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1. Synthesis of SCO FeII complexes with novel π-extended 2,2'-biimidazole ligands

   Yergeshbayeva, S.; Shatruk, M. (April 2021, National Meeting of the American Chemical Society)

   null (Ed.)

   Spin crossover (SCO) is a phenomenon observed for certain transition metal complexes with electronic configuration 3d4-3d7. The conversion between the low-spin (LS) and high-spin (HS) states is usually driven by a variety of external perturbations, such as temperature, pressure, or light. The switching between the enthalpically preferred LS state and entropically favorable HS state is accompanied by dramatic changes in the metal-ligand bond lengths, unit cell volume, optical absorption spectrum, and magnetic susceptibility.1 These changes make SCO materials suitable for applications in sensors, memory, and display devices. One of the central challenges in the SCO research is to initiate strongly cooperative interactions known to lead to abrupt spin transitions and thermal hysteresis that can be harvested as a memory effect. One of the strategies to enhance the cooperativity is to design SCO complexes with supramolecular interactions such as π-stacking of aromatic fragments or hydrogen bonding.2 In this work, we report syntheses and characterization of heteroleptic complexes of [Fe(tpma)(L)](ClO4)2 (tpma = tris(pyridin-2-ylmethyl)amine) with novel π-extended biimidazole-type ligands (L) bearing 2,3-dimethyl-naphthalene-, 6,7-dimethyl-2,3-diphenyl-quinoxaline, and 2,3-dimethyl-anthracene pendant fragments. Solvent-free naphthalene-functionalized complex [Fe(tpma)(xnap-bim)](ClO4)2 exhibits abrupt spin transition at T1/2 = 127K with a narrow 1 K hysteresis loop. In contrast, polymorph of this complex that contains one interstitial molecules of pyridine exhibits gradual SCO. Anthracene-functionalized complex [Fe(tpma)(anthra-bim)](ClO4)2 also crystallizes as two polymorphs. Structural studies at 100, 230, and 300 K revealed dramatic changes in the N-Fe-N biting angles and Fe-N distances, indicating the occurrence of temperature-induced SCO. Complex [Fe(tpma)(quin-bim)](ClO4)2 (quin-bim = 6,7-dimethyl-2,3-diphenyl-quinoxaline-2,2’-biimidazole) showed only HS state at 100 and 230 K. In the crystal packing the mononuclear cations form stacks along b axis. We discuss how the observed magnetic behavior correlates with changes in the crystal packing and interactions between the pendant aromatic substituents on the aforementioned complexes. 

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2. Modular Design of Multifunctionality in TCNQ-Based Fe(II) Spin Crossover Complexes

   Üngör, Ö.; Choi, E. S.; Shatruk, M. (April 2021, National Meeting of the Anerican Chemical Society)

   null (Ed.)

   Fe(II) coordination complexes with ligands of an intermediate field strength often show witching between the high-spin (HS) and low-spin (LS) electronic configurations, known as spin crossover (SCO). This spin-state conversion is achieved by changes in temperature, pressure, or photoexcitation, which make SCO complexes promising materials for various applications that rely on bistable systems. Multifunctional materials that exhibit both spin-state switching and conductivity can be created by combining Fe(II) SCO complexes with organic TCNQ-type electron acceptors. In such complexes, TCNQ●d– radical anions are typically arranged in layers of one-dimensional stacks that provide conducting pathways (Fig. 1). The stacking distance can be affected by structural changes induced by the alteration in the electronic configuration and, thus, bond lengths at the Fe(II) center, resulting in synergy between SCO and conductivity. The synthesis of such materials can be approached in two ways: (1) by coordinating TCNQ●d– ligands directly to the Fe(II) center, which is partially protected by blocking ligands that limit the growth of extended structures or (2) by co-crystallizing completely blocked Fe(II) centers with free TCNQ●d– radicals. We will discuss several examples of the second approach, in which homoleptic Fe(II) cationic SCO complexes with tridentate 2,6-bispyrazolyl-pyridine (bpp) type ligands have been co-crystallized with fractionally-charged TCNQ●d– radical anions. The temperature- and solvent-dependent magnetic behavior and transport properties of these materials will be discussed. We will also present new pathways to improve the design of such molecule-based conductors with spin-state switching properties. To the best of out knowledge, we report the first examples of Fe(II) based conducting molecular materials with abrupt temperature-driven spin transitions. 

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3. Light-induced spin-state switching in Fe(II) spin-crossover complexes with thiazole-based chelating ligands

   https://doi.org/10.1039/D4DT00308J  

   Jo, Minyoung; Amanyazova, Botagoz; Yergeshbayeva, Sandugash; Gakiya-Teruya, Miguel; Üngör, Ökten; Lopez_Rivera, Paola; Jen, Natalie; Lukyanenko, Evgeny; Kurkin, Alexander V; Erkasov, Rakhmetulla; et al (June 2024, Dalton Transactions)

   Three homoleptic Fe(II) complexes with bidentate thiazole-based ligands exhibit spin-crossover (SCO) at the metal center. Abrupt temperature-driven and light-induced spin transitions are observed due to cooperative interactions between SCO cations. 

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4. Synthesis and Characterization of [Fe(Htrz)2(trz)](BF4)] Nanocubes

   https://doi.org/10.3390/molecules27041213  

   Blanco, Alexis A.; Adams, Daniel J.; Azoulay, Jason D.; Spinu, Leonard; Wiley, John B. (February 2022, Molecules)

   Compounds that exhibit spin-crossover (SCO) type behavior have been extensively investigated due to their ability to act as molecular switches. Depending on the coordinating ligand, in this case 1H-1,2,4-triazole, and the crystallite size of the SCO compound produced, the energy requirement for the spin state transition can vary. Here, SCO [Fe(Htrz)2(trz)](BF4)] nanoparticles were synthesized using modified reverse micelle methods. Reaction conditions and reagent ratios are strictly controlled to produce nanocubes of 40–50 nm in size. Decreases in energy requirements are seen in both thermal and magnetic transitions for the smaller sized crystallites, where, compared to bulk materials, a decrease of as much as 20 °C can be seen in low to high spin state transitions. 

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5. (Invited) Utilizing Redox-Coupled Spin-Crossover to Enhance Molecular Bistability

   https://doi.org/10.1149/MA2025-01562705mtgabs  

   Dinolfo, Peter Henry; Mitchell, Andrea L; McCabe, Charles A; Bonitatibus, Peter J (July 2025, ECS Meeting Abstracts)

   Spin crossover (SCO) is one of the most widely studied phenomena in transition metal complexes, in part due to the possible technological applications of such species in molecular electronics, memory storage, electrochromics, and display devices. Any transition metal complex with a d⁴–d⁷electron configuration, such as 2+ and 3+ ions of Cr, Mn, Fe, and Co, can theoretically exhibit SCO effects which depend highly on the coordination environment and ligand field strength. Redox-coupled SCO processes provide a mechanism to enhance the molecular bistability and trigger transitions between low- and high-spin states. Similar reaction mechanisms often occur in electrocatalytic and enzymatic reactions. The electrochemical response of redox-coupled SCO processes can be modeled as a square scheme containing two one-electron reactions and two chemical steps, resulting in a separation of anodic and cathodic waves. Herein we describe the influence of ligand coordination and structural changes on the redox-coupled SCO properties of several Co complexes. This structural-functional analysis allows us to understand the fundamental properties that control redox-coupled SCO processes and optimize redox bistability for a range of applications. 

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