peter wadley...2016/09/26 · • wide range of antiferromagnetic systems : oxides, semiconductors,...
Post on 24-Jan-2021
6 Views
Preview:
TRANSCRIPT
-
Univ. of Nottingham United Kingdom (P Wadley, K Edmonds, R Campion, B Gallagher et al.)
Inst. of Physics ASCRPrague, Czech Republic(T Jungwirth, V Novak, K Olejnik, X.Marti, V. Schuler)
Hitachi Cambridge Lab. United Kingdom (J Wunderlich, P. Roy)
Diamond Light Source, United Kingdom (S Dhesi, F Maccherozzi)
Current induced switching of an antiferromagnet
Univ. of Mainz, Forschungs-zentrum Julich, Germany (J Sinova, H Gomonay, F Freimuth
Institute of Physics, Warsaw, Poland(M Grzybowski, M Sawicki, T Dietl)
Peter Wadley
-
Outline
• Motivation• Spintronics with antiferromagnets• CuMnAs system• Current induced switching of the spin axis• Imaging of domain structure• Imaging the switching• Conclusions and outlook
-
• Wide range of antiferromagnetic systems :oxides, semiconductors, semimetals, half metals, metals etc
• Some spin-orbit based magnetotransport effects are equally strong in AF systems (AMR, TAMR…..) (Shick et al Phys. Rev. B 81, 212409 (2010)) demonstration (Marti, PW et al Nat. Mat. (‘14), Park et al. Nature Mat. ’11, PRL ’12), Wang et al. PRL ’12:)
• No stray fringing fields. Robust against external magnetic fields (like charge based memory) and against radiation (like magnetic memory)
• Ultrafast dynamics (Kimel,Rasing et al Nature ‘04, P. Roy, Wunderlich PRB 16, Gomonay, Jungwirth, Sinova PRL 16)
• Topologically interesting systems : predictions of magnetically switchable Dirac semimetals (L. Smejkal-Thursday morning) and AF skyrmionic compounds
Motivation
-
“Interesting, but without application”
Spintronics with antiferromagnets
Ferromagnet (FM): global uniform
molecular field
Antiferromagnet (AF):local alternating molecular field
Exchange biasspin valve
AFpinned FMfree FM
-
“Interesting, but without application”
Example:Magnetic anisotropy energy due to coupling between spin and lattice orbitals ⟶ magnetic memory
EnergyDOS
EnergyDOS
Spintronics with antiferromagnets
Ferromagnet (FM): global uniform
molecular field
Antiferromagnet (AF):local alternating molecular field
Effects even in magnetization should be equally present in FM and AF
-
“Interesting, but without application”
Spintronics with antiferromagnets
Ferromagnet (FM): global uniform
molecular field
Antiferromagnet (AF):local alternating molecular field
Effects even in magnetization should be equally present in FM and AF
To make them more widely applicable we need the ability to efficiently control and measure the spin state…
-
01
FMmemory bit
01
AFmemory bit
0 π4
π2
π3π4
R
M vs. I angle
Reading the antiferromagnetic state:Anisotropic Magnetoresistance (AMR)
V
MI
V
MI
high resistance state low resistance state
W Thomson , Proc. Roy. Soc. (1856)
-
Reading the antiferromagnetic state:Anisotropic Magnetoresistance (AMR)
(transverse geometry)
VI
longitudinal Rxx = R0 + R1cos2F
transverse Rxy = R1sin2F
F
M
I
-
Switching an antiferromagnet
Need to generate an alternating local field on a sub unit cell resolution!
Zelezny, Jungwirth et al PRL 2014 predict a way to accomplish this based on current–induced spin polarization
F. Freimuth
-
Inverse spin galvanic (Edelstein) effect
!pcurr ⊥!J
Global inversion asymmetry - -> non-equilibrium spin polarization
Current-induced spin polarization
GaAs
J
!pcurr
LETTERS
PUBLISHED ONLINE: 2 AUGUST 2009 | DOI: 10.1038/NPHYS1362
Evidence for reversible control of magnetization ina ferromagnetic material by means of spin–orbitmagnetic fieldAlexandr Chernyshov1*, Mason Overby1*, Xinyu Liu2, Jacek K. Furdyna2, Yuli Lyanda-Geller1and Leonid P. Rokhinson1†
The current state of information technology accentuates thedichotomy between processing and storage of information,with logical operations carried out by charge-based devices andnon-volatile memory based on magnetic materials. The mainobstacle for a wider use of magnetic materials for informationprocessing is the lack of efficient control of magnetization.Reorientation of magnetic domains is conventionally carriedout by non-local external magnetic fields or by externallypolarized currents1–3. The efficiency of the latter approachis enhanced in materials where ferromagnetism is carrier-mediated4, because in such materials the control of carrierpolarization provides an alternative means for manipulatingthe orientation of magnetic domains. In some crystallineconductors, the charge current couples to the spins bymeans of intrinsic spin–orbit interactions, thus generatingnon-equilibrium electron spin polarization5–11 tunable by localelectric fields. Here, we show that magnetization can bereversibly manipulated by the spin–orbit-induced polarizationof carrier spins generated by the injection of unpolarizedcurrents. Specifically, we demonstrate domain rotation andhysteretic switching of magnetization between two orthogonaleasy axes in a model ferromagnetic semiconductor.
