Reprint
Engineering Properties of Superconducting Materials
Edited by
June 2021
136 pages
- ISBN978-3-0365-0372-1 (Hardback)
- ISBN978-3-0365-0373-8 (PDF)
This book is a reprint of the Special Issue Engineering Properties of Superconducting Materials that was published in
Chemistry & Materials Science
Engineering
Physical Sciences
Summary
Plastic (and microplastic) pollution has been described as one of the greatest environmental challenges of our time, and a hallmark of the human-driven epoch known as the Anthropocene. It has gained the attention of the general public, governments, and environmental scientists worldwide. To date, the main focus has been on plastics in the marine environment, but interest in the presence and effects of plastics in freshwaters has increased in the recent years. The occurrence of plastics within inland lakes and rivers, as well as their biota, has been demonstrated. Experiments with freshwater organisms have started to explore the direct and indirect effects resulting from plastic exposure. There is a clear need for further research, and a dedicated space for its dissemination. This book is devoted to highlighting current research from around the world on the prevalence, fate, and effects of plastic in freshwater environments.
Format
- Hardback
License
© 2022 by the authors; CC BY-NC-ND license
Keywords
hybrid high voltage direct current transmission system; resistive-type superconducting fault current limiter; scheme design; short-circuit fault; Yttrium barium copper oxide materials; transient simulation; high pressure; diamond anvil cell; Raman spectroscopy; electrical conductivity; phase transition; pressure-induced metallization; iron-based superconductors; critical currents; flux pinning; microstructure; superconducting tape; quench; R-SFCL; AC and DC overcurrent; experiment; finite element method (FEM); numerical modeling; superconducting coil; alternating current (AC) losses; superconducting material law; inductive fault current limiter; magnetic flux shielding; multiphysics simulation; transient state; field-circuit coupling method; high-temperature superconducting bulk; modeling; magnetic levitation; electromagnetic-thermo-force coupling; high speed; HTS; bulk superconductors; coated conductors; mathematical modelling; H-formulation