Self-referenced multibit MRAM cell having a synthetic antiferromagnetic storage layer

What is claimed is: 1. A multibit MRAM cell comprising a magnetic tunnel junction including a sense layer having a freely orientable sense magnetization; a tunnel barrier layer between the sense layer and a storage layer; the storage layer comprising a first storage layer having a first storage magnetization, a second storage layer having a second storage magnetization and a storage coupling layer between the first and second storage layers; the first storage magnetization being pinned by an antiferromagnetic layer at a low threshold temperature of the magnetic tunnel junction and unpinned at a high threshold temperature of the magnetic tunnel junction; the sense magnetization being arranged for inducing a dipolar field having a magnitude above a spin-flop field of the storage layer capable of aligning the second storage magnetization when the magnetic tunnel junction is at the high threshold temperature such that each of the first and second storage magnetization is oriented with a spin-flop angle θ SF to the direction of the dipolar field; the MRAM cell further comprising aligning means for aligning the sense magnetization in a plurality of distinct orientations in the range of 0° to 360°, wherein the first and second storage magnetizations move to maintain their orientation of spin-flop angle θ SF to the direction of the dipolar field, during said aligning, such that the first and second storage magnetization can be aligned in said plurality of distinct orientations in the dipolar field, in accordance with the direction of the sense magnetization, when the magnetic tunnel junction is at the high threshold temperature. 2. The multibit MRAM cell according to claim 1 , wherein the sense layer and the first and second storage layer has a thickness below 10 nm; and the magnetic tunnel junction 2 has a lateral dimension, perpendicular to said thickness, below 200 nm. 3. The multibit MRAM cell according to claim 2 , wherein the sense layer has a thickness between 1 nm and 10 nm. 4. The multibit MRAM cell according to claim 2 , wherein the first and second storage layer has a thickness between 1 nm and 10 nm; or between 0.1 nm and 5 nm, or preferably between 0.5 nm and 4 nm. 5. The multibit MRAM cell according to claim 2 , wherein the magnetic tunnel junction has a lateral dimension, perpendicular to said thickness, between 10 nm and 200 nm, or preferably between 40 nm and 100 nm. 6. The multibit MRAM cell according to claim 1 , wherein the first and second storage layers are such that a local stray field induced by the first storage layer is substantially equal to the one induced by the second storage layer. 7. The multibit MRAM cell according to claim 1 , wherein said aligning means comprises a write magnetic field being orientable in m distinct orientations in the range of 0° to 360° and configured to saturate the sense magnetization in accordance with the direction of the write magnetic field. 8. The multibit MRAM cell according to any one of claim 7 , wherein said aligning means comprises a field line magnetically coupled to the magnetic tunnel junction and adapted for passing a first write current inducing a first write magnetic field; and a bit line electrically coupled to the magnetic tunnel junction and adapted for passing a second write current inducing a second write magnetic field; the magnetic field resulting from the combination of the first and second write magnetic field. 9. A method for operating a multibit MRAM cell comprising a magnetic tunnel junction including a sense layer having a freely orientable sense magnetization; a tunnel barrier layer between the sense layer and a storage layer; the storage layer comprising a first storage layer having a first storage magnetization, a second storage layer having a second storage magnetization and a storage coupling layer between the first and second storage layers; the first storage magnetization being pinned by an antiferromagnetic layer at a low threshold temperature of the magnetic tunnel junction and unpinned at a high threshold temperature of the magnetic tunnel junction; the sense magnetization being arranged for inducing a dipolar field having a magnitude above a spin-flop field of the storage layer capable of aligning the second storage magnetization when the magnetic tunnel junction is at the high threshold temperature such that each of the first and second storage magnetization is oriented with a spin-flop angle θ SF to the direction of the dipolar field; the MRAM cell further comprising aligning means for aligning the sense magnetization in a plurality of distinct orientations in the range of 0° to 360°, wherein the first and second storage magnetizations move to maintain their orientation of spin-flop angle θ SF to the direction of the dipolar field, during said aligning, such that the first and second storage magnetization can be aligned in said plurality of distinct orientations in the dipolar field, in accordance with the direction of the sense magnetization, when the magnetic tunnel junction is at the high threshold temperature; the method comprising, during a write operation: heating the antiferromagnetic storage layer to the high threshold temperature such as to unpin the first storage magnetization; orientating the first storage magnetization with the dipolar field such that each of the first and second storage magnetization is oriented with a spin-flop angle θ SF to the direction of the dipolar field; aligning the sense magnetization in one of said plurality of distinct orientations, and wherein the first and second storage magnetization move to maintain their orientation of spin-flop angle θ SF to the direction of the dipolar field, during said aligning, such as to switch the first and second storage magnetization in the induced dipolar field in accordance with the direction of the sense magnetization; cooling the antiferromagnetic storage layer to the low threshold temperature to freeze the first storage magnetization and to switch, by magnetic coupling, the second storage magnetization in a direction antiparallel to the one of the first storage magnetization. 10. The method according to claim 9 , wherein said aligning the sense magnetization comprises applying a write magnetic field having a magnitude adapted for saturating the sense magnetization in a direction corresponding to the one of the write magnetic field. 11. The method according to claim 9 , wherein the multibit MRAM cell further comprises a field line magnetically coupled to the magnetic tunnel junction adapted for passing a first write current, and a bit line electrically coupled to the magnetic tunnel junction and adapted for passing a second write current; the method further comprising: passing the first write current in the field line to induce a first write magnetic field and passing the second write current in the bit line to induce the second write magnetic field; adjusting the direction and magnitude of each of the first and second write current such that the write magnetic field is oriented in one of said plurality of distinct orientations. 12. The method according to claim 9 , further comprising, during a read operation: performing a plurality of read cycles, wherein each read cycle comprises aligning the sense magnetization direction relative to the switched direction of the second storage magnetization, and measuring a resistance of the magnetic tunnel junction being indicative of a degree of alignment between the sense magnetization direction and the second storage magnetization direction. 13. The multibit MRAM cell according to claim 2 , wherein the first and, second storage layer has a thickness be