1 / 18

Memory Storage in Near Space Environment

Memory Storage in Near Space Environment. Collin Jones University of Montana Department of Physics and Astronomy. UM BOREALIS. Experimental Payload. We suspended an experimental payload containing UV detection, particle capture, and the cosmic radiation test (MRAM).

gad
Download Presentation

Memory Storage in Near Space Environment

An Image/Link below is provided (as is) to download presentation Download Policy: Content on the Website is provided to you AS IS for your information and personal use and may not be sold / licensed / shared on other websites without getting consent from its author. Content is provided to you AS IS for your information and personal use only. Download presentation by click this link. While downloading, if for some reason you are not able to download a presentation, the publisher may have deleted the file from their server. During download, if you can't get a presentation, the file might be deleted by the publisher.

E N D

Presentation Transcript

  1. Memory Storage in Near Space Environment Collin Jones University of Montana Department of Physics and Astronomy

  2. UM BOREALIS Experimental Payload • We suspended an experimental payload containing UV detection, particle capture, and the cosmic radiation test (MRAM).

  3. Significance of Memory Storage • Not always an option to have real time data therefore criteria for memory storage: • Efficiency • Energy • Temperature • Radiation Effects Options: • Flash memory – commercially available • What Else?

  4. Future Option • What is MRAM? • Does it meet our criteria? • Physical Phenomena • Ferromagnetism • Magnetoresistance • How does MRAM work? • Our Experimental Findings

  5. What is MRAM? Magnetoresistive Random Access Memory stores information as an orientation of magnetic polarity, not as an electric charge www.ece.nus.edu Toggle MRAM structure

  6. Does MRAM meet out criteria? • Nonvolatile • If the device is switched off, memory is preserved • Instant-ON technology • Energy Savings • Potential in aerospace applications • Radiation Hard (Our experiment) • Endurance as a memory storage device (~1015 write cycles)

  7. Physical Phenomena Governing MRAM

  8. Ferromagnetism • Matter contains positive and negative charges which in general are in equal numbers. • In addition to charge electrons also have an inherent property called spin, either up or down. • In general most matter has equal numbers of spin up and spin down electrons which cancel any effect. • Ferromagnets are materials where there is a net spin. This tendency of electron spins to align with one another is due to the quantum mechanical exchange interaction.

  9. Magnetoresistance This is the observable change in electrical resistivity when a magnetic field is present. Two of the most useful types of magnetoresistance are; • Giant Magnetoresistance • Tunneling Magnetoresistance

  10. Giant Magnetoresistance (GMR) GMR can occur between two adjacent ferromagnetic layers separated by a spacer. • Electrons with their spins aligned with the ferromagnetic moment are less likely to scatter which leads to lower resistance. • High resistivity = antiparallel alignment • Low resistivity = parallel alignment

  11. GMR – Spin Valve • A spin valve structure is one with a ferromagnetic-nonmagnetic-ferromagnetic layering scheme such as the one below. 60%Co-40%Fe 80%Ni-20%Fe • We can control the layers orientation by using external magnetic fields. • We can detect which orientation the layers are in by measuring the resistance. • The 2007 Nobel Prize in Physics was awarded to Albert Fert and Peter Grunberg for their discovery of the GMR effect.

  12. Tunnel Magnetoresistance (TMR) • TMR is analogous to GMR • Parallel small resistivity large tunneling probability • Anti-parrallel large resistivity small tunneling probability Courtesy of: physicsworld.com

  13. How MRAM Works Writing and Reading Courtesy of: www.ece.nus.edu.sg/isml * The bottom layer is fixed.

  14. Writing and Reading (Cont’d) • To write to a given bit, current passes through the word line an then the bit lines • Reading is determined by the resistivity of the individual MTJs

  15. Our Experimental Findings • A sample of collected Geiger Data is displayed above Our experiment indicates that the radiation dose during our three hour flight was insufficient to corrupt the data in either of the chips, MRAM or flash memory.

  16. Wrap-up • MRAM remained unaffected by radiation dosagefrom cosmic rays. • Pros • Nonvolatile • Endurance • Radiation Hard • Cons • Scaling Issues for large storage (16 Mb) • Cost of Production

  17. Conclusion • We have found both MRAM and Flash are viable technologies for short term high altitude flight applications. • MRAM is potentially advantageous in applications: • With a larger radiation dose • Where immediate memory retrieval is necessary • Where energy efficiency is critical e.g. short term high altitude balloon flights.

  18. Literature and Sources • Physics of Ferromagnetism by SoshinChikazumi • Journal of Research and Development, Jan. 2006, IBM Special Thanks to Dr. Schneider and Jen Fowler

More Related