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Department of Electronics Nanoelectronics 18 Atsufumi Hirohata 12:00 Wednesday, 11/March/2015 (P/L 006)

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Presentation on theme: "Department of Electronics Nanoelectronics 18 Atsufumi Hirohata 12:00 Wednesday, 11/March/2015 (P/L 006)"— Presentation transcript:

1 Department of Electronics Nanoelectronics 18 Atsufumi Hirohata 12:00 Wednesday, 11/March/2015 (P/L 006)

2 Quick Review over the Last Lecture Carbon nanomaterials : ( Diamond ) : ( Graphene ) : ( Fullerene ) : ( Carbon nanotube ) :

3 Contents of Nanoelectonics I. Introduction to Nanoelectronics (01) 01 Micro- or nano-electronics ? II. Electromagnetism (02 & 03) 02 Maxwell equations 03 Scholar and vector potentials III. Basics of quantum mechanics (04 ~ 06) 04 History of quantum mechanics 1 05 History of quantum mechanics 2 06 Schrödinger equation IV. Applications of quantum mechanics (07, 10, 11, 13 & 14) 07 Quantum well 10 Harmonic oscillator 11 Magnetic spin 13 Quantum statistics 1 14 Quantum statistics 2 V. Nanodevices (08, 09, 12, 15 ~ 18) 08 Tunnelling nanodevices 09 Nanomeasurements 12 Spintronic nanodevices 15 Low-dimensional nanodevices 16 Optical nanodevices 17 Organic nanodevices 18 Quantum computation

4 18 Quantum Computation Public key cryptosystem Traveling salesman problem Qubits

5 Public Key Cryptosystem In 1976, B. Whitfield Diffie and Martin E. Hellman proposed public key cryptosystem. * http://www.wikipedia.org/ RSA (Ronald L. Rivest, Adi Shamir and Leonard M. Adleman) cryptography developed in 1977. Conventional cryptography ** http://www.maitou.gr.jp/rsa/ Use the same key. encryption decryption key A encryption decryption key A Public key for encryption Individual secure key No one can decrypt with using key A. 256-digit factorization : 10M years with IBM Blue Gene BUT ~ 10 sec with a quantum computer !

6 Traveling Salesman Problem As an example of non-deterministic polynomial (NP) complete problems : * http://www.wikipedia.org/

7 Bee Can Solve a Traveling Salesman Problem

8 History of Quantum Computation In 1956, Richard P. Feynman told : * http://www.wikipedia.org/ ** K. Nakamura, SX World 26, Autumn (2000). “There’s plenty of room at the bottom.” In 1980, Paul Benioff predicted : calculations without energy consumption  quantum computation In 1985, David Deutch introduced quantum turing machine. Turing machine : Input tape with letters In 1994, Peter W. Shor formulated factorization algorithm. In 1996, L. K. Grover developed database algorithm. For qubits : 1 tape insertion  2 n calculations achieved  parallel calculation

9 Technical Requirements for a Quantum Computer 5 major technical obstacles for the realisation of a quantum computer : * Array of necessary numbers of qubits Factorization of a 200-digit integer  1000 qubits Initialisation of qubits Long coherence time * S. Kawabata, NRI Res. Rep. 1, 4 (2004). Q-factor = coherence time / 1 gate time > 10,000 Operationability of a quantum logic gate 1-qubit unitary transformation + 2-qubit CNOT gate Observability of qubits

10 Potential Qubits Major potential qubits for quantum computation : * K. Goser, P. Glösekötter and J. Dienstuhl, Nanoelectronics and Nanosystems (Springer, Berlin, 2004). ** S. Kawabata, NRI Res. Rep. 1, 4 (2004). QubitsQ-factorPresent recordsNotes Nuclear magnetic resonance (NMR) 10 9 7 qubits (algorithm)Maximum 10 qubits Ion-trap10 12 2 qubits (algorithm)Difficult to integrate Superconducting charge10 4 2 qubits (control NOT) Superconducting flux10 3 1 qubit (unitary transformation) Exciton (electron-hole pair)10 3 2 qubits (control NOT) Electron charge10 5 1 qubit (unitary transformation) Electron spin10 4 Nuclear spin10 9

11 NMR Qubits 5-qubit operation at 215 Hz was achieved : * L. M. K. Vandersypen et al., Phys. Rev. Lett. 85, 5452 (2000). Maximum 10 qubits...

12 Exciton Qubits in Solid States InAs quantum dots buried in GaAs act as qubits : * K. Goshima et al., Appl. Phys. Lett. 87, 253110 (2005). dot B dot A exciton b exciton a 2-qubit state “ 1 1 ”

13 Spin Qubits in Solid States In 1998, Daniel Loss and David P. DiVincenzo proposed spin qubits : Qubits : electron spins embedded in quantum dots ** http://www.rle.mit.edu/60th/speakers.htm * http://theorie5.physik.unibas.ch/loss/ *** http://www.wikipedia.org/ Unitary transformation : application of an external magnetic field Control NOT : Heisenberg interaction between neighbouring spins

14 Nuclear Spin Qubits in Solid States In 1998, Bruce E. Kane proposed nuclear spin qubits doped in Si : Advantage : very long coherence time (10 6 sec at ~100 mK) * D. P. DiVincenzo, Nature 393, 113 (1998). By applying gate A voltage, P + and an electron in an A gate couples  polarises. J gate controls the interaction between the neighbouring nuclear spins.

15 Superconducting Qubits in Solid States In 1999, first demonstration of 1-qubit unitary transformation in solid states : * Y. Nakamura et al., Nature 398, 876 (1999); I. Chiorescu et al., Science 299, 1869 (2003). Rabi oscillation : Proof of quantum entanglement

16 Other Superconducting Qubits * http://www3.fed.or.jp/salon/houkoku/re_ryoushi.pdf

17 Roadmap for Quantum Computation * http://www3.fed.or.jp/salon/2ndryo/2ndryo_houkokusho_.pdf http://www.dwavesys.com/ http://googleresearch.blogspot.jp/2013/05/launching-quantum-artificial.html

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