|
gptkbp:instance_of
|
gptkb:Information_Technology
|
|
gptkbp:challenges
|
error correction
decoherence
|
|
gptkbp:collaborations
|
universities
startups
tech companies
|
|
gptkbp:developed_by
|
various research institutions
|
|
gptkbp:example
|
gptkb:D-Wave_Systems
gptkb:Google_Sycamore
gptkb:IBM_Quantum_System_One
gptkb:Rigetti_Computing
|
|
gptkbp:funding
|
gptkb:venture_capital
government grants
private investments
|
|
gptkbp:has_advantage_in
|
certain computational tasks
|
|
gptkbp:has_limitations
|
scalability issues
high operational costs
limited software ecosystem
sensitivity to environmental noise
|
|
https://www.w3.org/2000/01/rdf-schema#label
|
Quantum Computers
|
|
gptkbp:impact
|
gptkb:Artificial_Intelligence
drug discovery
financial modeling
material science
|
|
gptkbp:is_applied_in
|
gptkb:crypt
gptkb:machine_learning
quantum simulation
optimization problems
|
|
gptkbp:is_capable_of
|
quantum parallelism
|
|
gptkbp:is_compared_to
|
classical computers
|
|
gptkbp:key_figures
|
gptkb:Peter_Shor
gptkb:Alain_Aspect
gptkb:Michael_Nielsen
gptkb:Lov_Grover
gptkb:David_Deutsch
gptkb:Artur_Ekert
gptkb:Charles_Bennett
gptkb:Scott_Aaronson
gptkb:Seth_Lloyd
gptkb:John_Preskill
|
|
gptkbp:operates
|
quantum mechanics principles
|
|
gptkbp:requires
|
cryogenic temperatures
|
|
gptkbp:research_focus
|
gptkb:Quantum_Computing
quantum supremacy
quantum networking
|
|
gptkbp:trends
|
hybrid quantum-classical systems
improved error rates
increased qubit count
more accessible technology
|
|
gptkbp:uses
|
quantum algorithms
quantum bits (qubits)
quantum gates
|
|
gptkbp:bfsParent
|
gptkb:Qiskit_Machine_Learning
gptkb:IBM_Research_-Brazil
gptkb:IBM_Research_-Canada
gptkb:IBM_Research_-Lithuania
gptkb:IBM_Quantum_Network
gptkb:Post-Quantum_Cryptography
gptkb:IBM_Australia_Research_Lab
|
|
gptkbp:bfsLayer
|
5
|