NOVEL LATTICE MATCHED SEED LAYER TO IMPROVE PMA FOR PERPENDICULAR MAGNETIC PINNING
The invention comprises a novel composite seed layer with lattice-matched crystalline structure so that an excellent epitaxial growth of magnetic pinning layer along its FCC (111) orientation can be achieved, resulting in a significant enhancement of PMA for perpendicular spin-transfer-torque magnetic-random-access memory (pSTT-MRAM) using perpendicular magnetoresistive elements as basic memory cells which potentially replace the conventional semiconductor memory used in electronic chips, especially mobile chips for power saving and non-volatility.
This invention relates to a novel lattice-matched seed layer (LmSL) to improve perpendicular magnetic anisotropy (PMA) for magnetic pinning multilayer in a magnetic structure, such as a perpendicular magnetic tunnel junction.
2. Description of the Related ArtIn recent years, magnetic random access memories (hereinafter referred to as MRAMs) using the magnetoresistive effect of ferromagnetic tunnel junctions (also called MTJs) have been drawing increasing attention as the next-generation solid-state nonvolatile memories that can cope with high-speed reading and writing, large capacities, and low-power-consumption operations. A ferromagnetic tunnel junction has a three-layer stack structure formed by stacking a storage layer (SL) having a changeable magnetization direction, an insulating spacing layer, and a fixed pinning layer (PL) that is located on the opposite side from the SL and maintains a predetermined magnetization direction. The insulating spacing layer sandwiched between the SL and the PL serves as a tunneling barrier (TB) in a magnetic tunnel junction. In a SOT MRAM, there is an additional SOT layer immediately located on a surface of the SL, which is opposite to a surface of the SL where the insulating spacing layer is provided. SOT can be a thin layer made of heavy transition metal layer such as W or Ta, Pt, etc., or a layer of topological insulating layer such as BiSB.
As a write method to be used in such magnetoresistive elements of a STT MRAM, there has been suggested a write method (spin torque transfer switching technique) using spin momentum transfers. According to this method, the magnetization direction of a storage layer (SL) is reversed by applying a spin-polarized current to the magnetoresistive element. Furthermore, as the volume of the magnetic layer forming the SL is smaller, the injected spin-polarized current to write or switch can be also smaller. Accordingly, this method is expected to be a write method that can achieve both device miniaturization and lower currents. In a SOT MRAM, an electric current flows in the SOT layer, which is also a paramagnetic layer, to generate a spin-polarized current and inject it into its adjacent recording layer, which is a ferromagnetic layer. The spin-polarized current then exerts a torque on the magnetic moment to reverse it.
Further, as in a so-called perpendicular pMTJ element, both two magnetization films, i.e., the storage layer (SL) and the pinning layer (PL), have easy axis of magnetization in a direction perpendicular to the film plane due to their strong perpendicular interfacial anisotropy and magnetic crystalline anisotropy (shape anisotropies are not used), and accordingly, the device shape can be made smaller than that of an in-plane magnetization type. Also, variance in the easy axis of magnetization can be made smaller. Accordingly, by using a material having a large perpendicular magnetic crystalline anisotropy, both miniaturization and lower currents can be expected to be achieved while a thermal disturbance resistance is maintained.
There has been a known technique for achieving a high MR ratio in a perpendicular MTJ element by forming an underneath MgO tunnel barrier layer and a BCC or HCP-phase cap layer that sandwich a thin storage layer (SL) having an amorphous CoFeB ferromagnetic film and accelerate crystallization of the amorphous ferromagnetic film to match interfacial grain structure to MgO layer through a thermal annealing process. The SL crystallization starts from the tunnel barrier layer side to the cap layer and forms a CoFe grain structure having a perpendicular magnetic anisotropy, as Boron elements migrate into the cap layer. Accordingly, a coherent perpendicular magnetic tunnel junction structure is formed. By using this technique, a high MR ratio can be achieved.
