Claims
- 1. A magnetic force sensor for detecting a magnetic force of a magnetic sample having a given magnetization direction, the magnetic force sensor comprising: a magnetic probe having a tip portion, the tip portion having an electrolytically plated film of hard-magnetic material effective to maintain the magnetization direction of the probe constant and parallel to the given magnetization direction of the sample; and means for resiliently biasing the magnetic probe with respect to the magnetic sample in response to the magnetic force between the magnetic probe and the magnetic sample, the means for resiliently biasing comprising a leaf spring fixedly supporting the magnetic probe.
- 2. A magnetic force sensor as claimed in claim 1; wherein the electrolytically plated film of hard-magnetic material comprises an alloy of iron and cobalt.
- 3. A magnetic force sensor as claimed in claim 2; wherein the magnetic probe and the means for biasing art comprised of silicon.
- 4. A magnetic force sensor as claimed in claim 2; wherein the means for biasing is comprised of stainless steel and the magnetic probe comprises a tungsten needle probe.
- 5. A magnetic force sensor as claimed in claim 1, wherein the electrolytically plated film of hard-magnetic material comprises an alloy of cobalt and nickel.
- 6. A magnetic force sensor as claimed in claim 5; wherein the means for biasing is comprised of stainless steel and the magnetic probe comprises a tungsten needle probe.
- 7. A magnetic force sensor as claimed in claim 5; wherein the magnetic probe and the means for biasing are comprised of silicon.
- 8. A force sensor for magnetic force microscopy for detecting a magnetic force of a magnetic sample having a given magnetization direction, the force sensor comprising: a magnetic probe for scanning a surface of the sample, the magnetic probe having an electrolytically plated hard-magnetic thin film having a magnetization direction which is maintained constant and parallel to the given magnetization direction of the magnetic sample during scanning of the magnetic probe relative to the surface of the magnetic sample; and a leaf spring having the magnetic probe attached thereto at a free end thereof, the leaf spring being resiliently deflectable in response to the magnetic force between the magnetic probe and the magnetic sample.
- 9. A force sensor as claimed in claim 8; wherein the electrolytically plated hard-magnetic thin film is comprised of an iron/cobalt alloy.
- 10. A force sensor as claimed in claim 9; wherein the leaf spring and magnetic probe are comprised of silicon.
- 11. A force sensor as claimed in claim 9; wherein the leaf spring is comprised of stainless steel and the magnetic probe comprises a tungsten needle probe.
- 12. A force sensor as claimed in claim 8; wherein the leaf spring is comprised of stainless steel, the magnetic probe comprises a tungsten needle probe and the electrolytically plated hard-magnetic thin film is comprised of a cobalt/nickel alloy.
- 13. A force sensor as claimed in claim 8; wherein the leaf spring and magnetic probe are comprised of silicon and the electrolytically plated hard-magnetic thin film is comprised of a cobalt/nickel alloy.
- 14. A magnetic force sensor as claimed in claim 8; wherein the magnetic force sensor comprises a cantilever member.
- 15. A method of manufacturing a magnetic force sensor for detecting a magnetic force of a magnetic sample having a given magnetization direction, comprising the steps of: providing a magnetic probe having a tip portion; forming a film of hard-magnetic material on the tip portion of the magnetic probe by electrolytic plating effective to maintain the magnetization direction of the magnetic probe constant and parallel to the given magnetization direction of the sample; and supporting the magnetic probe with a biasing member comprised of a leaf spring so that the magnetic probe is resiliently biased with respect to the magnetic sample in response to the magnetic force between the magnetic probe and the magnetic sample.
- 16. A method according to claim 15; wherein the forming step comprises forming a film of an alloy of iron and cobalt on the tip portion of the magnetic probe by electrolytic plating.
- 17. A magnetic force sensor for detecting a magnetic force of a magnetic sample having a given magnetization direction, the magnetic force sensor comprising: a cantilever member having a free end; and a magnetic probe fixed to the free end of the cantilever member and having a tip portion, the tip portion having an electrolytically plated film of hard-magnetic material effective to maintain the magnetization direction of the probe constant and parallel to the given magnetization direction of the sample.
Priority Claims (1)
Number |
Date |
Country |
Kind |
5-40318 |
Mar 1993 |
JP |
|
Parent Case Info
This application is a continuation of Ser. No. 08/200,820, filed Feb. 23, 1994, now U.S. Pat. No. 6,081,113.
US Referenced Citations (6)
Number |
Name |
Date |
Kind |
5043578 |
Guethner et al. |
Aug 1991 |
A |
5103174 |
Wandass et al. |
Apr 1992 |
A |
5171992 |
Clabes et al. |
Dec 1992 |
A |
5218262 |
Taguchi et al. |
Jun 1993 |
A |
5298760 |
Fuchs et al. |
Mar 1994 |
A |
5375087 |
Moreland et al. |
Dec 1994 |
A |
Non-Patent Literature Citations (1)
Entry |
Grutter et al., “Batched Fabricated Sensors for Magnetic Force Microscopy”, Oct., 1990, American Institute of Physics, pp. 1820-1822. |
Continuations (1)
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Number |
Date |
Country |
Parent |
08/200820 |
Feb 1994 |
US |
Child |
09/559376 |
|
US |