Holonomic Quantum Computing

1. Holonomic QuantumComputing Mikio Nakahara Department of Physics, Kinki University, Japan in collaboration with A. Niskanen, M. Salomaa, S. Tanimura, D. Hayashi, Y. Kondo, Y. Ota, M. Bando HQC @ Tehran, 4 Jan, 2009

2. Plan of the talk • 1. What is holonomy (anholonomy)? • 2. Wilczek-Zee holonomy • 3. Isoholonomic Problem • 4. Multi-Partite Construction • 5. Physical Realizations • 5. Summary and Discussions HQC @ Tehran, 4 Jan, 2009

3. 1. What is holonomy?1.1 Holonomy holonomy HQC @ Tehran, 4 Jan, 2009

4. Holonomy in Mechanics 1 Deformation with Angular Momentum Conserved Shape = Control Manifold HQC @ Tehran, 4 Jan, 2009

5. Holonomy in Mechanics 2 HQC @ Tehran, 4 Jan, 2009

6. 1.2 Isoholonomic Problem HQC @ Tehran, 4 Jan, 2009

7. HQC @ Tehran, 4 Jan, 2009

8. 1.3 Holonomic Quantum Computing • Change of Hamiltonian adiabatically along a loop in the control manifold produces the Wilczek-Zee holonomy. Unitary matrices necessary for quantum computing is implemented as holonomies in HQC (Zanardi & Rasetti, 1999). • Timing does not matter. Only the geometrical image of the loop in the control manifold is important. • We are interested in the isoholonomic problem, given a unitary matrix U. HQC @ Tehran, 4 Jan, 2009

9. Plan of the talk • 1. What is holonomy (anholonomy)? • 2. Wilczek-Zee holonomy • 3. Isoholonomic Problem • 4. Multi-Partite Construction • 5. Physical Realizations • 5. Summary and Discussions HQC @ Tehran, 4 Jan, 2009

10. 2.1 Berry’s Phase HQC @ Tehran, 4 Jan, 2009

11. HQC @ Tehran, 4 Jan, 2009

12. Wilczek-Zee Holonomy 1 HQC @ Tehran, 4 Jan, 2009

13. Wilczek-Zee Holonomy 2 HQC @ Tehran, 4 Jan, 2009

14. Derivation of WZ holonomy HQC @ Tehran, 4 Jan, 2009

15. HQC @ Tehran, 4 Jan, 2009

16. Wilczek-Zee Holonomy 3 HQC @ Tehran, 4 Jan, 2009

17. Plan of the talk • 1. What is holonomy (anholonomy)? • 2. Wilczek-Zee holonomy • 3. Isoholonomic Problem • 4. Multi-Partite Construction • 5. Physical Realizations • 5. Summary and Discussions HQC @ Tehran, 4 Jan, 2009

18. 3. Isoholonomic Problem HQC @ Tehran, 4 Jan, 2009

19. Motivation for Studying the Isoholonomic Problem in HQC • Adiabaticity demands that the control parameters be changed as slowly as possible. • On the other hand, operation time should be as short as possible to fight against decoherence. • Therefore we should employ the shortest path in the control parameter space to compromise between two conflicting requirements. HQC @ Tehran, 4 Jan, 2009

20. 3.1 Geometrical Setting HQC @ Tehran, 4 Jan, 2009

21. HQC @ Tehran, 4 Jan, 2009

22. HQC @ Tehran, 4 Jan, 2009

23. 3.2Solution of Isoholonomic Problem HQC @ Tehran, 4 Jan, 2009

24. Solution of Isoholonomic Problem 2 HQC @ Tehran, 4 Jan, 2009

25. Solution of Isoholonomic Problem 3 HQC @ Tehran, 4 Jan, 2009

26. Solution of Isoholonomic Problem 4 HQC @ Tehran, 4 Jan, 2009

27. Inverse Problem HQC @ Tehran, 4 Jan, 2009

28. Solution to U(g) Isoholonomic Problem HQC @ Tehran, 4 Jan, 2009

29. HQC @ Tehran, 4 Jan, 2009

30. 3.3 Applications to HQC HQC @ Tehran, 4 Jan, 2009

31. HQC @ Tehran, 4 Jan, 2009

32. CNOT gate HQC @ Tehran, 4 Jan, 2009

33. DFT2 gate HQC @ Tehran, 4 Jan, 2009

34. Plan of the talk • 1. What is holonomy (anholonomy)? • 2. Wilczek-Zee holonomy • 3. Isoholonomic Problem • 4. Multi-Partite Construction • 5. Physical Realizations • 5. Summary and Discussions HQC @ Tehran, 4 Jan, 2009

35. 4. Multi-Partite Construction • It is not likely to find a quantum system with 2n-fold degenerate ground state. 2100~1030! • Need to find multipartite implementation and make use of entanglement to save computational resources. • A. O. Niskanen, M. Nakahara and M. M. Salomaa, Phys. Rev. A 67, 012319 (2003) HQC @ Tehran, 4 Jan, 2009

36. 4.1 Model Hamiltonian HQC @ Tehran, 4 Jan, 2009

37. HQC @ Tehran, 4 Jan, 2009

38. HQC @ Tehran, 4 Jan, 2009

39. HQC @ Tehran, 4 Jan, 2009

40. Plan of the talk • 1. What is holonomy (anholonomy)? • 2. Wilczek-Zee holonomy • 3. Isoholonomic Problem • 4. Multi-Partite Construction • 5. Physical Realizations • 5. Summary and Discussions HQC @ Tehran, 4 Jan, 2009

41. 5. Physical Implementations of HQC HQC @ Tehran, 4 Jan, 2009

42. Example; Isospectral deformation of NMR (Ising) Hamiltonian HQC @ Tehran, 4 Jan, 2009

43. 0 HQC @ Tehran, 4 Jan, 2009

44. WZ connection HQC @ Tehran, 4 Jan, 2009

45. Example: Hadamard Gate HQC @ Tehran, 4 Jan, 2009

46. 2-qubit gates HQC @ Tehran, 4 Jan, 2009

47. HQC @ Tehran, 4 Jan, 2009

48. Plan of the talk • 1. What is holonomy (anholonomy)? • 2. Wilczek-Zee holonomy • 3. Isoholonomic Problem • 4. Multi-Partite Construction • 5. Physical Realizations • 6. Summary HQC @ Tehran, 4 Jan, 2009

49. 7. Summary HQC @ Tehran, 4 Jan, 2009

50. Working/studying in my lab. http://alice.math.kindai.ac.jp • Postdoc (April, 2009~ ) salary $ 2,800/month must be younger than 35. • Senior Scientist (April, 2009~ ) salary $2,600/month for 5 working days/week $3,200/month for 6 working days/week must be older than 35. • PhD student, RA salary $13,000/year Tuition fee $10,000/year. (maybe waived) (Almost unlimited research funding for theorists.) HQC @ Tehran, 4 Jan, 2009