A thin film sensing device operates based on a spin polarized current. The spin device includes ferromagnetic layers characterized by different coercivities and/or magnetization states, and one or more low transmission barriers in between. The device is further configured so that the spin polarized
A thin film sensing device operates based on a spin polarized current. The spin device includes ferromagnetic layers characterized by different coercivities and/or magnetization states, and one or more low transmission barriers in between. The device is further configured so that the spin polarized current flows at least in part in a direction perpendicular to the aforementioned layers.
대표청구항▼
What is claimed is: 1. A thin film spin-based device comprising: i) a first thin film ferromagnetic layer with a first changeable magnetization state responsive to a magnetic field coupled to the thin film spin-based device and characterized by a first coercivity; ii) a second thin film ferromagnet
What is claimed is: 1. A thin film spin-based device comprising: i) a first thin film ferromagnetic layer with a first changeable magnetization state responsive to a magnetic field coupled to the thin film spin-based device and characterized by a first coercivity; ii) a second thin film ferromagnetic layer with a second non-changeable magnetization state and characterized by a second coercivity which is substantially higher than said first coercivity; iii) a third thin film layer situated between said first thin film ferromagnetic layer and said second thin film ferromagnetic layer, said third thin film layer comprising a low transmission barrier material; wherein a spin polarized current flows in part in a path perpendicular to a magnetization plane of said first thin film ferromagnetic layer, to said third thin film layer, and to said second thin film ferromagnetic layer respectively; further wherein an impedance value of the device varies in accordance with a relationship between said first changeable magnetization state and said second non-changeable magnetization state. 2. The thin film spin based device of claim 1 wherein a spin transimpedance increases as said thin film spin-based device decreases in size. 3. The thin film spin based device of claim 1, wherein said thin film spin-based device is configured as a spin transistor. 4. The thin film spin based device of claim 1, wherein said third thin film layer is electrically grounded. 5. The thin film spin based device of claim 1, further including a separate low transmission barrier interface associated with said second thin film ferromagnetic layer. 6. The thin film spin based device of claim 1, further including a fourth layer located in said thin film stack which is adapted to promote isotropic flow for a spin based current. 7. The thin film spin based device of claim 1, wherein said low transmission barrier material is located at an interface to said first thin film ferromagnetic layer. 8. The thin film spin based device of claim 1, wherein said low transmission barrier material is located at an interface to said second thin film ferromagnetic layer. 9. The thin film spin based device of claim 1, wherein said low transmission barrier material is located at a boundary to said third thin film layer which includes a conductive paramagnetic material. 10. The spin-based device of claim 1, wherein a coupling parameter α=H/I corresponding to an applied magnetic field strength (H) and current amplitude (I) ratio is configured to be between 5 and 20. 11. The thin film spin based device of claim 1 wherein said first changeable magnetization state can be switched between a first state and a second state using a magnetic field of less than approximately 10 oersteds. 12. The thin film spin-based device of claim 1, wherein said first thin film ferromagnetic layer has a first relatively easy axis of magnetization and a second substantially harder axis of magnetization. 13. The thin film spin-based device of claim 12, wherein said magnetic field is applied to change said first changeable magnetization state along said first axis of magnetization. 14. The thin film spin-based device of claim 13, wherein said magnetic field is applied to an edge region of said first ferromagnetic layer to change said first changeable magnetization state along said first axis of magnetization. 15. The thin film spin-based device of claim 12, wherein an output current associated with the device generates an output magnetic field along said harder axis of magnetization. 16. The thin film spin-based device of claim 15, wherein said output magnetic field is larger than said magnetic field applied to said first axis of magnetization. 17. The thin film spin-based device of claim 1, wherein an output current associated with the device is output along a first axis which is substantially perpendicular to a second axis associated with an input current for said magnetic field coupled to the thin film spin-based device. 18. The thin film spin-based device of claim 12, wherein a ratio of coercivity between said first axis of magnetization and said second harder axis of magnetization is less than 1/10. 19. The thin film spin-based device of claim 12, wherein an antiferromagnetic layer is coupled to said first thin film ferromagnetic layer to induce an anisotropy for said first axis of magnetization and said second harder axis of magnetization. 20. The thin film spin based device of claim 1, wherein said spin based current flows through at most a single pair of ferromagnetic layers including said first ferromagnetic layer and said second ferromagnetic layer. 21. The thin film spin-based device of claim 1, wherein such device is coupled to a second thin film spin-based device which is adapted to have at least one of a different coercivity, different switching field and/or different inductive coupling parameter from the thin film spin-based device. 22. The thin film spin-based device of claim 21, wherein an input of said second thin film spin-base device is inductively coupled to an output of the thin film spin-based device, and the thin film spin-based device is adapted such that an output signal from the thin film spin-based device has a larger amplitude than an input signal to such device. 23. The thin film spin-based device of claim 1, wherein said thin film spin-base device carries at least a portion of a write pulse associated with a switching field applied to the device. 24. The thin film spin-based device of claim 1, wherein said thin film spin-base device is part of a memory circuit and/or logic circuit. 