A core structure of the pMTJ stack comprises (see
Recently a French research group proposed (see Scientific Reports 8, Article number: 11724, 2018) a thin synthetic antiferromagnetic (tSAF) structure (see
No matter whether it is a thick pSAF or thin tSAF film stack, a key factor to achieve stable magnetic pinning is perpendicular magnetic anisotropy (PMA) of the perpendicular magnetic pinning layer (pMPL) [Co/Pt]m/Co (12), which provides a magnetic anchoring force to prevent the entire pSAF (or tSAF) film stack from a concurrent rotation under the influence of spin transfer torque or an external magnetic field. It was reported (see Article: Appl. Phys. Lett. 96, 152505 (2010)) that the PMA of Co/Pt (or Co/Pd) magnetic multilayer is closely dependent on the lattice constant of the multilayer itself, and a positive (perpendicular) PMA occurs only when Co/Pt (or Co/Pd) multilayer has FCC crystalline structure with a lattice constant larger than ˜0.372 nm, and the larger the lattice constant, the higher is the PMA of Co/Pt (or Co/Pd) multilayer. Without an external factor, increase of the PMA of Co/Pt (or Co/Pd) can only be achieved by increasing the thickness of Pt (or Pd) spacer. However, a research group found (see their report: Sensors, 17(12): 2743, December 2017) that the effective energy per bilayer starts to decrease linearly after a lattice constant value of ˜0.383 nm. They attributed this to the enhanced increase in the Pd fraction compared to the Co, which weakens the ferromagnetic coupling between the adjacent ultrathin Co layers.
SUMMARY OF THE PRESENT INVENTIONThe present invention discloses a lattice-matched seed layer (LmSL) having FCC crystalline structure to promote a perfect FCC (111) growth for above perpendicular magnetic pinning layer (pMPL) to enhance its PMA needed for magnetic stabilization. Said LmSL comprises:
a bi-layer stack containing (Rh, Cu, Al, Ag, or Au)/(Pt, Pd, or Ir) or (alloy of Rh, Cu, Al, Ag, or Au)/(Pt, Pd, or Ir) having a FCC crystalline structure with its lattice constant matched with said pMPL;
or bi-layer stack containing (RhN, CuN, AlN, or AgN)/(Pt, Pd, or Ir) or (alloy of RhN, CuN, AlN, or AgN)/(Pt, Pd, or Ir) with nitrogen (N) content tuned so that said RhN, CuN, AlN, AgN having its lattice constant matched with said pMPL;
or a multi-layer stack containing (RhN, CuN, AlN, or AgN)/X/(Pt, Pd, or Ir) or (alloy of RhN, CuN, AlN, or AgN)/X/(Pt, Pd, or Ir) with nitrogen (N) content tuned so that said RhN, CuN, AlN, AgN having its lattice constant matched with Pt, Pd, or Ir and having a thickness between 0.5 nm-10 nm, whereas X is a thin layer consisting of one or more transition metal elements selected from the group of Ta, Mo, Hf, W, Nb, Zr, Ru and having a thickness between 0.1 nm-2 nm.
Said LmSL and pMPL both having an FCC crystalline structure together with a composite non-magnetic spacer (CnmS) and a perpendicular magnetic reference layer (pMRL) having a body-center-cubic (BCC) crystalline structure constitute a strong perpendicular magnetic pinning element (pMPE): LmSL/pMPL/CnmS)/pMRL with enhanced synthetic antiferromagnetic (eSAF) coupling.
Said pMRL comprises a multilayer stack containing [Co/(Pt, Pd or Ni)]m/Co, and said CnmS comprises either a single layer of Ru, or Ir or a bi-layer of (Ru, Rh or Ir)/Cr or tri-layer of (Ru, Rh, or Ir)/(W, Mo, or V)/Cr, and said pMRL comprises a multilayer stack either of Co/[(Pt, Pd or Ni)]n/Co/(W, Mo, or Ta)/CoFeB for single layer Ru spacer, or Fe/CoFeB, Fe/FeB, FeB/CoFe for bilayer or tri-layer CnmS.