In crystalline materials with inversion asymmetry, intrinsicspin–orbit interactions couple the electron spinwith itsmomentumh̄k. The coupling is given by the Hamiltonian Hso = (h̄/2)�̂ ·(k),where h̄ is the reduced Planck constant and �̂ is the electronspin operator (for holes �̂ should be replaced by the total angularmomentum J). Electron states with different spin projection signson (k) are split in energy, analogous to the Zeeman splittingin an external magnetic field. In zinc-blende crystals such asGaAs there is a cubic Dresselhaus term12 D / k3, whereas strainintroduces a term " = C1"(kx ,�ky ,0) that is linear in k, where1" is the difference between strain in the ẑ and x̂, ŷ directions13.In wurtzite crystals or in multilayered materials with structuralinversion asymmetry, there also exists the Rashba term14 R,which has a different symmetry with respect to the direction of k,R =↵R(�ky ,kx ,0), where ẑ is along the axis of reduced symmetry.In the presence of an electric field, the electrons acquire an averagemomentum h̄1k(E), which leads to the generation of an electriccurrent j= ⇢̂�1E in the conductor, where ⇢̂ is the resistivity tensor.This current defines the preferential axis for spin precession h(j)i.As a result, a non-equilibrium current-induced spin polarizationhJEikh(j)i is generated, the magnitude of which hJ Ei dependson the strength of various mechanisms of momentum scattering
1Department of Physics and Birck Nanotechnology Center, Purdue University, West Lafayette, Indiana 47907, USA, 2Department of Physics, University ofNotre Dame, Notre Dame, Indiana 46556, USA. *These authors contributed equally to this work. †e-mail: leonid@purdue.edu.
jy jy
jxjx
6 µm M4
56
[110] [110]
[1 10] [1 10]
8
7
321
Heff
Heff
Heff
Heff
+I¬I
¬I
+I
[1 10]
[010]
[010]
[110]
[100]
[100]
Hϕ
ϕ
MH
a b
c d
Figure 1 | Layout of the device and symmetry of the spin–orbit fields.a, Atomic force micrograph of sample A with eight non-magnetic metalcontacts. b, Diagram of device orientation with respect to crystallographicaxes, with easy and hard magnetization axes marked with blue dashed andred dot–dash lines, respectively. Measured directions of Heff field areshown for different current directions. c,d, Orientation of effective magneticfield with respect to current direction for strain-induced (c) and Rashba (d)spin–orbit interactions. The current-induced Oersted field under thecontacts has the same symmetry as the Rashba field.
and spin relaxation5,15. This spin polarization has been measuredin non-magnetic semiconductors using optical7–9,11,16 and electronspin resonance17 techniques. It is convenient to parameterize hJEiin terms of an effective magnetic field Hso. Different contributionsto Hso have different current dependencies (/ j or j3), as wellas different symmetries with respect to the direction of j, asschematically shown in Fig. 1c,d, enabling one to distinguishbetween spin polarizations in different fields.
To investigate interactions between the spin–orbit-generatedmagnetic field and magnetic domains, we have chosen (Ga,Mn)As,a p-type ferromagnetic semiconductor18,19 with zinc-blende crys-talline structure similar to GaAs. Ferromagnetic interactions in thismaterial are carrier-mediated20,21. The total angular momentum ofthe holes J couples to the magnetic moment F of Mn ions by means
656 NATURE PHYSICS | VOL 5 | SEPTEMBER 2009 | www.nature.com/naturephysics
LETTERS
NATURE PHYSICS DOI: 10.1038/NPHYS1362
Figure 3 | Determination of current-induced effective spin–orbit magnetic field. a,b, Difference in switching angles for opposite current directions 1'(i)Has a function of I for sample A for different external fields H for orthogonal current directions. c, The measured effective field Heff =Hso ±HOe as a functionof average current density hji for sample A (triangles) and sample B (diamonds). d, Schematic diagram of the different angles involved in determining Heff:'H is the angle between current I and external magnetic field H; 1'H is the angle between total fields H+Heff(+I) and H+Heff(�I) and ✓ is the anglebetween I and Heff(+I).
