Pressure-Induced Mixed States Caused by Spin-Elastic Interactions during First-Order Spin Phase Transition in Spin Crossover Compounds

Abstract: Recently, the possibility of exploiting the phenomenon of spin transition (ST) has been intensively investigated; therefore, it is particularly important to study the behavior of ST under various stimuli. Here, the shape and content of the intermediate phase of ST in Hoffmann-like compounds [Fe(Fpz) 2 M(CN) 4 ] (M = Pt, Pd) under external stimuli are studied. For this purpose, magnetic and Raman spectroscopy studies were carried out. In pressure-induced spin transition (PIST), a mixture of high-spin and low-sp… Show more

“…The value of P 1/2 Pt is less than that of P 1/2 Pd , a fact that is consistent with the order of ligand field strength reported in ref . The pressure interval difference between the ST of the two compounds, Δ P (Pd) > Δ P (Pt), is similar to the results described in ref , which may be related to the different mechanical properties of the compounds …”

“…Isoq-Pt shows a more sudden ST behavior than Isoq-Pd because the mechanical properties of Isoq-Pt change more significantly than Isoq-Pd before and after ST, which are conducive to the generation of spin domains. 52 In the variable-pressure Raman and IR spectra using KBr as a PTM, both Isoq-Pt and Isoq-Pd experienced "gradual" PIST under pressure, where the PIST behavior of Isoq-Pt changed particularly significantly, and the pressure interval of its ST was even larger than that of Isoq-Pd. Interestingly, in the X-ray diffraction experiment using microcrystalline powder, we found that both Isoq-Pt and Isoq-Pd showed the same PIST behavior as the single crystal.…”

“…Under variable-pressure powder X-ray diffraction, Raman, and UV–vis absorption spectroscopy at room temperature using silicone oil as PTM, we found that Isoq-Pt undergoes an “abrupt” PIST under pressure, whereas Isoq-Pd undergoes a “gradual” PIST under pressure. Isoq-Pt shows a more sudden ST behavior than Isoq-Pd because the mechanical properties of Isoq-Pt change more significantly than Isoq-Pd before and after ST, which are conducive to the generation of spin domains . In the variable-pressure Raman and IR spectra using KBr as a PTM, both Isoq-Pt and Isoq-Pd experienced “gradual” PIST under pressure, where the PIST behavior of Isoq-Pt changed particularly significantly, and the pressure interval of its ST was even larger than that of Isoq-Pd .…”

“…The pressure interval difference between the ST of the two compounds, ΔP(Pd) > ΔP(Pt), is similar to the results described in ref 36, which may be related to the different mechanical properties of the compounds. 52 Variable-pressure Raman spectroscopy measurements of Isoq-Pt and Isoq-Pd microcrystalline powders using KBr as the PTM are shown in Figures S3 and S4. The pressure dependence of γ HS displayed in Figures S3d and S4d shows that both compounds exhibit a more "gradual" PIST behavior compared with that derived from using silicone oil as PTM.…”

Anomalous Pressure Response of Temperature-Induced Spin Transition and a Pressure-Induced Spin Transition in Two-Dimensional Hofmann Coordination Polymers

“…The value of P 1/2 Pt is less than that of P 1/2 Pd , a fact that is consistent with the order of ligand field strength reported in ref . The pressure interval difference between the ST of the two compounds, Δ P (Pd) > Δ P (Pt), is similar to the results described in ref , which may be related to the different mechanical properties of the compounds …”

“…Isoq-Pt shows a more sudden ST behavior than Isoq-Pd because the mechanical properties of Isoq-Pt change more significantly than Isoq-Pd before and after ST, which are conducive to the generation of spin domains. 52 In the variable-pressure Raman and IR spectra using KBr as a PTM, both Isoq-Pt and Isoq-Pd experienced "gradual" PIST under pressure, where the PIST behavior of Isoq-Pt changed particularly significantly, and the pressure interval of its ST was even larger than that of Isoq-Pd. Interestingly, in the X-ray diffraction experiment using microcrystalline powder, we found that both Isoq-Pt and Isoq-Pd showed the same PIST behavior as the single crystal.…”

“…Under variable-pressure powder X-ray diffraction, Raman, and UV–vis absorption spectroscopy at room temperature using silicone oil as PTM, we found that Isoq-Pt undergoes an “abrupt” PIST under pressure, whereas Isoq-Pd undergoes a “gradual” PIST under pressure. Isoq-Pt shows a more sudden ST behavior than Isoq-Pd because the mechanical properties of Isoq-Pt change more significantly than Isoq-Pd before and after ST, which are conducive to the generation of spin domains . In the variable-pressure Raman and IR spectra using KBr as a PTM, both Isoq-Pt and Isoq-Pd experienced “gradual” PIST under pressure, where the PIST behavior of Isoq-Pt changed particularly significantly, and the pressure interval of its ST was even larger than that of Isoq-Pd .…”

“…The pressure interval difference between the ST of the two compounds, ΔP(Pd) > ΔP(Pt), is similar to the results described in ref 36, which may be related to the different mechanical properties of the compounds. 52 Variable-pressure Raman spectroscopy measurements of Isoq-Pt and Isoq-Pd microcrystalline powders using KBr as the PTM are shown in Figures S3 and S4. The pressure dependence of γ HS displayed in Figures S3d and S4d shows that both compounds exhibit a more "gradual" PIST behavior compared with that derived from using silicone oil as PTM.…”

Anomalous Pressure Response of Temperature-Induced Spin Transition and a Pressure-Induced Spin Transition in Two-Dimensional Hofmann Coordination Polymers

“…10 Importantly, both factors also influence the critical pressure where pressure-induced amorphisation occurs. 23 There has been interest in the pressure-dependent spin-state of MOF-related Hoffman-type clathrates [24][25][26] and the elastic properties of molecular Fe(II) SCO complexes, 27,28 highlighting that changing the spin-state significantly impacts B. The impact of the spin-state of metal centres within the metal-node on the mechanical properties of MOFs has not been explored to our knowledge.…”

Spin-state dependent pressure responsiveness of Fe(ii)-based triazolate metal–organic frameworks

Reversible Colossal Barocaloric Effect of a New Fe^II Molecular Complex with Low Hysteretic Spin Crossover Behavior