Your search keyword '"Freedman, Danna E."' showing total 2 results

1. Tunable Cr 4+ Molecular Color Centers

Author

Massachusetts Institute of Technology. Department of Chemistry, Laorenza, Daniel W, Kairalapova, Arailym, Bayliss, Sam L, Goldzak, Tamar, Greene, Samuel M, Weiss, Leah R, Deb, Pratiti, Mintun, Peter J, Collins, Kelsey A, Awschalom, David D, Berkelbach, Timothy C, Freedman, Danna E, Massachusetts Institute of Technology. Department of Chemistry, Laorenza, Daniel W, Kairalapova, Arailym, Bayliss, Sam L, Goldzak, Tamar, Greene, Samuel M, Weiss, Leah R, Deb, Pratiti, Mintun, Peter J, Collins, Kelsey A, Awschalom, David D, Berkelbach, Timothy C, and Freedman, Danna E

Abstract

The inherent atomistic precision of synthetic chemistry enables bottom-up structural control over quantum bits, or qubits, for quantum technologies. Tuning paramagnetic molecular qubits that feature optical-spin initialization and readout is a crucial step toward designing bespoke qubits for applications in quantum sensing, networking, and computing. Here, we demonstrate that the electronic structure that enables optical-spin initialization and readout for S = 1, Cr(aryl)4, where aryl = 2,4-dimethylphenyl (1), o-tolyl (2), and 2,3-dimethylphenyl (3), is readily translated into Cr(alkyl)4 compounds, where alkyl = 2,2,2-triphenylethyl (4), (trimethylsilyl)methyl (5), and cyclohexyl (6). The small ground state zero field splitting values (<5 GHz) for 1-6 allowed for coherent spin manipulation at X-band microwave frequency, enabling temperature-, concentration-, and orientation-dependent investigations of the spin dynamics. Electronic absorption and emission spectroscopy confirmed the desired electronic structures for 4-6, which exhibit photoluminescence from 897 to 923 nm, while theoretical calculations elucidated the varied bonding interactions of the aryl and alkyl Cr4+ compounds. The combined experimental and theoretical comparison of Cr(aryl)4 and Cr(alkyl)4 systems illustrates the impact of the ligand field on both the ground state spin structure and excited state manifold, laying the groundwork for the design of structurally precise optically addressable molecular qubits.

Published

2022

2. Chemical control of spin–lattice relaxation to discover a room temperature molecular qubit

Author

Massachusetts Institute of Technology. Department of Chemistry, Amdur, M. Jeremy, Mullin, Kathleen R., Waters, Michael J., Puggioni, Danilo, Wojnar, Michael K., Gu, Mingqiang, Sun, Lei, Oyala, Paul H., Rondinelli, James M., Freedman, Danna E., Massachusetts Institute of Technology. Department of Chemistry, Amdur, M. Jeremy, Mullin, Kathleen R., Waters, Michael J., Puggioni, Danilo, Wojnar, Michael K., Gu, Mingqiang, Sun, Lei, Oyala, Paul H., Rondinelli, James M., and Freedman, Danna E.

Abstract

Elucidating the role of specific vibrational modes in spin lattice relaxation is a key step to designing room temperature qubits. We executed an experimental and theoretical study on a series of Cu2+ qubits to increase their operating temperature.

Published

2022