0
0 200 400 600 800Time (s)
I
I I
IM
M M
M
¬101
I (m
A)
I (mA)
0
¬1.0 –0.5 0 0.5 1.0
5
¬5
Rxy
(Ω
)
Rxy
(Ω
)
0
5
¬5
0
Rxy
(Ω
)
¬5
5
45 90
a b
c
¬1 1〈 j 〉 µ 106 (A cm¬2) H
(°)ϕ
Figure 4 | Current-induced reversible magnetization switching. a, 'Hdependence of Rxy near the [010] ! [̄100] magnetization switching forI= ±0.7 mA in sample A for Ik[11̄0]. b, Rxy shows hysteresis as a functionof current for a fixed field H= 6 mT applied at 'H = 72�. c, Magnetizationswitches between the [010] and [̄100] directions when alternating ±1.0 mAcurrent pulses are applied. The pulses have 100 ms duration and are shownschematically above the data curve. Rxy is measured with I= 10 µA.
experiment. As for the magnitude of H so, for three-dimensionalJ = 3/2 holes we obtain
Hso(E)= eC1"g ⇤µB
(�38nh⌧h +18nl⌧l)217(nh +nl)
·(Ex ,�Ey ,0)
where E is the electric field, g ⇤ is the Luttinger Landé factor forholes, µB is the Bohr magneton and nh,l and ⌧h,l are densities andlifetimes for the heavy (h) and light (l) holes. Detailed derivation ofH so is given in the Supplementary Information. Using this result, weestimate dH so/dj = 0.6⇥10�9 T cm2 A�1 assuming nh =n�nl and⌧h =mh/(e2⇢n), where ⇢ is the resistivity measured experimentally,and using 1" = 10�3, n = 2⇥ 1020 cm�3. The agreement betweentheory and experiment is excellent. It is important to note, however,that we used GaAs band parameters25 mh = 0.4m0, where m0is the free electron mass, g ⇤ = 1.2 and C = 2.1 eVÅ. Althoughthe corresponding parameters for (Ga,Mn)As are not known, theuse of GaAs parameters seems reasonable. We note, for example,
that GaAs parameters adequately described tunnelling anisotropicmagnetoresistance in recent experiments26.
Finally, we demonstrate that the current-induced effective spin–orbit field H so is sufficient to reversibly manipulate the directionof magnetization. Figure 4a shows the 'H dependence of Rxy forsample A, showing the [010] ! [1̄00] magnetization switching. Ifwe fixH = 6mT at 'H = 72�, Rxy forms a hysteresis loop as currentis swept between ±1mA. Rxy is changing between ±5, indicatingthat M is switching between the [010] and [1̄00] directions. Short(100ms) 1mA current pulses of alternating polarity are sufficient topermanently rotate the direction of magnetization. The device thusperforms as a non-volatile memory cell, with two states encoded inthe magnetization direction, the direction being controlled by theunpolarized current passing through the device. The device can bepotentially operated as a four-state memory cell if both the [110]and [1̄10] directions can be used to inject current. We find thatwe can reversibly switch the magnetization with currents as low as0.5mA (current densities 7⇥ 105 A cm�2), an order of magnitudesmaller than by polarized current injection in ferromagneticmetals1–3, and just a few times larger than by externally polarizedcurrent injection in ferromagnetic semiconductors4.
