DNP in Quantum Computing · DNP in Quantum Computing . Eisuke Abe . Spintronics Research Center,...
Transcript of DNP in Quantum Computing · DNP in Quantum Computing . Eisuke Abe . Spintronics Research Center,...
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DNP in Quantum Computing
Eisuke Abe Spintronics Research Center, Keio University
2017.08.25 Future of Hyper-Polarized Nuclear Spins
@IPR, Osaka
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DNP in quantum computing
• Molecule – Pseudo-pure state – Algorithmic cooling
• Phosphorus donor in silicon – ENDOR – Single nuclear spin under control
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1. A scalable physical system with well characterized qubits
2. The ability to initialize the state of the qubits to a simple fiducial state, such as |000...⟩
3. Long relevant decoherence times, much longer than the gate operation time
4. A “universal” set of quantum gates
5. A qubit-specific measurement capability
DiVincenzo’s criteria
Fortschr. Phys. 48, 771 (2000) DiVincenzo
(©RWTH Aachen U.)
Spin-½
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1. A scalable physical system with well characterized qubits
2. The ability to initialize the state of the qubits to a simple fiducial state, such as |000...⟩ → 100% DNP
3. Long relevant decoherence times, much longer than the gate operation time
4. A “universal” set of quantum gates
5. A qubit-specific measurement capability
DiVincenzo’s criteria
Fortschr. Phys. 48, 771 (2000) DiVincenzo
(©RWTH Aachen U.)
T2
Arbitrary unitary operations
Spin-½
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A molecule as a quantum computer
C C
19F Br
19F 19F
Bromotrifluoroethylene
Qubit A
Qubit B
Qubit C
νA,B,C ~ 470 MHz @B0 = 11.7 T
JAB = −122.1 Hz
JBC = 53.8 Hz
JAC = 75.0 Hz
νA − νB = 13.2 kHz
νC − νA = 9.5 kHz
𝐻mol = − � 𝜈𝑖𝐼𝑧𝑖
𝑖
+ � 𝐽𝑖𝑖𝐼𝑧𝑖 𝐼𝑧
𝑖
𝑖<𝑖
Hamiltonian
|0⟩ |1⟩
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A molecule as a quantum computer
C C
19F Br
19F 19F
Bromotrifluoroethylene
Qubit A
Qubit B
Qubit C
νA,B,C ~ 470 MHz @B0 = 11.7 T
JAB = −122.1 Hz
JBC = 53.8 Hz
JAC = 75.0 Hz
νA − νB = 13.2 kHz
νC − νA = 9.5 kHz
𝐻mol = − � 𝜈𝑖𝐼𝑧𝑖
𝑖
+ � 𝐽𝑖𝑖𝐼𝑧𝑖 𝐼𝑧
𝑖
𝑖<𝑖
Hamiltonian
|001⟩ |010⟩ |100⟩
|011⟩ |101⟩ |110⟩
|111⟩
|ABC⟩ = |000⟩
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DiVincenzo’s criteria for a molecule
1. Qubits: Nuclear spins in a molecule → (ABC)n polymer*
2. Initialization: “Measure and flip”
3. Coherence: Good
4. Quantum gates: RF control and spin-spin interaction (always on)
5. Measurement:
*Science 261, 1569 (1993) Lloyd
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Molecules as a quantum computer
Thermal equilibrium ensemble
(> 1018 identical molecules)
𝐻mol = − � 𝜈𝑖𝐼𝑧𝑖
𝑖
+ � 𝐽𝑖𝑖𝐼𝑧𝑖 𝐼𝑧
𝑖
𝑖<𝑖
Hamiltonian
Ensemble of molecules can be measured, but then how to initialize them?