Said pMPE with large PMA are employed to form a perpendicular magnetoresistive element (pMRE) comprising LmSL/pMPL/CnmS/pMRL/TB/SL/CL or a reverse structure of BCC seed layer/SL/TB/PMRL/CnmS/pMPL/LmSL, and wherein said TB is a tunnel barrier, SL is a storage layer (SL) having magnetic anisotropy in a direction perpendicular to a film surface and having a variable magnetization direction on the tunnel barrier layer and CL is a capping layer.
Application of said pMRE including bottom-pinned pSTT-MRAM, top-pinned pSTT-MRAM and dual-pinned pSTT-MRAM. Said pMRE is sandwiched between an upper electrode and a lower electrode of each MRAM memory cell, which also comprises a write circuit which bi-directionally supplies a spin polarized current to the magnetoresistive element and a select transistor electrically connected between the magnetoresistive element and the write circuit.
Table 1 List of crystalline structure and corresponding lattice constant for some selected metallic elements.
DETAILED DESCRIPTION OF THE INVENTIONFrom prior art discussion, the PMA of the perpendicular magnetic pinning layer (pMPL) (Co/Pt (or Co/Pd) multilayer) is closely related to its lattice constant, and the larger is the lattice constant, the higher is its PMA. In this invention, we employ a lattice-matched seed layer (LmSL) with FCC (111) crystalline structure at the bottom of Co/Pt or Co/Pd multilayer to provide a specially engineered lattice mold (bedding) for the growth of Co/Pt or Co/Pd multilayer to maximize its PMA. Among the various materials in periodical table, there are some metallic elements (see Table 1) which naturally form an FCC crystalline structure in their solid phase with lattice constant close to or slightly larger than that of Co/Pt (or Co/Pd). Said LmSL is in direct contact with said pMPL either from below or on the top as a cap with a thickness between 0.5 nm-10 nm; and said LmSL comprise several film configurations as below:
-
- (1) said LmSL is a bi-layer stack containing (Rh, Cu, Al, Ag, or Au)/(Pt, Pd, or Ir) (stack 113 in
FIG. 3 ) or (alloy of Rh, Cu, Al, Ag, or Au)/(Pt, Pd, or Ir) (stack 114 inFIG. 3 ) having a FCC crystalline structure with its lattice constant matched with said pMPL; wherein for the alloyed LmSL, an element with a larger lattice constant (such as Al, Ag, Au) can be mixed with element having a smaller lattice constant (such as Ni or Cu) to form a just-right lattice constant to maximize the PMA for Co/Pt (or Co/Pd) multilayer; - (2) said LmSL is a bi-layer stack containing (RhN, CuN, AlN, or AgN)/(Pt, Pd, or Ir) or (alloy of RhN, CuN, AlN, or AgN)/(Pt, Pd, or Ir) (stack 115 in
FIG. 3 ) with nitrogen (N) content tuned so that said RhN, CuN, AlN, AgN having its lattice constant matched with or larger than Pt (or Pd); wherein the metal nitridation is done by ion assisted physical vapor deposition (PVD) or ion bean deposition (IBD); wherein said lattice constant of nitrides (RhN, CuN, AlN, or AgN) can be increased by adding more nitrogen (N2) gas to Ar gas during deposition, for example to a nitrogen-rich CuN can have a lattice constant of 0.388 nm. - (3) said LmSL is a tri-layer stack (stack 116 in
FIG. 3 ) containing (RhN, CuN, AlN, or AgN)/X/(Pt, Pd, or Ir) or (alloy of RhN, CuN, AlN, or AgN)/X/(Pt, Pd, or Ir) with nitrogen (N) content tuned so that said RhN, CuN, AlN, AgN having its lattice constant matched with Pt (or Pd), whereas X is a thin layer consisting of one or more transition metal elements selected from the group of Ta, Mo, Hf, W, Nb, Zr, Ru and has a thickness no more than 2 nm. Adding of such transition metal in between, crystalline structure (lattice constant and crystalline orientation) said LmSL can be optimized to further enhance PMA for said pMPL.