MethodsThe (Ga,Mn)As wafers were grown by molecular beam epitaxy at 265 �C andsubsequently annealed at 280 �C for 1 h in nitrogen atmosphere. Sample Awas fabricated from a 15-nm-thick epilayer with 6% Mn, and sample B from a10-nm-thick epilayer with 7%Mn. Both wafers have a Curie temperature Tc ⇡80K.The devices were patterned into 6- and 10-µm-diameter circular islands to decreasedomain pinning. Cr/Zn/Au (5 nm/10 nm/300 nm) ohmic contacts were thermallyevaporated. All measurements were carried out in a variable-temperature cryostatat T = 40K for sample A and at 25K for sample B, well below the temperature of(Ga,Mn)As-specific cubic-to-uniaxial magnetic anisotropy transitions27, which hasbeen measured to be 60 and 50K for the two wafers. The temperature rise for thelargest currents used in the reported experiments wasmeasured to be
-
SiSi
BA
!pcurr,A
Local inversion asymmetry
J
!pcurr,B
Writing by spin-orbit torque in antiferromagnetsInverse spin galvanic (Edelstein) effect
Zhang et al. Nature Phys. 2014 Zelezny, et al. PRL2014
“Hidden” spin polarization
-
Switching an antiferromagnet
All we have to do is find a system where the local spin accumulation matches the spin sub-lattices
Tetragonal CuMnAs
J
Cu"
As"
Mn"Mn"
a"0
1
b"
1⟶0
AMR9read"biaxial"AF"
0⟶1
1
0
write"biaxial"AF"
“GMR”9read"uniaxial"AF"
1 0 d" e"
AMR9read"uniaxial"AF"c"
1⟶0
write"uniaxial"AF"
0⟶1
Mn2Au
-
CuMnAs material system• Grown using molecular beam epitaxy on
GaAs and GaP substrates• Tetragonal Cu2Sb structure• Single crystal growth• Relaxed mosaic block structure on GaAs• Strained and more coherent on GaP
Wadley, Campion, Gallagher, Jungwirth et al Nat. Commun. (13) DOI: 10.1038/ncomms3322
Wadley, Campion, Jungwirth, Gallagher et al Sci. Rep. (5), 17079 (15)
Richard Campion – 9:30am Friday
-
Writing the stateJwrite ~ 107 A/cm2
CuMnAs (010)
CuMnAs (100)
Cu"
As"
Mn"Mn"
a"0
1
b"
1⟶0
AMR9read"biaxial"AF"
0⟶1
1
0
write"biaxial"AF"
“GMR”9read"uniaxial"AF"
1 0 d" e"
AMR9read"uniaxial"AF"
c"
1⟶0
write"uniaxial"AF"
0⟶1
-
Cu"
As"
Mn"Mn"
a"0
1
b"
1⟶0
AMR9read"biaxial"AF"
0⟶1
1
0
write"biaxial"AF"
“GMR”9read"uniaxial"AF"
1 0 d" e"
AMR9read"uniaxial"AF"
c"
1⟶0
write"uniaxial"AF"
0⟶1
Writing the state
Reading the stateJread ~ 104 A/cm2
Jwrite ~ 107 A/cm2
-
0 5 10 15 20
0.36
0.39
0.42
0.45
R
xy (W
)
Scan number
Set pulse along 12-6 Set pulse along 3-10
December 2014 – Very first measurements
Wadley, Howells
-
+
-
R T
Jwrite
Jwrite
Jread
30μm
[010
]
[100]
Electrical switching of antiferromagnetic CuMnAs
- Room-temperature-- Switching current density ~106 A cm-2 comparable to FM STT-MRAM devices
150 μm
Wadley, Olejnik, Jungwirth et al. Science 2016
-
AMR symmetry of the electrical read-out
transverse longitudinal
green line: probe current
-
Local inversion asymmetry & AF
Mn GaAs
!pcurr
LETTERS
PUBLISHED ONLINE: 2 AUGUST 2009 | DOI: 10.1038/NPHYS1362
Evidence for reversible control of magnetization ina ferromagnetic material by means of spin–orbitmagnetic fieldAlexandr Chernyshov1*, Mason Overby1*, Xinyu Liu2, Jacek K. Furdyna2, Yuli Lyanda-Geller1and Leonid P. Rokhinson1†
The current state of information technology accentuates thedichotomy between processing and storage of information,with logical operations carried out by charge-based devices andnon-volatile memory based on magnetic materials. The mainobstacle for a wider use of magnetic materials for informationprocessing is the lack of efficient control of magnetization.Reorientation of magnetic domains is conventionally carriedout by non-local external magnetic fields or by externallypolarized currents1–3. The efficiency of the latter approachis enhanced in materials where ferromagnetism is carrier-mediated4, because in such materials the control of carrierpolarization provides an alternative means for manipulatingthe orientation of magnetic domains. In some crystallineconductors, the charge current couples to the spins bymeans of intrinsic spin–orbit interactions, thus generatingnon-equilibrium electron spin polarization5–11 tunable by localelectric fields. Here, we show that magnetization can bereversibly manipulated by the spin–orbit-induced polarizationof carrier spins generated by the injection of unpolarizedcurrents. Specifically, we demonstrate domain rotation andhysteretic switching of magnetization between two orthogonaleasy axes in a model ferromagnetic semiconductor.
