Coherent manipulation and quantum phase interference in a fullerene-based electron triplet molecular qutrit

Wang, Ye-Xin; Liu, Zheng; Fang, Yu‐Hui; Zhou, Shen; Jiang, Shang‐Da; Gao, Song

doi:10.1038/s41534-021-00362-w

Cited by 25 publications

(23 citation statements)

References 43 publications

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“…Several other qualities of the 5 (TT) state also make it attractive for QIS applications. Due to its high spin multiplicity, 5 (TT) can be utilized as a five-level qudit, which may facilitate greater storage and processing of quantum information compared to systems with fewer accessible quantum levels. − The 5 (TT) state can also be photogenerated on-demand at arbitrary locations, potentially with high spatial resolution using nanophotonic architectures. , This offers advantages over spin qubits based on defect centers, such as nitrogen-vacancy centers in diamond, , for which the placement of defects at specific sites in the lattice remains challenging. Moreover, the high binding energy of excitons in organic semiconductors may enable long 5 (TT) lifetimes and, in turn, allow quantum coherent control at room temperature provided that sources of spin decoherence can be suppressed.…”

Section: Introductionmentioning

confidence: 99%

Using Molecular Design to Enhance the Coherence Time of Quintet Multiexcitons Generated by Singlet Fission in Single Crystals

et al. 2022

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Multiexciton quintet states, 5 (TT), photogenerated in organic semiconductors using singlet fission (SF), consist of four quantum entangled spins, promising to enable new applications in quantum information science. However, the factors that determine the spin coherence of these states remain underexplored. Here, we engineer the packing of tetracene molecules within single crystals of 5,12-bis(tricyclohexylsilylethynyl)tetracene (TCHS−tetracene) to demonstrate a 5 (TT) state that exhibits promising spin qubit properties, including a coherence time, T 2 , = 3 μs at 10 K, a population lifetime, T pop , = 130 μs at 5 K, and stability even at room temperature. The single-crystal platform also enables global alignment of the spins and, consequently, individual addressability of the spin-sublevel transitions. Decoherence mechanisms, including exciton diffusion, electronic dipolar coupling, and nuclear hyperfine interactions, are elucidated, providing design principles for increasing T 2 and the operational temperature of 5 (TT). By dynamically decoupling 5 (TT) from the surrounding spin bath, T 2 = 10 μs is achieved. These results demonstrate the viability of harnessing singlet fission to initiate multiple electron spins in a well-defined quantum state for next-generation molecular-based quantum technologies.

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Section: Introductionmentioning

confidence: 99%

Using Molecular Design to Enhance the Coherence Time of Quintet Multiexcitons Generated by Singlet Fission in Single Crystals

et al. 2022

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“…Evidenced by the electron spin properties of N@C 60,70 , [2] Sc@C 82 , Y@C 82 , La@C 82 , [3, 4] etc., the structure essentially extends the coherence time, as it diminishes the relaxation processes related to fluctuations of environment. Moreover, the carbonaceous elemental composition can effectively sustain the spin coherence due to the zero nuclear spin of the 12 C. As a result, some electron‐spin‐based quantum applications, including molecular quantum computing, [5, 6] molecular atomic clocks, [7] and quantum metrology and sensing, [8, 9] have been proposed.…”

Section: Introductionmentioning

confidence: 99%

Implementation of Quantum Level Addressability and Geometric Phase Manipulation in Aligned Endohedral Fullerene Qudits

et al. 2022

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Endohedral nitrogen fullerenes have been proposed as building blocks for quantum information processing due to their long spin coherence time. However, addressability of the individual electron spin levels in such a multiplet system of 4S3/2 has never been achieved because of the molecular isotropy and transition degeneracy among the Zeeman levels. Herein, by molecular engineering, we lifted the degeneracy by zero‐field splitting effects and made the multiple transitions addressable by a liquid‐crystal‐assisted method. The endohedral nitrogen fullerene derivatives with rigid addends of spiro structure and large aspect ratios of regioselective bis‐addition improve the ordering of the spin ensemble. These samples empower endohedral‐fullerene‐based qudits, in which the transitions between the 4 electron spin levels were respectively addressed and coherently manipulated. The quantum geometric phase manipulation, which has long been proposed for the advantages in error tolerance and gating speed, was implemented in a pure electron spin system using molecules for the first time.

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“…Hence, quantum gate operations at higher temperatures are still an inevitable obstacle to overcome for a practical QIP device 4 . Optical excitations, especially in organic materials, could be one of the solutions, offering larger energy scales for coherent interactions against incoherent thermal noise due to the high temperature (~77 K, the boiling point of liquid nitrogen) [5][6][7] . By using optical excitations, we can also avoid the decoherence induced by the external electrodes conventionally used for the control of electrons 8 .…”

Section: Introductionmentioning

confidence: 99%

“…For radical-bearing molecules, the long-lived triplet (spin-1) can be formed by optical excitations and intersystem crossing (ISC, from the singlet excited state to the triplet ground state) 14 , which can interact via exchange interactions coherently with the radical spin. The triplet plays a role not only as a qutrit (a 3-level quantum system), which can lead to increased security, greater channel capacities, and more efficient gate operations 7 , but also a coupler for controlling the interaction between radicals 15 . Spin states such as a quartet (one radical coupled with a triplet), as shown in Fig.…”

Section: Introductionmentioning

confidence: 99%

Triplet-radical spin entanglement: potential of molecular materials for high-temperature quantum information processing

Chang

Chen

et al. 2022

NPG Asia Mater

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Recently, spin-bearing molecules have been experimentally demonstrated to have great potential as building blocks for quantum information processing due to their substantial advantages including tunability, portability, and scalability. Here, we propose a theoretical model based on the theory of open quantum systems for spin dynamics in a molecule containing one radical, which can interact with the triplet state arising from another part of the molecule owing to optical excitation and intersystem crossing. With the initial state being a classical mixture of a radical $$\frac{1}{2}$$ 1 2 -spin, the exchange interaction between the radical and the triplet produces a spin coherent state, which could potentially be used for a qubit-qutrit quantum entangling gate. Our calculations for the time-resolved electron paramagnetic resonance spectra showed good qualitative agreement with the related experimental results for radical-bearing molecules at high temperature (~77 K, the boiling point of liquid nitrogen). This work therefore lays a solid theoretical cornerstone for optically driven quantum gate operations in radical-bearing molecular materials, aiming toward high-temperature quantum information processing.

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Coherent manipulation and quantum phase interference in a fullerene-based electron triplet molecular qutrit

Cited by 25 publications

References 43 publications

Using Molecular Design to Enhance the Coherence Time of Quintet Multiexcitons Generated by Singlet Fission in Single Crystals

Using Molecular Design to Enhance the Coherence Time of Quintet Multiexcitons Generated by Singlet Fission in Single Crystals

Implementation of Quantum Level Addressability and Geometric Phase Manipulation in Aligned Endohedral Fullerene Qudits

Triplet-radical spin entanglement: potential of molecular materials for high-temperature quantum information processing

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