- (1) said LmSL is a bi-layer stack containing (Rh, Cu, Al, Ag, or Au)/(Pt, Pd, or Ir) (stack 113 in
The following lists are some typical embodiments to illustrate the use of said LmSL to increase PMA for perpendicular magnetic stabilization for bottom-pined, top-pined and dual-pinned pSTT-MRAM having either a thick pSAF or thin tSAF film stack:
First EmbodimentThe annealing temperature of above bottom-pinned film pSTT-MRAM stacks are between 350 C-450 C for 30 min to 150 min. With the help of said LmSL, after annealing the low portion (11-13) of the stack including Ru will be converted into FCC crystalline structure with (111) orientation normal to film surface and upper portion of the stack (16-21) above Cr into a BCC (100) crystalline structure to achieve a large PMA while having a high tunnel magnetoresistive (TMR) value. For comparison,
While certain embodiments have been described above, these embodiments have been presented by way of example only, and are not intended to limit the scope of the inventions. Indeed, the novel embodiments described herein may be embodied in a variety of other forms; furthermore, various omissions, substitutions and changes in the form of the embodiments described herein may be made without departing from the spirit of the inventions. The accompanying claims and their equivalents are intended to cover such forms or modifications as would fall within the scope and spirit of the inventions.
Claims
1. A perpendicular magnetic pinning element (pMPE) comprising
- a lattice-matched seed layer (LmSL) having a face-center-cubic (FCC) crystalline structure;
- a perpendicular magnetic pinning layer (pMPL) provided on the top surface of the LmSL and having a face-center-cubic (FCC) crystalline structure and having an invariable magnetization direction, and said LMSL/pMPL forming a strong perpendicular magnetic anisotropy (PMA);
- an antiferromagnetic coupling spacer (AFCs) provided on the top surface of the pMPL and having a single layer structure of (Ru, Rh or Ir), bi-layer structure of (Ru, Rh or Ir)/Cr or tri-layer structure of (Ru, Rh, or Ir)/(W, Mo, or V)/Cr;
- a perpendicular magnetic reference layer (pMRL) provided on the top surface of the AFCs and having a body-center-cubic (BCC) crystalline structure and having an invariable magnetization direction;
- said pMPE forming a strong antiferromagnetic coupling (AFC);
2. The element of claim 1, wherein said pMPL is a multilayer stack containing [Co/(Pt, Pd or Ni)]n/Co wherein n is an integer between 2 and 6, and thickness of each said Co and (Pt, Pd, or Ni) is between 0.25 nm-0.7 nm and 0.2 nm-0.8 nm, respectively.
3. The element of claim 1, wherein said LmSL is a bi-layer stack containing (Rh, Cu, Al, Ag, or Au)/((Pt, Pd, or Ir) or alloy of (Pt, Pd, or Ir)) or (alloy of Rh, Cu, Al, Ag, or Au)/((Pt, Pd, or Ir) or alloy of (Pt, Pd, or Ir)) having a FCC crystalline structure with its lattice constant matched with said pMPL and having a thickness between 0.5 nm-10 nm.
4. The element of claim 1, wherein said LmSL is a bi-layer stack containing (RhN, CuN, AlN, or AgN)/((Pt, Pd, or Ir) or alloy of (Pt, Pd, or Ir)) or (alloy of RhN, CuN, AlN, or AgN)/((Pt, Pd, or Ir) or alloy of (Pt, Pd, or Ir)) with nitrogen (N) content tuned so that said RhN, CuN, AlN, AgN having its lattice constant matched with Pt, Pd, or Ir and having a thickness between 0.5 nm-10 nm.
