1. Quantum Information Science
Atomic-Molecular
Optical Physics
Condensed
Matter Physics
Exotic Quantum
States of Matter!
J. Preskill
3 Dec. 2008

2. Quantum Information Science
Planck
Quantum Information Science
Quantum physics, information theory, and computer science are among the crowning intellectual achievements of the 20th century.
Quantum information science is an emerging synthesis of these themes, which is providing important insights into fundamental issues at the interface of computation and physical science, and may guide the way to revolutionary technological advances.
Turing
Shannon

3. Information
is encoded in the state of a physical system.

4. Information
is encoded in the state of a
quantum
system.

5. Put
to work!

6. Quantum Entanglement classically correlated socks
quantumly correlated photons
There is just one way to look at a classical bit (like the color of my sock), but there are complementary ways to observe a quantum bit (like the polarization of a single photon). Thus correlations among qubits are richer and much more interesting than correlations among classical bits.
A quantum system with two parts is entangled when its joint state is more definite and less random than the state of each part by itself. Looking at the parts one at a time, you can learn everything about a pair of socks, but not about a pair of qubits!

7. The quantum correlations of many entangled qubits cannot be easily described in terms of ordinary classical information. To give a complete classical description of one typical state of just a few hundred qubits would require more bits than the number of atoms in the visible universe!
It will never be possible, even in principle to write down such a description.

8. We can’t even hope to describe the state of a few hundred qubits in terms of classical bits.
As Feynman first suggested in 1981, a computer that operates on qubits rather than bits (a quantum computer) can perform tasks that are beyond the capability of any conceivable digital computer!

9. ? ? = ´ Finding Prime Factors = ? ?
An example of a problem that is hard for today’s supercomputers: finding the factors of a large composite number. Factoring e.g. 500 digit numbers will be intractable for classical computers even far into the future.

10. = ´ Finding Prime Factors 1807082088687 4048059516561 6440590556627 =
But for a quantum computer, factoring is not much harder than multiplication! The boundary between the problems that are “hard” and the problems that are “easy” is different in a quantum world than a classical world.

11. John Preskill
Physics
Jeff Kimble
Physics
Alexei Kitaev
Physics and Computer Science
Gil Refael
Physics
Leonard Schulman
Computer Science
CENTER FOR
THE PHYSICS OF INFORMATION

12. Former IQI Postdocs now in faculty positions elsewhere
Hallgren
Shi
Doherty
Nayak
Geremia
Childs
Bacon
Duan
Hayden
Terhal
Vidal
Raussendorf
Bose
Leung
Bravyi
Verstraete
Wocjan
Ardonne

13. Former IQI Postdocs now in faculty positions elsewhere
Penn State
Waterloo
Michigan
Queensland
UNM
Waterloo
Washington
Michigan
McGill
IBM
Queensland
UBC
London
Waterloo
IBM
Vienna
U. Cental Fla.
Nordita

14. Some former IQI Students
Bob Gingrich (2001) – PIMCO
Andrew Landahl (2002) – University of New Mexico Federico Spedalieri (2003) – UCLA
Sumit Daftuar (2003) – Goldman Sachs
John Cortese (2003) – LIGO (Caltech) Charlene Ahn (2004) – Toyon Research Corporation Dave Beckman (2004) – Toyon Research Corporation
Jim Harrington (2004) – Los Alamos National Laboratory
Carlos Mochon (2005) – Perimeter Institute Anura Abeyesinghe (2006) – Univ. Central Florida Graeme Smith (2006) – IBM
Ben Toner (2006) – CWI, Amsterdam
Panos Aliferis (2007) – IBM
Parsa Bonderson (2007) -- Microsoft Research
Mike Zwolak (2007) – Los Alamos National Laboratory
Bonderson
Zwolak
Gingrich
Landahl
Spedalieri
Daftuar
Ahn
Cortese
Harrington
Mochon
Abeyesinghe
Smith
Toner
Aliferis

15. Quantum Information Challenges
Cryptography
Privacy from physical principles
Algorithms
What can quantum computers do?
Quantum
Computer
Error correction
Reliable quantum computers
Hardware
Toward scalable devices
Noise
And …what are the implications of these ideas for basic physics?

