but it's mostly an analytical chemist would carry out the tests.
Yes, an MRI (Magnetic Resonance Imaging) machine is considered an invention. It was developed in the 1970s by physicist Raymond Damadian, along with contributions from other scientists, and it revolutionized medical imaging by providing detailed images of organs and tissues without the use of ionizing radiation. The technology relies on the principles of nuclear magnetic resonance, which were adapted for medical use. As a result, MRI has become an essential tool in diagnosing and monitoring various medical conditions.
design engineering
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nuclear engineer
The main difference is specilization. I am a chemical engineer myself, and we have the option of specializing in a wide variety of degrees, such as genetic engineering. Note that chemical engineering is a very broad field dealing with polymers, metallurgy, biology, environmental chemistry, and the list goes on. Genetic engineering, in short, is really a specialization of chemical engineering to specifically biological chemistry.
J. Valk has written: 'Basic principles of nuclear magnetic resonance imaging' -- subject(s): Diagnostic use, Magnetic resonance imaging, Nuclear magnetic resonance
In the context of nuclear magnetic resonance imaging (NMRI), resonance refers to the absorption of radiofrequency energy by atomic nuclei in a magnetic field. When the applied radiofrequency matches the resonant frequency of the atomic nuclei, it causes them to resonate and emit signals that can be detected and used to create images of the internal structures of the body.
Gordon Keith Hamer has written: 'Substituent effects in nuclear magnetic resonance spectroscopy' -- subject(s): Nuclear magnetic resonance spectroscopy
No, a nuclear reactor produces thermal energy and ionising radiation, no magnetic effects.
Kistasamy Sathianandh Naidoo has written: 'Nuclear magnetic resonance and relaxation in solid and liquid lanthanum' -- subject(s): Nuclear magnetic resonance, Lanthanum
D W. Mathieson has written: 'Nuclear magnetic resonance for organic chemistry' 'Nuclear magnetic resonance for organic chemists' 'Interpretation of organic spectra'
Nuclear Magnetic Resonance is often used in the Radiology modality of MRI, which stands for Magnetic Resonance Imaging. Nuclear Magnetic Resonance is an alternative to radiation producing techniques such as the traditional Anode/Cathode X-ray tube. NMR is used to help to visualize patient anatomy and pathology without delivering the harmful effects of ionizing radiation used in other modalities.
Brian Harold Barber has written: 'A nuclear magnetic resonance study of the protein concanavalin A' -- subject(s): Nuclear magnetic resonance, Concanavalin A, Molecular biology
D. I Hoult has written: 'An overview of NMR in medicine' -- subject- s -: Magnetic resonance imaging, Nuclear magnetic resonance
Jozef Jaklovsky has written: 'Preparation of nuclear targets' -- subject(s): Bibliography, Targets (Nuclear physics) 'NMR imaging' -- subject(s): Bibliography, Diagnosis, Magnetic resonance imaging, Nuclear magnetic resonance, Nuclear medicine
Earl P. Steinberg has written: 'Nuclear magnetic resonance imaging technology' -- subject(s): Diagnostic use, Government policy, Imaging systems in medicine, Magnetic resonance imaging, Medical imaging equipment industry, Nuclear magnetic resonance spectroscopy
Else Rubaek Danielsen has written: 'Magnetic resonance spectroscopy diagnosis of neurological diseases' -- subject(s): Brain, Brain Diseases, Brain chemistry, Diagnosis, Diagnostic use, Diseases, Nuclear magnetic resonance, Nuclear magnetic resonance spectroscopy, Pathology