5. The element of claim 1, wherein said LmSL is a multi-layer stack containing (RhN, CuN, AlN, or AgN)/X/((Pt, Pd, or Ir) or alloy of (Pt, Pd, or Ir)) or (alloy of RhN, CuN, AlN, or AgN)/X/((Pt, Pd, or Ir) or alloy of (Pt, Pd, or Ir)) with nitrogen (N) content tuned so that said RhN, CuN, AlN, AgN having its lattice constant matched with Pt, Pd, or Ir and having a thickness between 0.5 nm-10 nm, whereas X is a thin layer consisting of one or more transition metal elements selected from the group of Ta, Mo, Hf, W, Nb, Zr, Ru and having a thickness no more than 2 nm.
6. The element of claim 1, wherein said LmSL is a multi-layer stack containing (RhN, CuN, AlN, or AgN)/X/((Pt, Pd, or Ir) or alloy of (Pt, Pd, or Ir)) or (alloy of RhN, CuN, AlN, or AgN)/X/((Pt, Pd, or Ir) or alloy of (Pt, Pd, or Ir)) with nitrogen (N) content tuned so that said RhN, CuN, AlN, AgN having its lattice constant matched with Pt, Pd, or Ir and having a thickness between 0.5 nm-10 nm, whereas X is a thin layer consisting of one or more transition metal elements selected from the group of Ta, Mo, Hf, W, Nb, Zr, Ru and having a thickness between 0.3 nm-1.0 nm.
7. The element of claim 1, wherein said LmSL and said pMPL both having their closed-packed FCC (111) crystalline orientation normal to the film surface.
8. The element of claim 1, wherein said pMRL containing a bi-layer stack of Fe/CoFeB, Fe/FeB, FeB/CoFeB, or Fe/CoFe and said Fe having a thickness between 0.1-0.5 nm, said CoFeB, FeB and CoFe having a thickness between 0.7 nm 1.3 nm.
9. The element of claim 1, wherein said pMRL containing a multilayer stack of Fe/[Co/(Pt, Pd or Ni)]m/(W or Mo)/CoFeB, with m an integer between 2 and 4; and the thickness of said Co and (Pt, Pd, or Ni) is between 0.25 nm-0.7 nm and 0.2 nm-0.8 nm, respectively, said CoFeB having a thickness between 0.7 nm-1.3 nm., said W, Mo having a thickness between 0.1 nm to 0.5 nm.
10. The element of claim 1, wherein said strong AFC between said pMPL and said pMRL is achieved through interfacial RKKY coupling having a film stack configuration of Co/AFCs/Fe or Co/AFCs/FeB, FeCo(>50%)/AFCs/Fe(>50%)Co, or Co/AFCs/Fe(>40%)CoB; wherein said Co or FeCo(>50%) layer is an interfacial portion of pMPL contacting with the (Ru, Rh, or Ir) of said AFCs and said Fe, FeB, Fe(>50%)Co or Fe(>40%)CoB layer is an interfacial portion of pMRL contacting with the Cr of said AFCs.
11. The element of claim 1, wherein said (Ru, Rh or Ir) in single layer structure of AFCs has a thickness between 0.4 nm to 0.85 nm, wherein said (Ru, Rh or Ir) in bi-layer or tri-layer structure has a thickness between 0.3 nm to 0.7 nm and said Cr or (W, Mo, or V)/Cr in said AFCs has a thickness between 0.1 nm to 0.5 nm so that the total thickness combination of Ru/Cr or (W, Mo, or V)/Cr is at the (effective) first peak or 2nd peak of RKKY coupling with their interfacial magnetic layers of Co and Fe.
