Quantum weirdness in technology

Leo Kouwenhoven

Quantum weirdness in technology

from molecules via teleportation to a quantum computer

QUANTUMMECHANICAL WORLD

CLASSICAL WORLD

fm pm nm µm mm m

Quantum mechanics, the theory for small objects

Solvay conference 1927, Brussels

Quantum mechanics, absurd behaviour in big objects

Quantum Transport Group 2012, Delft

Quantum superposition

chemical bonds are quantum glue from electron superpositions.

CH4 methane

Quantum superposition

Two different positions at the same time!

Colliding with itself (interference)

Entanglement

Entanglement

“Properties remain entangled over long distances.”

Teleportation !

A measurement HERE also changes the thing THERE ……instantaneously!

Entanglement

Einstein: “Haha… Spooky action at a distance. You see, quantum is wrong.”

A measurement HERE also changes the thing THERE ……instantaneously!

Entanglement

Feynman: “Shut up and calculate!”

A measurement HERE also changes the thing THERE ……instantaneously!

Entanglement

Me: “Let’s do it!”

Entanglement Teleportation

Entanglement Teleportation

Entanglement Teleportation

Quantum Teleportation “Transfer information over a large

distance without going there”

Philosophy

What does it mean?

Quantum theory gives extremely accurate predictions è Quantum theory is the best tested theory!! è We know how it works but not why it works this way.

Feynman: “Shut up and calculate!”

Single photon light bulb

100 nm"

100 nm"

Single photon light bulb

Majorana particles on a chip

quantum

nm µm mm m atom gadget

DiCarlo group @ TUDelft

quantum

nm µm mm m atom gadget

DiCarlo group @ TUDelft

Can we extend quantum behaviour to even larger systems?

Hanson group @ TUDelft

Can we make quantum behaviour more complex?

quantum quantum classical

nm µm mm m atom transistor circuit gadget

Photo’s © Miraceti, Luigi Chiesa, T137, Yukata Tsutano used under a Creative Commons license: www.creativecommons.org

Why a quantum computer?

Klassieke bits 0 of 1 of

Quantum bits = qubits 0 en 1 = |0> + |1> en =

What is a quantum computer good for?

15 = 3 x 5

There exits no classical algorithm to factorize numbers efficiently ! The problem increases exponentially in time with the number of digits.

91 = ... x ... ? 437 = ... x ... ? ???

200 digits 1 day (onmogelijk vandaag) 201 2 days 202 4 days 203 8 days 210 1024 days ~ 3 years 220 3.000 years 230 3.000.000 years

“hard problems” take an exponentialy long time to solve

van Meter et al 2006

time to factor a product of two primes

bits

Classical computers are useless! Quantum computers could do it!

Complexity of Quantum Systemen grows exponential

| 0 〉

| 1 〉

α| 0 〉 + β | 1 〉

1 qubit n qubits

2n degrees-of-freedom ! | ψ 〉 = c1 | 000 〉 + c2 | 001 〉 + … + c8 | 111 〉

Classsical: speed ∝ n Quantum: speed ∝ 2n

Parallel computing:

Example: for n = 100 the quantum speed 2100 = 1030

Quantum information: - encode information in photons - in quantum mechanics it is impossible to measure the information without changing it. => internet security. A prototype quantum intranet exists!

http://www.idquantique.com

© U. Geneva

Quantum computer: - more complex circuits - prototype quantum circuit in 2020 - a full scale quantum computer in ~15 to 20 years