In crystalline materials with inversion asymmetry, intrinsicspin–orbit interactions couple the electron spinwith itsmomentumh̄k. The coupling is given by the Hamiltonian Hso = (h̄/2)�̂ ·(k),where h̄ is the reduced Planck constant and �̂ is the electronspin operator (for holes �̂ should be replaced by the total angularmomentum J). Electron states with different spin projection signson (k) are split in energy, analogous to the Zeeman splittingin an external magnetic field. In zinc-blende crystals such asGaAs there is a cubic Dresselhaus term12 D / k3, whereas strainintroduces a term " = C1"(kx ,�ky ,0) that is linear in k, where1" is the difference between strain in the ẑ and x̂, ŷ directions13.In wurtzite crystals or in multilayered materials with structuralinversion asymmetry, there also exists the Rashba term14 R,which has a different symmetry with respect to the direction of k,R =↵R(�ky ,kx ,0), where ẑ is along the axis of reduced symmetry.In the presence of an electric field, the electrons acquire an averagemomentum h̄1k(E), which leads to the generation of an electriccurrent j= ⇢̂�1E in the conductor, where ⇢̂ is the resistivity tensor.This current defines the preferential axis for spin precession h(j)i.As a result, a non-equilibrium current-induced spin polarizationhJEikh(j)i is generated, the magnitude of which hJ Ei dependson the strength of various mechanisms of momentum scattering
1Department of Physics and Birck Nanotechnology Center, Purdue University, West Lafayette, Indiana 47907, USA, 2Department of Physics, University ofNotre Dame, Notre Dame, Indiana 46556, USA. *These authors contributed equally to this work. †e-mail: leonid@purdue.edu.
jy jy
jxjx
6 µm M4
56
[110] [110]
[1 10] [1 10]
8
7
321
Heff
Heff
Heff
Heff
+I¬I
¬I
+I
[1 10]
[010]
[010]
[110]
[100]
[100]
Hϕ
ϕ
MH
a b
c d
Figure 1 | Layout of the device and symmetry of the spin–orbit fields.a, Atomic force micrograph of sample A with eight non-magnetic metalcontacts. b, Diagram of device orientation with respect to crystallographicaxes, with easy and hard magnetization axes marked with blue dashed andred dot–dash lines, respectively. Measured directions of Heff field areshown for different current directions. c,d, Orientation of effective magneticfield with respect to current direction for strain-induced (c) and Rashba (d)spin–orbit interactions. The current-induced Oersted field under thecontacts has the same symmetry as the Rashba field.
and spin relaxation5,15. This spin polarization has been measuredin non-magnetic semiconductors using optical7–9,11,16 and electronspin resonance17 techniques. It is convenient to parameterize hJEiin terms of an effective magnetic field Hso. Different contributionsto Hso have different current dependencies (/ j or j3), as wellas different symmetries with respect to the direction of j, asschematically shown in Fig. 1c,d, enabling one to distinguishbetween spin polarizations in different fields.
To investigate interactions between the spin–orbit-generatedmagnetic field and magnetic domains, we have chosen (Ga,Mn)As,a p-type ferromagnetic semiconductor18,19 with zinc-blende crys-talline structure similar to GaAs. Ferromagnetic interactions in thismaterial are carrier-mediated20,21. The total angular momentum ofthe holes J couples to the magnetic moment F of Mn ions by means
656 NATURE PHYSICS | VOL 5 | SEPTEMBER 2009 | www.nature.com/naturephysics
LETTERS
NATURE PHYSICS DOI: 10.1038/NPHYS1362
Figure 3 | Determination of current-induced effective spin–orbit magnetic field. a,b, Difference in switching angles for opposite current directions 1'(i)Has a function of I for sample A for different external fields H for orthogonal current directions. c, The measured effective field Heff =Hso ±HOe as a functionof average current density hji for sample A (triangles) and sample B (diamonds). d, Schematic diagram of the different angles involved in determining Heff:'H is the angle between current I and external magnetic field H; 1'H is the angle between total fields H+Heff(+I) and H+Heff(�I) and ✓ is the anglebetween I and Heff(+I).
