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Home > Press > Oxford Instruments and Dresden High Magnetic Field Laboratory collaborate to develop HTS magnet technology components for high field superconducting magnet systems

Abstract:
Oxford Instruments, a leading provider of high technology tools and systems for industry and research, has entered into a collaboration agreement with the High Field Laboratory (HLD) at Helmholtz-Zentrum Dresden-Rossendorf e.V. (HZDR), Germany, to develop high temperature superconducting (HTS) insert coils for high field magnet systems greater than 25 Tesla.

Oxford Instruments and Dresden High Magnetic Field Laboratory collaborate to develop HTS magnet technology components for high field superconducting magnet systems

Abingdon, UK | Posted on June 29th, 2016

The collaboration brings these two leading players in high field magnets together. HLD is a member of the European Magnetic Field Laboratory (EMFL) and one of the world-leading high field user facilities; Oxford Instruments is a world leader in the design and supply of both superconducting materials, and high magnetic field and cryogenic environments. The collaboration will cover the design, engineering and testing of HTS test coils using the Bi-2212 HTS round wire supplied by Oxford Superconducting Technology (OST, Carteret, NJ, USA). The Bi-2212 test coils will be integrated into the HLD 19 Tesla large bore magnet with a large magnet bore of 150 mm. This 19 T, 150 mm magnet, operating at 4.2 K, using low temperature superconducting (LTS) materials only, was specifically developed and commissioned by Oxford Instruments in February 2015 to accommodate HTS insert coils targeting high magnet fields of over 25 Tesla, in addition to a wide range of sample configurations for a variety of experiments.

Uniquely, this agreement will allow Oxford Instruments and the High Field Laboratory at Dresden to develop the Bi-2212 HTS technology components required to enable the next generation of research tools needed to probe matter at high fields, and to facilitate materials research and discovery of new materials using all-superconducting magnets. A high field in an all-superconducting magnet will be a major step forward in the high field user capability at international user facilities for experiments in high magnetic fields. Realising these new magnets will remove the infrastructure requirements and costs associated with the typical resistive magnets used to generate magnetic fields greater than 25 Tesla today.

“This project will essentially contribute to the development of a new class of high field magnets of great capability for the international science community. All-superconducting magnets for the field range 25 Tesla and beyond will allow for intensifying research on complex matter and stimulate exciting developments in solid-state physics and related disciplines”, said Prof. Joachim Wosnitza, Director of the HLD.

“We are excited about this alliance between the two organisations working together to develop the next generation of high field magnets, essential for new discoveries in materials and nanotechnology applications”, commented Dr Ziad Melhem, Alliances Manager at Oxford Instruments’ NanoScience division. “This further confirms Oxford Instruments’ commitment to develop state-of-the-art high field superconducting magnet and cryogenic environments, which will benefit researchers in physical as well as life sciences for years to come.”

Dr Yibing Huang, HTS Program Manager at Oxford Superconducting Technology (OST) mentioned, “Bi-2212 wire is a high temperature superconductor which has unique characteristics that allow it to be made into a round conductor, along with many other advantages for ultra-high field magnet application. The conductor performance has advanced significantly in recent years through the strong collaboration among US national laboratories and industry. It is very satisfying to see this transition from demonstration material to device application.”



Issued for and on behalf of Oxford Instruments NanoScience

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About Oxford Instruments NanoScience
Oxford Instruments NanoScience designs, supplies and supports market-leading research tools that enable quantum technologies, new materials and device development in the physical sciences. Our tools support research down to the atomic scale through creation of high performance, cryogen-free low temperature and magnetic environments, based upon our core technologies in low and ultra-low temperatures, high magnetic fields and system integration, with ever-increasing levels of experimental and measurement readiness. Oxford Instruments NanoScience is a part of the Oxford Instruments plc group.





About Oxford Superconducting Technology
For nearly half a century, Oxford Instruments Superconducting Technology has been designing, developing and producing innovative conductors to meet the requirements of a sophisticated base of scientific and commercial customers. Our products are at the very heart of a majority of the superconducting magnets worldwide, and continue to be the first choice for quality and performance.


About Oxford Instruments plc
Oxford Instruments designs, supplies and supports high-technology tools and systems with a focus on research and industrial applications. Innovation has been the driving force behind Oxford Instruments' growth and success for over 50 years, and its strategy is to effect the successful commercialisation of these ideas by bringing them to market in a timely and customer-focused fashion.



The first technology business to be spun out from Oxford University, Oxford Instruments is now a global company and is listed on the London Stock Exchange (OXIG). Its objective is to be the leading provider of new generation tools and systems for the research and industrial sectors with a focus on nanotechnology. Its key market sectors include nano-fabrication and nano-materials. The company’s strategy is to expand the business into the life sciences arena, where nanotechnology and biotechnology intersect



This involves the combination of core technologies in areas such as low temperature, high magnetic field and ultra high vacuum environments; Nuclear Magnetic Resonance; X-ray, electron, laser and optical based metrology; atomic force microscopy; optical imaging; advanced growth, deposition and etching.



Oxford Instruments aims to pursue responsible development and deeper understanding of our world through science and technology. Its products, expertise, and ideas address global issues such as energy, environment, security and health.

About Helmholtz-Zentrum Dresden-Rossendorf
The Helmholtz-Zentrum Dresden-Rossendorf (HZDR) conducts research in the sectors energy, health, and matter. It focuses its research on the following topics:
· How can energy and resources be used efficiently, safely, and sustainably?

· How can malignant tumors be visualized and characterized more precisely and treated effectively?

· How do matter and materials behave in strong fields and in the smallest dimensions?

The HZDR has been a member of the Helmholtz Association, Germany’s largest research organization, since 2011. It has four locations (Dresden, Leipzig, Freiberg, and Grenoble) and employs about 1,100 people – approximately 500 of whom are scientists, including 150 doctoral candidates.

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Contacts:
Soma Deshprabhu
Marketing Communications Manager
Oxford Instruments NanoScience

Copyright © Oxford Instruments NanoScience

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