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November 25th, 2020
Teledyne e2v part of UK Collaboration to Develop Quantum Technologies to Measure Atmosphere

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Teledyne e2v are collaborating with STFC RALSpace and University of Birmingham in the development of a cold atom quantum-technology based instrument in preparation for a future space mission to take sensitive measurements of atmospheric drag.

Chelmsford, UK, November 25, 2020Teledyne e2v’s Space & Quantum team, a part of the Teledyne Imaging Group, based in Essex in the UK are collaborating with STFC RALSpace and University of Birmingham in the development of the Cold Atom Space Payload (CASPA) Accelerometer.

The company was selected through the open competition for the 13th Earth Observation (EO) Technology Call, run by the Centre for Earth Observation Instrumentation (CEOI) on behalf of the UK Space Agency, for its submission of a proposal for a highly innovative space based instrument.

The CASPA Accelerometer project will develop a cold atom quantum instrument in an autonomous, low power, compact form factor, in preparation for a future space mission to take sensitive measurements of atmospheric drag.

The Earth’s upper atmosphere is a highly active region that plays a key role in the planet’s energy transfer, influencing climate and weather. Understanding the dynamics of the Earth’s upper atmosphere will rely on extremely sensitive measurement of the forces acting on a specially designed satellite as it passes through the rarefied atmosphere of Very Low Earth Orbit (VLEO).

The new accelerometers are based on an area of quantum technology that uses alkali atoms, which are cooled by lasers close to absolute zero, without the use of cryogenics. The sensors will enable a dramatic step forward in our understanding of upper atmospheric dynamics and drive advances in climate modelling, weather forecasting and satellite orbit prediction.

This project will build on Teledyne e2v’s previous work to build the Cold Atom Space Payload (CASPA) CubeSat, which demonstrated a cold atom trap and represents a major step toward using cold atoms for space applications.

This industrial and academic collaboration aligns strongly with the key objectives of the UK Space Agency EO technology strategy, and reinforces the UK’s position as a world leader in the provision of cold atom payloads and sensors for a new generation of Earth observation satellites.


Teledyne e2v is part of the Teledyne Imaging Group. Their innovations lead developments in healthcare, life sciences, space, transportation, defence and security and industrial markets. Teledyne e2v’s unique approach involves listening to the market and application challenges of customers and partnering with them to provide innovative standard, semi-custom or fully-custom imaging solutions, bringing increased value to their systems. For more information, visit https://www.teledyne-e2v.com

 

  • The open competition EO-13 was run by the Centre for Earth Observation Instrumentation (CEOI) on behalf of the UKSA.
  • The CEOI is a partnership of Airbus Ltd, QinetiQ Ltd, STFC Rutherford Appleton Laboratory and University of Leicester
  • CEOI was set up in April 2007 and is funded by the UK Space Agency to support UK industry and universities to develop new technologies for space, to collaborate, and to maintain its position as a world-leader in Earth Observation satellite technology
  • The CEOI recently updated the UK Earth Observation Technology Strategy on behalf of the UK Space Agency
  • This project will build on Teledyne e2v’s previous CASPA project which was funded by UKRI within the UK’s National Quantum Technology Programme (https://uknqt.epsrc.ac.uk/)

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