12. The element of claim 1, wherein said pMPE has its magnetization direction perpendicular to the surface of said film stack, and said pMPE further forms a perpendicular magnetic tunnel junction (pMTJ) together with a tunnel barrier (TB) and a storage layer (SL), whereas said TB is sandwiched between said SL and said pMPL.
13. The element of claim 12, wherein said TB is an MgO layer having a thickness between 0.8 nm to 1.5 nm, and said SL is a single layer CoFeB or tri-layer CoFeB/(W or Mo)/CoFeB having a total CoFeB thickness between 1 nm-2.0 nm, wherein said W or Mo has a thickness between 0.1 nm-0.5 nm.
14. The element of claim 12, wherein said pMTJ comprises a film stack of LmSL/pMPL/AFCs/pMRL/TB/SL/capping layer counting from bottom to top, forming a bottom-pinned pSTT-MRAM film element.
15. The element of claim 12, wherein said pMTJ comprises a film stack of BCC seed layer/SL/TB/pMRL/AFCs/pMPL/LmSL cap layer counting from bottom to top, forming a top-pinned pSTT-MRAM film element.
16. The element of claim 12, wherein said pMTJ comprises a film stack of LmSL/pMPL1/AFCs1/pMRL1/TB1/SL/TB2/pMRL2/AFCs2/pMPL2/LmSL cap layer, forming a dual-pinned pSTT-MRAM film element.
17. The element of claim 14, wherein said bottom-pinned pSTT-MRAM film element comprises a film stack of substrate/LmSL/[Co/Pt]n/Co/(Ru, Rh, or Ir)/[Co/Pt]m/Co/(Ta, W or Mo)/CoFeB/MgO/CoFeB/(W or Mo)/CoFeB/MgO/W/Ru/Ta, with said superlattice repeating numbers n and m ranging from 2 to 6 and 1 to 4 respectively.
18. The element of claim 14, wherein said bottom-pinned pSTT-MRAM film element comprises a film stack of substrate/LmSL/[Co/Pt]n/Co/(Ru, Rh, or Ir)/Cr/Fe/CoFeB/MgO/CoFeB/W or Mo/CoFeB/MgO/W/Ru/Ta or substrate/Pt/[Co/Pt]n/Co/(Ru, Rh, or Ir)/(W, Mo, or V)/Cr/Fe/CoFeB/MgO/CoFeB/W, Mo/CoFeB/MgO/W/Ru/Ta.
19. The element of claim 16, wherein said dual-pinned pSTT-MRAM film element comprises a film stack of substrate/LmSL/[Co/Pt]n/Co/(Ru, Rh or Ir)/Cr/Fe/CoFeB/MgO/CoFeB/W or Mo/CoFeB/MgO/CoFeB/Fe/Cr/(Ru, Rh or Ir)/Co/[Pt/Co]n/LmSL/W/Ru or substrate/LmSL/[Co/Pt]n/Co/(Ru, Rh, or Ir)/(W, Mo, or V)/Cr/Fe/CoFeB/MgO/CoFeB/W or Mo/CoFeB/MgO/CoFeB/Fe/Cr/(W, Mo, or V)(Ru, Rh or Ir)/Co/[Pt/Co]n/LmSL/W/Ru.
20. The element of claim 16, wherein said dual-pinned pSTT-MRAM film element comprises a film stack of substrate/ or substrate/LmSL//[Co/(Pt or Pd)]m/Co/(Ru or Ir)/Co/[(Pt or Pd]/Co]n/(W, Mo or Ta)/CoFeB/MgO/CoFeB/(W or Mo)/CoFeB/MgO/CoFeB/(W, Mo or Ta)/Co/[Co/Pt or Pd]n/Co/(Ru or Ir)/Co/[(Pt or Pd)/Co]m/LmSL/cap.
Type: Application
Filed: Feb 10, 2020
Publication Date: Aug 12, 2021
Inventor: RONGFU XIAO (DUBLIN, CA)
Application Number: 16/786,304