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IonQ
Index
Mathematics
Fields of mathematics
Applied mathematics
Information theory
Quantum computing
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1970-01-01
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Quantum computing
Information theory
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Mathematics
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IonQ
by
Ciro Santilli
34
Updated
2024-12-15
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Created
1970-01-01
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Video 1.
Quantum Simulation and Computation with Trapped Ions by Christopher Monroe (2021)
Source
.
Video 2.
Quantum Computing with Trapped Ions by Christopher Monroe (2018)
Source
. Co-founder of
IonQ
. Cool dude. Starts with basic background we already know now. Mentions that there is some relationship between
atomic clocks
and
trapped ion quantum computers
, which is interesting. Then he goes into turbo mode, and you get lost unless you're an expert!
Video 1. "Quantum Simulation and Computation with Trapped Ions by Christopher Monroe (2021)"
is perhaps a better watch.
youtu.be/9aOLwjUZLm0?t=1216
superconducting qubits are bad because it is harder to ensure that they are all the same
youtu.be/9aOLwjUZLm0?t=1270
our wires are provided by
lasers
. Gives example of
ytterbium
+
1
, which has nice frequencies for practical
laser
choice. Ytterbium ends in 6s2 5d1, so they must remove the 5d1 electron? But then you are left with 2 electrons in 6s2, can you just change their spins at will without problem?
youtu.be/9aOLwjUZLm0?t=1391
a single atom actually reflects 1% of the input laser, not bad!
youtu.be/9aOLwjUZLm0?t=1475
a transition that they want to drive in Ytterbium has 355 nm, which is easy to generate TODO why.
youtu.be/9aOLwjUZLm0?t=1520
mentions that 351 would be much harder, e.g. as used in inertially confied fusion, takes up a room
youtu.be/9aOLwjUZLm0?t=1539
what they use: a
pulsed laser
. It is made primarily for
photolithography
,
Coherent, Inc.
makes 200 of them a year, so it is reliable stuff and easy to operate. At
www.coherent.com/lasers/nanosecond/avia-nx
we can see some of their 355 offers.
archive.ph/wip/JKuHI
shows a used system going for 4500 USD.
youtu.be/9aOLwjUZLm0?t=1584
Cirac and Zoller proposed the idea of using entangled ions soon after they heard about
Shor's algorithm
in 1995
youtu.be/9aOLwjUZLm0?t=1641
you use
optical tweezers
to move the pairs of ions you want to entangle. This means shining a
laser
on two ions at the same time. Their movement depends on their
spin
, which is already in a superposition. If both move up, their distance stats the same, so the
Coulomb interaction
is unchanged. But if they are different, then one goes up and the other down, distance increases due to the diagonal, and energy is lower.
youtu.be/9aOLwjUZLm0?t=1939
S. Debnah 2016 Nature experiment with a pentagon. Well, it is not a pentagon, they are just in a linear chain, the pentagon is just to convey the full connectivity. Maybe also
Satanism
. Anyways. This point also mentions usage of an
acousto-optic modulator
to select which atoms we want to act on. On the other side, a simpler wide laser is used that hits all atoms (
optical tweezers
are literally like tweezers in the sense that you use two lasers). Later on mentions that the modulator is from Harris, later merged with L3, so:
www.l3harris.com/all-capabilities/acousto-optic-solutions
youtu.be/9aOLwjUZLm0?t=2119
Bernstein-Vazirani algorithm
. This to illustrate better connectivity of their ion approach compared to an
IBM quantum computer
, which is a
superconducting quantum computer
youtu.be/9aOLwjUZLm0?t=2354
hidden shift algorithm
youtu.be/9aOLwjUZLm0?t=2740
Zhang et al. Nature 2017 paper about a 53 ion system that calculates something that cannot be classically calculated. Not fully controllable though, so more of a
continuous-variable quantum information
operation.
youtu.be/9aOLwjUZLm0?t=2923
usage of cooling to 4 K to get lower pressures on top of vacuum. Before this point all experiments were room temperature. Shows image of refrigerator labelled Janis cooler, presumably something like:
qd-uki.co.uk/cryogenics/janis-recirculating-gas-coolers/
youtu.be/9aOLwjUZLm0?t=2962
qubit vs gates plot by H. Neven
youtu.be/9aOLwjUZLm0?t=3108
modular trapped ion quantum computer
ideas. Mentions experiment with 2 separate systems with optical link. Miniaturization and their black box. Mentions again that their chip is from
Sandia
. Amazing how you pronounce that.
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