Difference between revisions of "Quantum simulator"
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# Quantum devices and transport | # Quantum devices and transport | ||
## the transport properties of the Fermi-Hubbard model should provide understanding of high-temperature cuprate phenomenology | ## the transport properties of the Fermi-Hubbard model should provide understanding of high-temperature cuprate phenomenology | ||
| + | ## quantum-dot based photovoltaics | ||
| + | ## quantum thermoelectrics | ||
| + | ## spintronics | ||
| + | ## nanothermodynamics (an information-based Carnot cycle) | ||
# Gravity, particle physics, and cosmology | # Gravity, particle physics, and cosmology | ||
# Non-equilibrium quantum many-body dynamics | # Non-equilibrium quantum many-body dynamics | ||
==Cite== | ==Cite== | ||
Revision as of 20:53, 3 January 2020
This work [1] Systems: atomic, molecular, optical, solid state. Being built are gated quantum dots and photonic arrays. Possible areas of research are:
- Quantum materials simulation.
- pseudo-gap
- strange metals
- the quantum critical fan
- heterostructures,
- artificial lattice structures (quantum spin ice)
- quantum generalizations of soft matter (the spin glass)
- Quantum chemistry
- to build a model of the photosynthesis problem
- calculating reaction rates and modeling catalysis
- calculating molecular properties of a single Cr2 dimer
- Quantum devices and transport
- the transport properties of the Fermi-Hubbard model should provide understanding of high-temperature cuprate phenomenology
- quantum-dot based photovoltaics
- quantum thermoelectrics
- spintronics
- nanothermodynamics (an information-based Carnot cycle)
- Gravity, particle physics, and cosmology
- Non-equilibrium quantum many-body dynamics
Cite
- ↑ Quantum Simulators: Architectures and Opportunities. Altman et. al