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Spin system in thermal equilibrium
𝜌eq =1𝑍 exp −
𝐻mol𝑘B𝑇 ≈
𝟏𝑛2𝑛 +
𝜖2𝑛 𝜌𝑛
𝜖 =500 MHz2 × 300 K
≈ 10−5
𝜌𝑛 = � 𝜎𝑧𝑖
𝑖
Silent majority (no signal, no time evolution)
𝐻mol = − � 𝜈𝑖𝐼𝑧𝑖
𝑖
+ � 𝐽𝑖𝑖𝐼𝑧𝑖 𝐼𝑧
𝑖
𝑖<𝑖
≈ −𝜈0 � 𝐼𝑧𝑖
𝑖
Hamiltonian
Density matrix
𝜌2 = 𝜎𝑧 ⊗ 𝟏1 + 𝟏1 ⊗ 𝜎𝑧
𝜌1 = 𝜎𝑧
𝜌3 = 𝜎𝑧 ⊗ 𝟏1 ⊗ 𝟏1 + 𝟏1 ⊗ 𝜎𝑧 ⊗ 𝟏1 + 𝟏1 ⊗ 𝟏1 ⊗ 𝜎𝑧
𝑑 𝜌2 =
200
−2
𝑑 𝜌3 =
311
−11
−1−1−3
𝑑 𝜌1 = 1−1
Simplified notation of ρn
|0⟩ |1⟩
|01⟩ |10⟩ |11⟩
|00⟩
|001⟩ |010⟩ |011⟩
|000⟩
|101⟩ |110⟩ |111⟩
|100⟩
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Initialization
𝜌eq =𝟏𝑛
2𝑛 +𝜖
2𝑛 𝜌𝑛
Thermal equilibrium
𝑑 𝜌pure =
10⋮0
𝜌pure = 000 … ⟨000 … |
100% DNP
𝜌pps = 1 − 𝛼𝟏𝑛
2𝑛 + 𝛼𝜌pure
Pseudo-pure state
Temporal averaging
Spatial averaging
Logical labeling
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Science 275, 350 (1997) Gershenfeld & Chuang
(©MIT)
PNAS 94, 1634 (1997) Cory et al.
(©IQC, U. Waterloo)
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Nature 393, 344 (1998) Jones et al.
(Received 6 Mar.; accepted 23 Apr.; published 28 May)
(Received 16 Jan.; accepted 22 Apr.; published 1 Aug.)
J. Chem. Phys. 109, 1648 (1998) Jones et al.
Nature 393, 143 (1998) Chuang et al.
(Received 21 Jan.; accepted 18 Mar.; published 14 May)
Phys. Rev. Lett. 80, 3408 (1998) Chuang et al.
(Received 21 Nov. ’97; published 13 Apr.)
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Nature 414, 883 (2001) Vandersypen et al.
(©QuTech, TU Delft) (©IBM)
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DiVincenzo’s criteria for NMR QC
1. Qubits: Nuclear spins in molecules → (ABC)n polymers*
2. Initialization: DNP, pseudo-pure state, algorithmic cooling**
3. Coherence: Good
4. Quantum gates: RF control and spin-spin interaction (always on)
5. Measurement: Ensemble-averaged signals
*Science 261, 1569 (1993) Lloyd
**Proc. 31st Annu. ACM Symp. Theory Compt. p.322 (1999) Schulman & Vazirani
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Logical labeling
𝑑 𝜌3 =
311
−11
−1−1−3
Case study: n = 3
|001⟩ |010⟩ |100⟩
|011⟩ |101⟩ |110⟩
|111⟩
|ABC⟩ = |000⟩ +1 −1
ρ3
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Logical labeling
𝑉 =
1 0 0 0 0 0 0 00 0 0 0 0 1 0 00 0 0 0 0 0 1 00 0 0 1 0 0 0 00 0 0 0 1 0 0 00 1 0 0 0 0 0 00 0 1 0 0 0 0 00 0 0 0 0 0 0 1
𝑑 𝜌3 =
311
−11
−1−1−3
Case study: n = 3
Unitary operator for LL3
A
B
C
A⊕B
A⊕B⊕C
B
C
Flip A if BC = 01 or 10
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Logical labeling
𝑉 =
1 0 0 0 0 0 0 00 0 0 0 0 1 0 00 0 0 0 0 0 1 00 0 0 1 0 0 0 00 0 0 0 1 0 0 00 1 0 0 0 0 0 00 0 1 0 0 0 0 00 0 0 0 0 0 0 1
𝑑 𝜌3 =
311
−11
−1−1−3