16. Condensed matter physics
In a nutshell:
whole >  (parts)
Emergent phenomena: the collective behavior of many particles cannot be easily guessed, even if we have complete knowledge of how the particles interact with one another.
Entangled quantum many-particle systems have an enormous capacity to surprise and delight us.
Fractional quantum Hall state
High temp. superconductor
Crystalline material

17. Emergence: the fractional quantum Hall effect
Fractional quantum Hall state
Highly mobile electrons, confined to a two-dimensional interface between semiconductors, and exposed to a strong magnetic field, find a very exotic highly-entangled quantum state (which can be observed at sufficiently low temperature).
The local excitations (“quasi-particles”) of this system are profoundly different than electrons. In fact, a single quasi-particle carries an electric charge that is a fraction (for example, 1/3) of the charge of an electron.
Is this the tip of an enormous iceberg?
Are such phenomena useful?

18. Topology
Quantum
Computer
Noise!
Quantum
Computer

19. F

20. F

21. F
Aharonov-Bohm
Phase
exp(ieF)

22. F
Aharonov-Bohm
Phase
exp(ieF)

23. Anyons
Quantum information can be stored in the collective state of exotic particles in two dimensions (“anyons”).
The information can be processed by exchanging the positions of the anyons (even though the anyons never come close to one another).

24. Anyons
Quantum information can be stored in the collective state of exotic particles in two dimensions (“anyons”).
The information can be processed by exchanging the positions of the anyons (even though the anyons never come close to one another).

25. Topological quantum computation
annihilate pairs?
Kitaev
braid
braid
braid
time
create pairs

26. Topological quantum computation
create pairs
braid
annihilate pairs?
Kitaev
time

27. Topological quantum computation
The computation is intrinsically resistant to noise.
If the paths followed by the particles in spacetime execute the right braid, then the quantum computation is guaranteed to give the right answer!
time

28. Topological quantum computation
Physical fault tolerance with nonabelian anyons
Kitaev
Eisenstein

29. “The rule of simulation that I would like to have is that the number of computer elements required to simulate a large physical system is only proportional to the space-time volume of the physical system”
R. P. Feynman, “Simulating Physics with Computers” (1981).

30. Condensed matter meets atomic physics
Quantum simulators:
Condensed matter meets atomic physics
In general, we can’t simulate a many-particle quantum system with a classical computer.
But we can simulate one quantum system with another one!
The atomic physicists have developed remarkable tools for cooling and controlling atoms. Exploiting these tools, we can study (and discover) quantum many-particle phenomena that up until now have been experimentally inaccessible.

31. Crossover in fermion pair condensates
C. Regal et al. (2004) , M. Zwierlein et al. (2005)
Superfluidity persists through the crossover from a molecular condensate of tightly bound pairs of fermionic (potassium or lithium) atoms (BEC) to a condensate of loosely bound Cooper pairs (BCS) analogous to a superconducting state of a system of electrons.
Because a superfluid flows without resistance, a rotating superfluid organizes into vortices, each carrying a tiny fraction of the angular momentum, and because the vortices repel one another, they crystalize into a regular lattice. The strength of the interactions between fermionic atoms can be modulated by varying a magnetic field, so that the crossover from (b) to (c) can be studied experimentally.

32. Many-body physics with polar molecules
P. Zoller et al. (2006)
J. Ye et al. (2008)
Polar molecules, trapped in an optical lattice, have dipole moments, which provide a useful handle for manipulating the interactions among the molecules and realizing exotic quantum many-body states (for example, the ground state of the Kitaev model, which supports nonabelian anyons).

33. How fast does information escape from a black hole?
Hayden,
Preskill
How fast does information escape from a black hole?
Alice
black hole
Bob
strongly
mixing
unitary
maximal
entanglement
Alice’s
qubits
Bob decodes
black
hole
radiation
Black holes are (we believe) efficient quantum information processors. How long do we have to wait for information absorbed by a black hole to be revealed in its emitted Hawking radiation? We have recently reconsidered this question using new tools from quantum information theory.
Our (tentative) conclusion is that the retention time can be surprisingly short. The analysis uses the theory of quantum error-correcting codes and quantum circuits.

34. Quantum Information Science
Atomic-Molecular
Optical Physics
Condensed
Matter Physics
Exotic Quantum
States of Matter!

35. Exotic Quantum States of Matter! Preskill Kitaev Schulman
Kimble Painter Vahala
Eisenstein Roukes Refael Motrunich
Exotic Quantum
States of Matter!
All-Star
All-Star