Room-Temperature Quantum Coherence and Rabi Oscillations in Vanadyl Phthalocyanine: Toward Multifunctional Molecular Spin Qubits

Atzori, Matteo; Tesi, Lorenzo; Morra, Elena; Chiesa, Mario; Sorace, Lorenzo; Sessoli, Roberta

doi:10.1021/jacs.5b13408

Cited by 330 publications

(474 citation statements)

References 31 publications

(49 reference statements)

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“…Since, for typical pulsed ESR setups, the time to manipulate an electron spin is about 10 ns, both T 1 and T 2 need to be much longer in order to observe coherent spin oscillations and, possibly to perform some error corrections. As a matter of facts, Rabi oscillations at room temperature have been recently reported in VOPc [17]. These results represent an important milestone for molecular magnetism.…”

Section: Coherent Spin Dynamics Of Spin Ensemblesmentioning

confidence: 67%

Molecular Spins in the Context of Quantum Technologies

2017

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Section: Coherent Spin Dynamics Of Spin Ensemblesmentioning

confidence: 67%

Molecular Spins in the Context of Quantum Technologies

2017

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“…Moreover, a pronounced crystal size dependence of the relaxation time was observed in complexes 6-8. Another mononuclear V(IV) based spin qubits with short V=O bond (1.58 Å) is the complex VOPc 9 (Pc = Phthalocyanine) (Figure 4a) [31,48]. Together with its d 1 electron configuration, this molecule makes a perfect two level system for spin qubit.…”

Section: Introductionmentioning

confidence: 99%

The Rise of Single-Ion Magnets as Spin Qubits

2016

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Recent studies revealed that magnetic molecules with single spin centers showed exciting phenomena related to quantum information processing, such as long quantum coherence times and Rabi oscillations. In this review, we go over these phenomena according to the essential metal ions, from which we can see the development of single-ion magnets as spin qubits is booming, especially quantum coherence times have been significantly enhanced from nanoseconds to hundreds of microseconds in a short period. Hence, the correlations between the molecular structures and quantum coherence are becoming clearer. In this regard, some chemical approaches to designing better spin qubits have been discussed.

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“…For instance, single-molecule magnets using copper phthalocyanine [1], nitrogen, and phosphorous atom in fullerene cages, such as N@C 60 [2], and P@C 60 , endohedral metallofullerene, such as Sc 3 N@C 80 [3], Sc 3-x YN@C 80 (CF 3 ) n [4,5], Gd x Sc 3-x N@C 80 [6], HoSc 2 N@C 80 [7], LnSc 2 N@C 80 [8], (Sc 3 N@C 80 ) 2 dimmer [9], scandium oxide endohedral metallofullerenes Sc 4 O 2 @C 80 (CF 3 ) n , Sc 4 O 2 @C 80 [10,11], and endohedral metallofullerene encapsulated within single-walled-carbon nanotube (SWCNTs) as peapods [12][13][14], were applied for controlling the magnetic interaction with entanglement of quantum spin in the spinlattice relaxation process. Experimental verification of spintronics, and nuclear magnetic resonance (NMR) quantum computers using single nitrogen vacancy defects in the center of diamonds [15], perfluorobutadienyl iron complex [16], nitrogen endohedral fullerenes, vanadium phthalocyanines [17], and single-molecule magnets [18,19] were performed for analyzing spin dynamics, Rabi oscillation, and entanglement of nuclear spin as quantum bits in quantum algorithm calculation. The Rabi oscillation at room temperatures was detected in a solid state molecular system using vanadium phthalocyanine mixed with the isostructural diamagnetic host complex using titanyl-phthalocyanine in a molar ratio of 1:1000 [17][18][19].…”

Section: Introductionmentioning

confidence: 99%

“…Experimental verification of spintronics, and nuclear magnetic resonance (NMR) quantum computers using single nitrogen vacancy defects in the center of diamonds [15], perfluorobutadienyl iron complex [16], nitrogen endohedral fullerenes, vanadium phthalocyanines [17], and single-molecule magnets [18,19] were performed for analyzing spin dynamics, Rabi oscillation, and entanglement of nuclear spin as quantum bits in quantum algorithm calculation. The Rabi oscillation at room temperatures was detected in a solid state molecular system using vanadium phthalocyanine mixed with the isostructural diamagnetic host complex using titanyl-phthalocyanine in a molar ratio of 1:1000 [17][18][19].…”

Section: Introductionmentioning

confidence: 99%

Electronic Structures, and Optical and Magnetic Properties of Quadruple-Decker Phthalocyanines

Suzuki

Oku

2017

Magnetochemistry

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For applications of magnetic devices with operating nuclear-spin-based quantum bits in quantum computing, electronic structures, and magnetic and optical properties of quadruple-decker phthalocyanines with 3d transition metals, such as scandium, yttrium, and lanthanum atoms (M 3 Pc 4 : M = Sc, Y, and La), were studied by quantum calculation using density function theory. Electron density distributions at the highest occupied molecular orbital and lowest unoccupied molecular orbital were considerably delocalized on the phthalocyanine ring with considerable bias of the electrostatic potential. The wide energy gaps and the ultraviolet-visible-near infrared spectra of the systems were based on the phthalocyanine ring-ring interactions with overlapping π-orbitals on the phthalocyanine rings. The chemical shift behavior of 13 C and 14 N-NMR of Sc 3 (Pc) 4 , Y 3 (Pc) 4 , and La 3 (Pc) 4 depended on the deformation of their structures owing to Jahn-Teller splitting of the d-orbital in the metal ligand field, the considerable perturbation of the metal ligand crystal field on the phthalocyanine ring, the electronic structure based on the electron density distribution, and the magnetic interaction of the nuclear quadrupole interaction. The magnetic parameters of the principle g-tensor, the V-tensor of the electronic field gradient, and the asymmetric parameters were influenced by the deformed structures of the complex with the considerable deviation of the charge density distribution. The quadruple-decker metal phthalocyanines using 3d transition metals have an advantage in controlling the electronic structure and magnetic parameters based on the nuclear spin interaction in spin lattice relaxation with respect to applications of single-molecular magnets.

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Room-Temperature Quantum Coherence and Rabi Oscillations in Vanadyl Phthalocyanine: Toward Multifunctional Molecular Spin Qubits

Cited by 330 publications

References 31 publications

Molecular Spins in the Context of Quantum Technologies

Molecular Spins in the Context of Quantum Technologies

The Rise of Single-Ion Magnets as Spin Qubits

Electronic Structures, and Optical and Magnetic Properties of Quadruple-Decker Phthalocyanines

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