Case study: n = 3
Unitary operator for LL3
|001⟩ |010⟩ |100⟩
|011⟩ |101⟩ |110⟩
|111⟩
|ABC⟩ = |000⟩ +1 −1
ρ3
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Logical labeling
𝑉 =
1 0 0 0 0 0 0 00 0 0 0 0 1 0 00 0 0 0 0 0 1 00 0 0 1 0 0 0 00 0 0 0 1 0 0 00 1 0 0 0 0 0 00 0 1 0 0 0 0 00 0 0 0 0 0 0 1
𝑑 𝜌3 =
311
−11
−1−1−3
𝑑 𝑉𝜌3𝑉† =
3−1−1−1111
−3
Case study: n = 3
Unitary operator for LL3
|001⟩ |010⟩ |100⟩
|011⟩ |101⟩ |110⟩
|111⟩
|ABC⟩ = |000⟩ +1 −1
Vρ3V†
≈
1000
Sub-ensemble of BC labeled by A = 0 is pseudo-pure
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𝐻 𝑝 = −𝑝 log2 𝑝 − 1 − 𝑝 log2(1 − 𝑝) Shannon entropy
𝑁cold𝑁 = 1 − 𝐻
1 + 𝜖02
Algorithmic cooling
Proc. 31st Annu. ACM Symp. Theory Compt. p.322 (1999) Schulman & Vazirani
Hot Cold
N-qubit array with polarization ϵ0
Redistribute entropy
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Algorithmic cooling
𝑁cold𝑁 = 1 − 𝐻
1 + 𝜖02
Proc. 31st Annu. ACM Symp. Theory Compt. p.322 (1999) Schulman & Vazirani
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Heat bath algorithmic cooling
Qubit array Bath Refresh
Hot Cold
PNAS 99, 3388 (2002) Boykin at al.
Iterative procedure to compress and pump out entropy from Qubits to Heat Bath
Colder than Bath
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HBAC: Partner pairing algorithm • R: Thermalize R by contacting with Bath with polarization ϵb • C1: Swap A and R (|001⟩↔|100⟩, |011⟩↔|110⟩) • C2: Swap B and R (|001⟩↔|010⟩, |101⟩↔|110⟩) • C3: Swap |011⟩ and |100⟩
A
B
R
R C1 R C2 C3 R Bath
Phys. Rev. Lett. 94, 120501 (2005) Schulman at al.
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HBAC: 1st round
𝑑 𝜌I =18
11111111
𝑑 𝜌I𝑅 =
18
1 + 𝜖b1 − 𝜖b1 + 𝜖b1 − 𝜖b1 + 𝜖b1 − 𝜖b1 + 𝜖b1 − 𝜖b
R
𝑑 𝐶1𝜌I𝑅𝐶1
† =18
1 + 𝜖b1 + 𝜖b1 + 𝜖b1 + 𝜖b1 − 𝜖b1 − 𝜖b1 − 𝜖b1 − 𝜖b
C1
p(A): 0 → ϵb p(B): 0 → 0 p(R): 0 → 0
A
B
R
R C1 R C2 C3 R Bath
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HBAC: 1st round
R 𝑑 (𝐶1𝜌I
𝑅𝐶1†)𝑅 =
18
1 + 𝜖b2
1 − 𝜖b2
1 + 𝜖b2
1 − 𝜖b2
1 − 𝜖b2
1 − 𝜖b2
1 − 𝜖b2
1 − 𝜖b2
C2
𝑑 𝐶2(𝐶1𝜌I𝑅𝐶1
†)𝑅𝐶2† =
18
1 + 𝜖b2
1 + 𝜖b2
1 − 𝜖b2
1 − 𝜖b2
1 − 𝜖b2
1 − 𝜖b2
1 − 𝜖b2
1 − 𝜖b2
p(A): ϵb → ϵb p(B): 0 → ϵb p(R): 0 → 0
A
B
R
R C1 R C2 C3 R Bath
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HBAC: 1st round
R C3 𝑑 𝐶3(𝐶2(𝐶1𝜌I
𝑅𝐶1†)𝑅𝐶2
†)𝑅𝐶3† =
18
1 + 𝜖b3
1 + 𝜖b2(1 − 𝜖b)
1 + 𝜖b2(1 − 𝜖b)
1 + 𝜖b2(1 − 𝜖b)
(1 + 𝜖b) 1 − 𝜖b2
(1 + 𝜖b) 1 − 𝜖b2
(1 + 𝜖b) 1 − 𝜖b2
1 − 𝜖b3
p(A): ϵb → 1.5ϵb − 0.5ϵb3
p(B): ϵb → 0.5ϵb + 0.5ϵb
3 p(R): 0 → 0.5ϵb + 0.5ϵb
3
A
B
R
R C1 R C2 C3 R Bath
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HBAC: Multiple rounds
A
B
R
R C1 R C2 C3 R Bath
m
p(A): 1.5ϵb − 0.5ϵb3 → ...
