Magnetometer Based On Spin Wave Interferometer

Background Magnetometers are among the most widely used instruments for a variety of applications. Sensitivity, intrinsic noise, size, energy budget and cost are the important characteristics of magnetometers. A variety of magnetic sensors, in curren…

Background

Magnetometers are among the most widely used instruments for a variety of applications. Sensitivity, intrinsic noise, size, energy budget, and cost are the important characteristics of magnetometers. A variety of magnetic sensors, in currently available magnetometers, are available based on their unique advantages and the intended application. Some of the highly sensitive magnetometers are plagued by high costs and require cryogenic temperatures for operation. The cheaper magnetometers are also less sensitive. These challenges continue to hinder the practical application of magnetometers for a wide variety of uses.

Current Invention

Prof. Aleksandr Khitun has developed a patent-pending, novel magnetometer based on a spin-wave interferometer. The sensing element for this instrument consists of a magnetic cross junction with four micro-antennas fabricated at the edges. Two of these antennas are used for spin-wave excitation and the other two are used for the detection of the inductive voltages generated by the interference of the spin waves. The output voltage attains its maximum or minimum depending on if the spin waves are coming in phase (constructive interference) or out of phase (destructive interference), respectively. The maximum sensitivity is during destructive interference.

Schematics of the sensing element

Schematics of the sensing element – a spin-wave interferometer built on a magnetic cross junction.

Website

https://techtransfer.universityofcalifornia.edu/NCD/32668.html?utm_source=AUTMGTP&utm_medium=webpage&utm_term=ncdid_32668&utm_campaign=TechWebsites

Advantages

The significance and benefits of this innovation are:

  • High sensitivity – 10-16 T/Ö Hz
  • Small size – prototype is 3mm X 3mm X 0.1mm with the potential to go to nanometer scale.
  • High operational frequency – 1GHz – 10GHz
  • Simplicity and low cost
  • Compatible with common electronic devices including smartphones
  • Room temperature operation

Potential Applications

  • Tracking distant objects such as submarines (1 – 10 km)
  • Tracking small objects such as weapons (at 50 m)
  • Detecting electromagnetic impulses in the brain
  • Gas pipeline monitoring.
  • Space telescopes

Contact Information

  • Name: Venkata Krishnamurty
  • Title :
  • Department :
  • Email: venkata.krishnamurty@ucr.edu
  • Phone :
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