0
0 200 400 600 800Time (s)
I
I I
IM
M M
M
¬101
I (m
A)
I (mA)
0
¬1.0 –0.5 0 0.5 1.0
5
¬5
Rxy
(Ω
)
Rxy
(Ω
)
0
5
¬5
0
Rxy
(Ω
)
¬5
5
45 90
a b
c
¬1 1〈 j 〉 µ 106 (A cm¬2) H
(°)ϕ
Figure 4 | Current-induced reversible magnetization switching. a, 'Hdependence of Rxy near the [010] ! [̄100] magnetization switching forI= ±0.7 mA in sample A for Ik[11̄0]. b, Rxy shows hysteresis as a functionof current for a fixed field H= 6 mT applied at 'H = 72�. c, Magnetizationswitches between the [010] and [̄100] directions when alternating ±1.0 mAcurrent pulses are applied. The pulses have 100 ms duration and are shownschematically above the data curve. Rxy is measured with I= 10 µA.
experiment. As for the magnitude of H so, for three-dimensionalJ = 3/2 holes we obtain
Hso(E)= eC1"g ⇤µB
(�38nh⌧h +18nl⌧l)217(nh +nl)
· (Ex ,�Ey ,0)
where E is the electric field, g ⇤ is the Luttinger Landé factor forholes, µB is the Bohr magneton and nh,l and ⌧h,l are densities andlifetimes for the heavy (h) and light (l) holes. Detailed derivation ofH so is given in the Supplementary Information. Using this result, weestimate dH so/dj = 0.6⇥10�9 T cm2 A�1 assuming nh =n�nl and⌧h =mh/(e2⇢n), where ⇢ is the resistivity measured experimentally,and using 1" = 10�3, n = 2⇥ 1020 cm�3. The agreement betweentheory and experiment is excellent. It is important to note, however,that we used GaAs band parameters25 mh = 0.4m0, where m0is the free electron mass, g ⇤ = 1.2 and C = 2.1 eVÅ. Althoughthe corresponding parameters for (Ga,Mn)As are not known, theuse of GaAs parameters seems reasonable. We note, for example,
that GaAs parameters adequately described tunnelling anisotropicmagnetoresistance in recent experiments26.
Finally, we demonstrate that the current-induced effective spin–orbit field H so is sufficient to reversibly manipulate the directionof magnetization. Figure 4a shows the 'H dependence of Rxy forsample A, showing the [010] ! [1̄00] magnetization switching. Ifwe fix H = 6mT at 'H = 72�, Rxy forms a hysteresis loop as currentis swept between ±1mA. Rxy is changing between ±5, indicatingthat M is switching between the [010] and [1̄00] directions. Short(100ms) 1mA current pulses of alternating polarity are sufficient topermanently rotate the direction of magnetization. The device thusperforms as a non-volatile memory cell, with two states encoded inthe magnetization direction, the direction being controlled by theunpolarized current passing through the device. The device can bepotentially operated as a four-state memory cell if both the [110]and [1̄10] directions can be used to inject current. We find thatwe can reversibly switch the magnetization with currents as low as0.5mA (current densities 7⇥ 105 A cm�2), an order of magnitudesmaller than by polarized current injection in ferromagneticmetals1–3, and just a few times larger than by externally polarizedcurrent injection in ferromagnetic semiconductors4.
MethodsThe (Ga,Mn)As wafers were grown by molecular beam epitaxy at 265 �C andsubsequently annealed at 280 �C for 1 h in nitrogen atmosphere. Sample Awas fabricated from a 15-nm-thick epilayer with 6% Mn, and sample B from a10-nm-thick epilayer with 7%Mn. Both wafers have a Curie temperature Tc ⇡80K.The devices were patterned into 6- and 10-µm-diameter circular islands to decreasedomain pinning. Cr/Zn/Au (5 nm/10 nm/300 nm) ohmic contacts were thermallyevaporated. All measurements were carried out in a variable-temperature cryostatat T = 40K for sample A and at 25K for sample B, well below the temperature of(Ga,Mn)As-specific cubic-to-uniaxial magnetic anisotropy transitions27, which hasbeen measured to be 60 and 50K for the two wafers. The temperature rise for thelargest currents used in the reported experiments wasmeasured to be
-
I
pulselength1ms
15ms
60ms
amplitude2×106 Acm-2
4×106 Acm-2
4.5×106 Acm-2
I
Jwrite pulselength5ms Jwrite amplitude4×106 Acm-2Variation of writing pulse length and amplitude
Domain-like saturation behaviourSee talk by J. Wunderlich and X. Marti – Thursday Schuler, Olejnik, Marti, PW, Jungwirth et al arxiv 16
Would like independent evidence of magnetic switching
-
http://www.spring8.or.jp
XMLD
(%)
XMLD
(a.u.)
