What question did this study set out to answer?

Investigate how iodine uptake affects spin states in Fe(II) spin-crossover frameworks.

March 25, 2026Open Access

“Reversible I 2 Uptake Induces Record‐High Spin‐Crossover Hysteresis in a Fe(II) Hofmann‐Type MOF”

Key Points

Investigate how iodine uptake affects spin states in Fe(II) spin-crossover frameworks.
Utilized vapor-phase iodine uptake in Hofmann-type MOF [Fe(pz)Pd(CN)4]
Conducted structural analysis to confirm framework integrity
Performed magnetic analyses to evaluate spin transitions
Achieved a thermal hysteresis of 120 K, a record for these materials
Iodine loading leads to multistep spin-crossover with asymmetric hysteresis
Full iodine saturation stabilizes extreme bistability with symmetric hysteresis

Abstract

Controlling bistable spin states in Fe(II) spin-crossover (SCO) frameworks remains challenging. Here, we demonstrate that guest-induced chemical pressure provides a reversible and general strategy to amplify thermal hysteresis. In the flexible Hofmann-type MOF Fe(pz)Pd(CN)4, vapor-phase iodine uptake produces a record-wide thermal hysteresis of 120 K, far exceeding previously reported values. Structural and magnetic analyses confirm that the framework remains intact, and lattice compression by iodine enhances cooperative spin transitions, stabilizing both high-spin and low-spin (LS) states. Partial iodine loading induces multistep SCO with asymmetric hysteresis, whereas full saturation generates extreme bistability with symmetric hysteresis. This approach establishes guest capture as a direct, reversible tool to control SCO bistability, offering a broadly applicable design principle for multifunctional porous materials.

“Reversible I 2 Uptake Induces Record‐High Spin‐Crossover Hysteresis in a Fe(II) Hofmann‐Type MOF”

Key Points

Abstract

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