p(B): 0.5ϵb + 0.5ϵb
3 → ... p(R): 0.5ϵb + 0.5ϵb
3 → ϵb
R
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HBAC: Multiple rounds
A
B
R
R C1 R C2 C3 R Bath
m
p(A) → 2ϵb (?)
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HBAC: Achievable polarization
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HBAC: Achievable polarization
𝑝 A max = 1 −2
𝑒2𝑛−2 ln(1+𝜖𝑏1−𝜖𝑏
) + 1
Phys. Rev. Lett. 116, 170501 (2016) Rodriguez-Briones & Laflamme
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Algorithmic cooling
𝑁cold𝑁 = 1 − 𝐻
1 + 𝜖02
Proc. 31st Annu. ACM Symp. Theory Compt. p.322 (1999) Schulman & Vazirani
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HBAC: Experiments
Phys. Rev. Lett. 100, 140501 (2008) Ryan et al.
Nature 438, 470 (2005) Baugh et al.
A
Bath
R
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Scalable approaches
• Large DNP on ensemble – Hard...
• HBAC on ensemble – Harder...?
• Measure-and-flip on individual spins – Hardest...??
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Scalable approaches
• Large DNP on ensemble – Hard...
• HBAC on ensemble – Harder...?
• Measure-and-flip on individual spins – Hardest...??
In a few rare systems (Si:P, NV...), we can.
The technique used is closely related to DNP.
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Phosphorus donor in silicon
31P
29Si
e–
28/30Si
28Si : 29Si (I = ½) : 30Si = 92.2% : 4.7% : 3.1%
III (13)
IV (14)
V (15)
B C N Al Si P Ga Ge As
31P (I = ½) = 100%
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Phosphorus donor in silicon
31P
e–
Isotopically purified 28Si (99.995%)
III (13)
IV (14)
V (15)
B C N Al Si P Ga Ge As
31P (I = ½) = 100%
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Energy levels of Si:P
|↓⇓⟩
|e,n⟩ = |↑⇓⟩ |↑⇑⟩
|↓⇑⟩
νe1 νe2
νn1
νn2
𝐻0 = 𝛾e𝐵0𝑆𝑧 − 𝛾P𝐵0𝐼𝑧 + 𝑎0𝑆𝑧𝐼𝑧
γe = 27.97 GHz/T
γP = 17.23 MHz/T
a0 = 117.53 MHz
B0 ~ 350 mT (X-band)
νe1 = γeB0 − a0 /2 νe2 = γeB0 + a0 /2
νn1 = a0 /2 + γPB0 νn2 = a0 /2 − γPB0
a0/γe = 4.2 mT
Field-sweep ESR spectrum
Hamiltonian
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Phys. Rev. 103, 500 (1956) Feher (©R.A. Icaacson)
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Phys. Rev. 103, 501 (1956) Feher & Gere
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Phys. Rev. 103, 501 (1956) Feher & Gere (π-pulse on e-spin)
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Phys. Rev. 103, 501 (1956) Feher & Gere (π-pulse on e-spin) (π-pulse on n-spin)
Electron Nuclear DOuble Resonance
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ENDOR & parity non-conservation
Annu. Rev. Biophys. Biomol. Struct. 31, 1 (2002) Feher
[…] In the fall of 1956, I gave a colloquium at Columbia University on the nuclear polarization scheme. After the colloquium, C. S. Wu and T. D. Lee excitedly tried to persuade me to measure the asymmetry of β-decay in a polarized sample of donor nuclei in silicon. T. D. Lee and C. N. Yang had circulated a preprint of an article in which they suggested that one of the conservation laws of physics, parity, did not hold in the case of weak interactions. [...] I listened politely with limited interest and promised them I would get to it as soon as I finished the ENDOR experiments [...]