-1
10
Experiment
Theory
Photon energy (eV)640 650
X-ray photoelectron emission microscopy
(XPEEM)
-
1000
900
800
700
600
500
400
300
200
100
0
10009008007006005004003002001000
1 µm
XMLD Mn Lh 120208-217
16oħw
X-ray photoelectron emission microscopy (XPEEM) Beamline I06, Diamond Light Source
V
15 um field-of-view
Different measurement geometry
-
1 µm
XMLD LH Mn Normalised 120279-2880 2 4 6 8 10 12 14 16
-0,23
-0,22
-0,21
-0,20
-0,19
-0,18
-0,17
-0,16
-0,15
Rxy1
(W)
Iteration
Rxy1
69mA current pulse
(6.1MA/cm2)
-
1 µm
XMLD LH Mn Normalised 120289-2980 2 4 6 8 10 12 14 16
-0,23
-0,22
-0,21
-0,20
-0,19
-0,18
-0,17
-0,16
-0,15
Rxy1
(W)
Iteration
Rxy1
69mA current pulse
(6.1MA/cm2)
-
1 µm
XMLD LH Mn Normalised 120299-3080 2 4 6 8 10 12 14 16
-0,23
-0,22
-0,21
-0,20
-0,19
-0,18
-0,17
-0,16
-0,15
Rxy1
(W)
Iteration
Rxy1
69mA current pulse
(6.1MA/cm2)
-
1 µm
XMLD LH Mn Normalised 120309-3180 2 4 6 8 10 12 14 16
-0,23
-0,22
-0,21
-0,20
-0,19
-0,18
-0,17
-0,16
-0,15
Rxy1
(W)
Iteration
Rxy1
69mA current pulse
(6.1MA/cm2)
-
1 µm
XMLD LH Mn Normalised 120319-3280 2 4 6 8 10 12 14 16
-0,23
-0,22
-0,21
-0,20
-0,19
-0,18
-0,17
-0,16
-0,15
Rxy1
(W)
Iteration
Rxy1
69mA current pulse
(6.1MA/cm2)
-
1 µm
XMLD LH Mn Normalised 120329-3380 2 4 6 8 10 12 14 16
-0,23
-0,22
-0,21
-0,20
-0,19
-0,18
-0,17
-0,16
-0,15
Rxy1
(W)
Iteration
Rxy1
69mA current pulse
(6.1MA/cm2)
-
1 µm
XMLD LH Mn Normalised 120339-3480 2 4 6 8 10 12 14 16
-0,23
-0,22
-0,21
-0,20
-0,19
-0,18
-0,17
-0,16
-0,15
Rxy1
(W)
Iteration
Rxy1
69mA current pulse
(6.1MA/cm2)
-
1 µm
XMLD LH Mn Normalised 120349-3580 2 4 6 8 10 12 14 16
-0,23
-0,22
-0,21
-0,20
-0,19
-0,18
-0,17
-0,16
-0,15
Rxy1
(W)
Iteration
Rxy1
69mA current pulse
(6.1MA/cm2)
-
1 µm
XMLD LH Mn Normalised 120359-3680 2 4 6 8 10 12 14 16
-0,23
-0,22
-0,21
-0,20
-0,19
-0,18
-0,17
-0,16
-0,15
Rxy1
(W)
Iteration
Rxy1
69mA current pulse
(6.1MA/cm2)
-
1 µm
XMLD LH Mn Normalised 120369-3780 2 4 6 8 10 12 14 16
-0,23
-0,22
-0,21
-0,20
-0,19
-0,18
-0,17
-0,16
-0,15
Rxy1
(W)
Iteration
Rxy1
69mA current pulse
(6.1MA/cm2)
-
1 µm
XMLD LH Mn Normalised 120379-3880 2 4 6 8 10 12 14 16
-0,23
-0,22
-0,21
-0,20
-0,19
-0,18
-0,17
-0,16
-0,15
Rxy1
(W)
Iteration
Rxy1
69mA current pulse
(6.1MA/cm2)
-
1 µm
XMLD LH Mn Normalised 120389-3980 2 4 6 8 10 12 14 16
-0,23
-0,22
-0,21
-0,20
-0,19
-0,18
-0,17
-0,16
-0,15
Rxy1
(W)
Iteration
Rxy1
69mA current pulse
(6.1MA/cm2)
-
1 µm
XMLD LH Mn Normalised 120399-4080 2 4 6 8 10 12 14 16
-0,23
-0,22
-0,21
-0,20
-0,19
-0,18
-0,17
-0,16
-0,15
Rxy1
(W)
Iteration
Rxy1
69mA current pulse
(6.1MA/cm2)
-
1 µm
XMLD LH Mn Normalised 120409-4180 2 4 6 8 10 12 14 16
-0,23
-0,22
-0,21
