NMR Contributions to the study of Quantum Correlations
Isabela A. Silva, Jefferson G. Filgueiras, Ruben Auccaise, Alexandre, M. Souza, Raimund Marx, Steffen J. Glaser, Tito J. Bonagamba, Roberto S., Sarthour, Ivan S. Oliveira, Eduardo R. deAzevedo
TL;DR
This paper reviews how Nuclear Magnetic Resonance (NMR) techniques have advanced the understanding of quantum correlations, focusing on state preparation, transformations, and characterization in quantum information processing with small qubit systems.
Contribution
It highlights NMR's capabilities in preparing, transforming, and characterizing quantum states, emphasizing its near-perfect performance for small-scale quantum information tasks.
Findings
NMR effectively prepares initial quantum states.
NMR can generate precise unitary transformations.
NMR accurately characterizes quantum states.
Abstract
In this chapter we review the contributions of Nuclear Magnetic Resonance to the study of quantum correlations, including its capabilities to prepare initial states, generate unitary transformations, and characterize the final state. These are the three main demands to implement quantum information processing in a physical system, which NMR offers, nearly to perfection, though for a small number of qubits. Our main discussion will concern liquid samples at room temperature.
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Taxonomy
TopicsMolecular spectroscopy and chirality · NMR spectroscopy and applications