Molecular Magnetic Materials 2016
DOI: 10.1002/9783527694228.ch7
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High‐ T c Ordered Molecular Magnets

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Cited by 5 publications
(4 citation statements)
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“…The additional functionalities co-exist or are strongly coupled with the magnetic ordering, providing a convenient route to multifunctionality [1]. In terms of future technological applications, it is crucial to develop new strategies towards higher magnetic ordering temperatures in molecular magnets [2] to eliminate the need for expensive cooling resources like liquid helium. Efforts thus far have focused mainly on Prussian blue analogs [3] and cyanido-bridged materials based on hepta-or octacyanidometallates of 4d and 5d metal ions [4,5].…”
Section: Introductionmentioning
confidence: 99%
“…The additional functionalities co-exist or are strongly coupled with the magnetic ordering, providing a convenient route to multifunctionality [1]. In terms of future technological applications, it is crucial to develop new strategies towards higher magnetic ordering temperatures in molecular magnets [2] to eliminate the need for expensive cooling resources like liquid helium. Efforts thus far have focused mainly on Prussian blue analogs [3] and cyanido-bridged materials based on hepta-or octacyanidometallates of 4d and 5d metal ions [4,5].…”
Section: Introductionmentioning
confidence: 99%
“…Hence, the metal-radical approach has been extensively used in the field of molecular magnetism, where organic radicals are typically isolated before their subsequent assembly with metal ion centers. , Frequently, radical ligands have also been introduced through post-synthetic redox treatment of complexes and materials containing closed-shell ligands. An alternative, however, to save time, reactants, and reduce chemical waste, is to explore the possibility of in-situ redox processes between the metal ion and the ligand during the synthesis. By rationally selecting the metal/ligand pair based on their respective redox properties, both energies and overlaps of magnetically relevant molecular orbitals (MOs) can be tuned to attain the desired magnetic and transport properties. Through this approach, molecule-based magnets with critical temperatures above room temperature have been obtained from the tetracyanoethylene (TCNE) radical and its analogues. …”
mentioning
confidence: 99%
“…We further examine the role of zeolitic water in the reversible magnetism control of thermally stable compound 1 in which the zeolitic water molecules randomly occupy interstitial sites to lower the magnetic ordering temperature . The structural vacancy in such a compound enables the absorption and desorption of water molecules, which in turn, could lead to dynamical and reversible tunability of magnetic exchange interactions for the proof-of-concept demonstration of stimuli directed energy conversion and cooling devices. , Figure a shows temperature dependence of the magnetization ( M – T ) of compound 1 at different relative humidity (RH). Under 0% RH, it shows a typical magnetic phase transformation between low-temperature ferrimagnetic phase and high-temperature paramagnetic phase with a T c of 360 K. The T c of compound 1 can decrease from 360 K (0% RH) to 304 K (80% RH) (Figure b).…”
mentioning
confidence: 99%