-0,20
-0,19
-0,18
-0,17
-0,16
-0,15
Rxy1
(W)
Iteration
Rxy1
69mA current pulse
(6.1MA/cm2)
-
1 µm
XMLD LH Mn Normalised 120419-4280 2 4 6 8 10 12 14 16
-0,23
-0,22
-0,21
-0,20
-0,19
-0,18
-0,17
-0,16
-0,15
Rxy1
(W)
Iteration
Rxy1
69mA current pulse
(6.1MA/cm2)
-
500nm x 500nm regions:
-
0.45
0.50
0.55
0.60
0 4 8 12 16-0.6
-0.3
0.0
0.3
0.6
Rxy
/ Rsq
(%)
pulse #
Average difference“1” = full switch from “black” to “white”
Grzybowski, Wadley, Edmonds, Gallagher, Jungwirth et alhttp://arxiv.org/abs/1607.08478
-
0.0 0.2 0.4 0.6 0.8 1.0
-4000
-2000
0
2000
4000
6.1 MA/cm2
5.9 MA/cm2
5.7 MA/cm2
0.0 0.2 0.4 0.6 0.8 1.0-4000
0
4000
8000
12000
16000
difference
Signal Signal
Num
ber o
f pix
els
Distribution functions
Grzybowski, Wadley, Edmonds, Gallagher, Jungwirth et alhttp://arxiv.org/abs/1607.08478
-
-1.0 -0.5 0.0 0.50.47
0.50
0.53
5.4 5.6 5.8 6.0
0.48
0.50
0.52
0.54
-0.6
-0.3
0.0
0.3
0.6X
MLD
J (MAcm-2)
R t/ R
sq(%
)
Rt / Rsq (%)
Extrapolating this relationship to full switching yields an expected AMR of 3.0 +/- 1%
Grzybowski, Wadley, Edmonds, Gallagher, Jungwirth et alhttp://arxiv.org/abs/1607.08478
-
VH3560nm CuMnAs on GaP(001)
VH2680nm CuMnAs on GaAs(001)
VH1250nm CuMnAs on GaP(001)
5µm
CuMnAs antiferromagnetic domain structures
5µm 10µm in-plane polarization
out of plane polarization
1 µm
x-rays
VH35_US1 132159-193
1 µm
VH35_US1 Mn XMLD Lv 132200-214
-
40 µm field-of-view
-400 -300 -200 -100 0 100 200 300 400
0.22
0.23
0.24
(I(E 1
) - I(E 2
))/(I(E 1
) + I(E 2
))
r (nm)
200nm
Thin CuMnAs ( 50nm): uniaxial anisotropy with 180o domain walls
CuMnAs domain structures
Uniaxial Domains Domain Wall ProfileDomain wall velocities limited only by magnon velocity (Gomonay, Jungwirth, Sinova PRL 16)
-
Optical detection of the spin axis (Poster T5)
Saidl, Nemec, PW et arxiv 16Switching using 250ps pulses (Olejnik, Schuler, Marti et al - ETH)
Marti, Olejnik, Schuler , et al.Talks by X. Marti and J. Wunderlich Thursday
-
• Incredible tool to study the domain behaviour and dynamics of antiferromagnets
• Switching with 250ps pulses achieved with very little optimisation
• Multi-level memory cell demonstrated• Picosecond switching expected for
coherent reorientation and domain wall motion
• Optical reading of the Neel vector demonstrated (Saidl, Nemec, PW et al)
• Insensitive to external fields
Outlook
1 µm
x-rays
VH35_US1 132159-193
0 20 40 60 80 100 120
−10
−5
0
5
10
writing pulse number
read
out s
igna
l (mΩ
)
0 10 20
−10
−5
0
5
10
signal count
readout signal (mΩ
)
0 20 40 60 80 100 120
−10
−5
0
5
10
writing pulse number
read
out s
igna
l (mΩ
)
0 10 20
−10
−5
0
5
10
signal count
readout signal (mΩ
)
top related