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- Neutron transport - Wikipedia
Neutron transport (also known as neutronics) is the study of the motions and interactions of neutrons with materials Nuclear scientists and engineers often need to know where neutrons are in an apparatus, in what direction they are going, and how quickly they are moving
- Neutronics - an overview | ScienceDirect Topics
Neutronics is also commonly denoted as reactor physics, though reactor physics commonly encompasses multiphysics as it has been the case of LWR core analysis for several decades
- Neutronics Solutions – Faster To Market
Our strengths are centered around servicing the solid-state lighting, display, industrial control, automotive, wireless, telecom, consumer, and video broadcast markets Through the partnerships with our Suppliers, our goal is to compress the time-to-revenue timeline for our customers
- Reactor Neutronics | ORNL
ORNL has a long history of reactor analysis using multigroup and continuous-energy physics with deterministic and Monte Carlo methods
- Neutronics of Advanced Nuclear Systems | SpringerLink
This book provides a systematic and comprehensive introduction to the neutronics of advanced nuclear systems, covering all key aspects, from the fundamental theories and methodologies to a wide range of advanced nuclear system designs and experiments
- English Portal - Neutronics
Neutronics (or neutron physics) is the study of neutron paths through matter, of conditions for a chain reaction, and of alterations in matter's composition induced by nuclear reactions It makes it possible to design and operate nuclear reactors and fuel cycle facilities
- Neutronics in fusion devices - Princeton Plasma Physics Laboratory
In 1935, during his research tenure at the legendary Cavendish Laboratory, the Australian physicist Mark Oliphant achieved the first fusion reactions on Earth Nuclear reactions produce or consume energy because some nuclear mass is lost or gained during the reaction
- Neutronics Calculation Advances at Los Alamos: Manhattan Project to . . .
We briefly summarize early simpler and more approximate neutronics methods and then describe the need to better predict neutronics behavior through consideration of theoretical equations, models and algorithms, experimental measurements, and available computing capabilities and their limitations
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