C. S. Wu (©AIP Emilio Segre
Visual Archives)
T. D. Lee (©Nobel Foundation)
C. N. Yang (©Nobel Foundation)
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ENDOR & parity non-conservation […] In the fall of 1956, I gave a colloquium at Columbia University on the nuclear polarization scheme. After the colloquium, C. S. Wu and T. D. Lee excitedly tried to persuade me to measure the asymmetry of β-decay in a polarized sample of donor nuclei in silicon. T. D. Lee and C. N. Yang had circulated a preprint of an article in which they suggested that one of the conservation laws of physics, parity, did not hold in the case of weak interactions. [...] I listened politely with limited interest and promised them I would get to it as soon as I finished the ENDOR experiments [...] After finishing these at the end of 1956, I took an extended skiing vacation in the West. On the way back I stopped off at the University of Pittsburgh where I gave a colloquium [...] At the conclusion, I mentioned that I would like to test Lee & Yang’s hypothesis of parity nonconservation. [...] it felt as if the temperature of the room had dropped by 10 degrees. Finally, G. C. Wick said, "But don’t you know that parity nonconservation has already been proven by several groups?". Of course, I did not know; I had been skiing for a month.
Annu. Rev. Biophys. Biomol. Struct. 31, 1 (2002) Feher
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Science 270, 255 (1995) DiVincenzo
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Nature 455, 1085 (2008) Morton et al.
Transfer to e-spin
νe1
π/2 π Echo
π π π
νn2 τ τ π π π
Transfer to n-spin
(©UCL)
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Phys. Rev. B 93, 161202 (2016) Petersen et al.
Phys. Rev. B 82, 121201 (2010) Abe et al.
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Cf. Nature 393, 143 (1998) Chuang et al. “Experimental realization of a quantum algorithm”
(©JQI)
Nature 393, 133 (1998) Kane
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(©UNSW)
Nature 497, 687 (2010) Morello et al.
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Nature 497, 687 (2010) Morello et al.
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Nature 489, 541 (2012) Pla et al.
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Nature 496, 334 (2013) Pla et al.
• νe1,2 = γeB0 ∓ a0 /2 are dependent on the n-spin state • ESR does not change the n-spin state → Quantum nondemolition (QND) measurement
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Nature 496, 334 (2013) Pla et al.
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Single nuclear spin under control
Nature 496, 334 (2013) Pla et al.
Rabi Ramsey
Hahn echo
Qubit array
DiVincenzo’s criteria
Initialization
Coherence
Quantum gates
Measurement
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Ensemble to single, single to... Ensemble (copy) of identical spins, global control
Single spin, local control Multiple single-spins, individual controls
Scalable quantum computer
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DNP in quantum computing
• Molecule – Preparation of pseudo-pure states costs resources
exponentially, deeming NMR QC non-scalable. – HBAC is a quantum information theoretic approach to
DNP.
• Phosphorus donor in silicon – Pulsed ENDOR, a well-established technique for
population transfer, is a quantum gate operation. – Single nuclear spins can be read out non-destructively.
The real challenge is how to scale up the system.