Masanori Tonouchi scite author profile

Magnetic phase switching in a coordination polymer is reported, which is demonstrated by combining two processes: (A) the pre-organization of magnetic/redox-active molecules into a framework, and (B) a post-treatment through electrochemical tuning of the pre-organized molecules. A TTF -TCNQ salt (TTF=tetrathiafulvalene; TCNQ=7,7,8,8-tetracyano-p-quinodimethane) was incorporated into a three-dimensional framework with paddlewheel-type dimetal(II, II) units ([M ]; M=Ru with S=1, 1; and Rh with S=0, 2), where the [M ] and TCNQ units form the coordinating framework, and TTF is located in the pores of framework, forming an irregular π-stacking alternating column with the TCNQ in the framework. In 1, the spins of [Ru ] and TCNQ units make a magnetic correlation through the framework upon decreasing the temperature from 300 K, which is, however, suddenly suppressed below 137 K (=T (1)) by the formation of a spin singlet in the TTF -TCNQ columns, as seen in the spin-Peierls transition (T (2)=200 K). This material was incorporated as a cathode in a Li-ion battery (LIB); a long-range ferrimagnetic correlation was formed through the three-dimensional [{Ru } TCNQ] framework at T =78 K in the discharge process. The reversible magnetic phase switching between the non-volatile ferrimagnetic and paramagnetic states, resulting from the local spin tuning of quasi-spin-Peierls singlet, is demonstrated through the discharge/charge cycling of the LIB.

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Frontispiece: Magnetic Switching by the In Situ Electrochemical Control of Quasi‐Spin‐Peierls Singlet States in a Three‐Dimensional Spin Lattice Incorporating TTF‐TCNQ Salts

Fukunaga

Tonouchi

Taniguchi

et al. 2018

Chemistry A European J

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Hiding a specific function of a material using a masking trigger (i.e., function inactivation) and then triggering the functionality by applying an external stimulus is a unique way to bring on‐demand functionality to a molecular system. We demonstrate magnetic phase control by combining the pre‐organization of trigger (i.e., “spin‐Peierls”‐like spin singlet formation incorporated in a porous magnetic framework) and a post‐treatment (i.e., electrochemical reduction using a Li‐ion battery cell) for triggering the magnetic long‐range correlation through the framework. For more information, see the Full Paper by H. Miyasaka on page 4294 ff.

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Masanori Tonouchi

Built-in TTF–TCNQ charge-transfer salts in π-stacked pillared layer frameworks

Magnetic Switching by the In Situ Electrochemical Control of Quasi‐Spin‐Peierls Singlet States in a Three‐Dimensional Spin Lattice Incorporating TTF‐TCNQ Salts

Frontispiece: Magnetic Switching by the In Situ Electrochemical Control of Quasi‐Spin‐Peierls Singlet States in a Three‐Dimensional Spin Lattice Incorporating TTF‐TCNQ Salts

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