Litcius/Paper detail

Spin Qubit in a 2D Gd<sup>III</sup>Na<sup>I</sup>‐Based Oxamato Supramolecular Coordination Framework

Jia Wang, Jing Yu, Ming‐Hui Cui, Yiming Lu, Zhongwen Ouyang, Chongyun Shao, Zhenxing Wang, You Song

2023Chemistry - A European Journal13 citationsDOI

Abstract

Abstract Qubits are the basic unit of quantum information and computation. To realize quantum computing and information processing, the decoherence times of qubits must be long enough. Among the studies of molecule‐based electron spin qubits, most of the work focused on the ions with the spin S =1/2, where only single‐bit gates can be constructed. However, quantum operations require the qubits to interact with each other, so people gradually carry out relevant research in ions or systems with S &gt;1/2 and multilevel states. In this work, a two‐dimensional (2D) oxygen‐coordinated Gd III Na I ‐based oxamato supramolecular coordination framework, Na[Gd(4‐HOpa) 4 (H 2 O)] ⋅ 2H 2 O ( 1 , 4‐HOpa=N‐4‐hydroxyphenyloxamate), was selected as a possible carrier of qubit. The field‐induced slow magnetic relaxation shows this system has phonon bottleneck (PB) effect at low temperatures with a very weak magnetic anisotropy. The pulse electron paramagnetic resonance studies show the spin‐lattice and spin‐spin relaxation times are T 1 =1.66 ms at 4 K and T m =4.25 μ s at 8 K for its diamagnetically diluted sample ( 1Gd0.12 % ). It suggested that the relatively long decoherence time is mainly ascribed to its near isotropic and the PB effect from resonance phonon trapped for pure sample, while the dilution further improves its qubit performance.

Topics & Concepts

QubitQuantum computerQuantum decoherenceElectron paramagnetic resonancePhysicsSpin (aerodynamics)ChemistryCondensed matter physicsAtomic physicsQuantum mechanicsQuantumThermodynamicsMagnetism in coordination complexesMetal-Organic Frameworks: Synthesis and ApplicationsOrganic and Molecular Conductors Research