25. The thin film spin-based device of claim 1, wherein said thin film spin-base device is part of a dynamically programmable gate. 26. A thin film spin polarized electron current device comprising: a first conductive layer separated from a separate second conductive layer; a first thin film ferromagnetic structure characterized by a first coercivity, and electrically coupled to said first conductive layer; wherein said first thin film ferromagnetic structure is configured to have a fixed magnetization state; a second thin film ferromagnetic structure characterized by a second coercivity substantially smaller than said first coercivity, and electrically coupled to said second conductive layer; wherein only said second thin film ferromagnetic structure has a changeable magnetization state responsive to an external magnetic field; a base layer between said first thin film ferromagnetic structure and said second thin film ferromagnetic structure, which base layer includes a material having equilibrium energy levels for electron spins which are substantially the same; wherein said base layer includes a first low transmission barrier at an interface to said first thin film ferromagnetic structure, and a second low transmission barrier at an interface to said second thin film ferromagnetic structure; wherein a spin polarized current flows in part in a path perpendicular to a magnetization plane of said second thin film ferromagnetic structure and said first thin film ferromagnetic structure; further wherein a value of said spin polarized current can be measured to determine a relationship between said changeable magnetization state and said second non-changeable magnetization state. 27. The thin film spin based device of claim 26 wherein said first thin film ferromagnetic structure includes one or more thin film layers, at least one of which includes permalloy, cobalt, iron and/or FeCo. 28. The thin film spin based device of claim 26 wherein said second thin film ferromagnetic structure includes one or more thin film layers, at least one of which includes permalloy, cobalt, iron and/or FeCo. 29. The thin film spin based device of claim 28, wherein said first thin film ferromagnetic structure includes an antiferromagnetic pinning layer. 30. The thin film spin based device of claim 26, further including a separate low transmission barrier interface associated with one of at least said second thin film ferromagnetic structure and/or said first thin film ferromagnetic structure. 31. The thin film spin based device of claim 26, wherein said device is situated on a silicon substrate. 32. The thin film spin based device of claim 26, further including a base layer interposed between said first ferromagnetic structure and said second ferromagnetic structure. 33. The thin film spin based device of claim 26, wherein said spin based current flows through at most a single pair of ferromagnetic structures including said first ferromagnetic structure and said second ferromagnetic structure. 34. The spin-based device of claim 26, wherein a coupling parameter α=H/I corresponding to a magnetic field strength (H) and current amplitude (I) ratio is configured to be between 5 and 20. 35. The thin film spin based device of claim 26 wherein said first changeable magnetization state can be switched between a first state and a second state using a magnetic field of less than 10 oersteds. 36. The thin film spin-based device of claim 26, further including a layer adapted to promote isotropic current flow. 37. The thin film spin-based device of claim 26, wherein such device is coupled to a second thin film spin-based device which is adapted to have at least one of a different coercivity, different switching field and/or different inductive coupling parameter from the thin film spin-based device. 38. The thin film spin-based device of claim 37, wherein an input of said second thin film spin-base device is inductively coupled to an output of the thin film spin-based device, and the thin film spin-based device is adapted such that an output signal from the thin film spin-based device has a larger amplitude than an input signal to such device. 39. The thin film spin-based device of claim 26, wherein said thin film spin-base device carries a portion of a write pulse associated with a switching field applied to the device. 40. The thin film spin-based device of claim 26, wherein said thin film spin-base device is part of a memory circuit and/or logic circuit. 41. The thin film spin-based device of claim 26, wherein said thin film spin-base device is part of a dynamically programmable gate. 42. A thin film electron spin-based sensing device comprising: i) a first thin film ferromagnetic layer with a changeable magnetization state comprising permalloy and/or cobalt; ii) a second thin film ferromagnetic layer with a non-changeable magnetization state also comprising permalloy and/or cobalt; iii) at least one third thin film layer situated between said first thin film ferromagnetic layer and said second thin film ferromagnetic layer, said at least one third thin film layer comprising a material with equilibrium levels which are substantially equal for two different electron spins present in a spin polarized current, said at least one third thin film layer including a low transmission barrier interface to said first thin film ferromagnetic layer and/or said second thin film ferromagnetic layer; wherein said spin polarized current flows at least in part perpendicular to first and second thin film ferromagnetic layers and varies in accordance with a relationship between said changeable magnetization state and said non-changeable magnetization state. 43. The thin film electron spin-based sensing device of claim 42, further wherein said low transmission barrier interface is configured to effectuate an impedance which is larger than a transimpedance of the thin film electron spin-based device. 44. The thin film electron spin-based sensing device of claim 42, wherein said first thin film ferromagnetic layer has a first coercivity substantially smaller than a second coercivity of said second thin film ferromagnetic layer. 45. The thin film electron spin-based sensing device of claim 42, wherein said third thin film layer is a conductive paramagnetic material. 46. The thin film electron spin-based sensing device of claim 45, wherein said third thin film layer is copper. 47. The spin-based device of claim 42, wherein a coupling parameter α=H/I corresponding to a magnetic field strength (H) and current amplitude (I) ratio is configured to be between 5 and 20. 48. The thin film spin based device of claim 42 wherein said first changeable magnetization state can be switched between a first state and a second state using a magnetic field of less than 10 oersteds. 49. The thin film spin-based device of claim 42, further including a layer adapted to promote isotropic current flow. 50. The thin film spin-based device of claim 42, wherein such device is coupled to a second thin film spin-based device which is adapted to have at least one of a different coercivity, different switching field and/or different inductive coupling parameter from the thin film spin-based device. 51. The thin film spin-based device of claim 50, wherein an input of said second thin film spin-base device is inductively coupled to an output of the thin film spin-based device, and the thin film spin-based device is adapted such that an output signal from the thin film spin-based device has a larger amplitude than an input signal to such device. 52. The thin film spin-based device of claim 42, wherein said thin film spin-base device carries a portion of a write pulse associated with a switching field applied to the device. 53. The thin film spin-based device of claim 42, wherein said thin film spin-base device is part of a memory circuit and/or logic circuit. 54. The thin film spin-based device of claim 42, wherein said thin film spin-base device is part of a dynamically programmable gate.
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