The paddlewheel‐type diruthenium(II, II) complex, [Ru₂^II,II(3,4‐Cl₂PhCO₂)₄], and TCNQ(EtO)₂, were selected as the D and A units for searching a N–I phase transition compound. These DA systems exhibit the following remarkable features: (1) the I_D of [Ru₂] and E_A of the TCNQ or DCNQI derivatives can be easily tuned by modifying the substitution of ligands or molecules without changing the basic assembly form; (2) the spin set in the I‐phase is not canceled even for an antiferromagnetically coupled set although it is canceled in the organic DA systems, leading to a ferrimagnetic spin correlation of S = 3/2 for [Ru₂^II,III]⁺ and S = 1/2 for TCNQ^•− through a chain; (3) the D⁺A⁻ set in the I‐state did not permit the dimerization that is frequently observed in π‐stacked organic systems, as a Peierls distortion because of its robust covalently bonded framework. To predict the balance between the I_D of D and E_A of A, the (ΔE_H–L(DA)) gap between the highest occupied molecular orbital level of D and lowest unoccupied molecular orbital level of A was easily evaluated by density functional theory calculations for each unit. A plot of ΔE_H–L(DA) as a function of ΔE_1/2(DA), wherein ΔE_1/2(DA) is the potential gap between the redox potentials of D and A, well predicted the oxidation state of these DA and D₂A assembly compounds (Figure S1, Supporting Information). The N‐ and I‐states are expected for ΔE_H–L(DA) > 0 and ΔE_H–L(DA) < 0, respectively. Interestingly, the ΔE_H–L(DA) value for the present DA set is 0.2291 eV. This value is close to ΔE_H–L(DA) = 0, i.e., the boundary region between N‐ and I‐states, which is similar to that (0.2003 eV) for the DA set of the previous N–I transition compound 0 (Figure S1, Supporting Information).

Notably, the chain‐type compounds of the [Ru₂^II,II] units with bidentate linkers often exhibit a porous nature for interstitial crystallization solvents or guest gas molecules. This characteristic led us to prepare guest‐induced switching materials associated with the N–I phase transition, as reported for some porous coordination polymers (PCPs) in terms of spin states, electrical conductivity, and magnetic ordering.

The 1‐DCE structure was examined by single crystal X‐ray crystallography at several temperatures ranging from 103 to 270 K. First, a change in the lattice system suitable for the international union of crystallography (IUCr) rule was observed with a change in the temperature; however, the Miller indices based on the cell system at 103 K were typically used for conveniently referring the crystallographic directions and planes for all data in the following discussions.

Compound 1‐DCE crystallized in the triclinic P‐1 space group in the entire temperature range was investigated (Tables S1–S5, Supporting Information), wherein one half of the formula unit, with inversion centers at the midpoint of the RuRu bond and the center of the TCNQ(EtO)₂ and DCE molecule, was determined as an asymmetric unit (Z = 1). Figure 1a depicts the ORTEP drawing of the formula unit of 1‐DCE at 103 K with atomic numbering schemes; chlorine atoms at the meta positions of the benzoate moiety exhibited disordered positions. Table S2 (Supporting Information) summarizes the selected bond distances and angles. Although TCNQ(EtO)₂ can serve as a tetradentate ligand with four cyano groups, the moiety in 1‐DCE acted as a linear‐type bidentate ligand with only two cyano groups in the trans position, affording a DA alternating chain motif with an [(Ru₂){TCNQ(EtO)₂}] repeat similar to 0, and an ionic DA chain compound with bis(1,2,5‐thiadiazolo)tetracyanoquinodimethane (BTDA‐TCNQ). The chains run along the <110> direction, affording a chain‐aggregated layer on the (001) plane (hereafter known as a chain layer; see Figure b–d). Within the chain layer, chains were closely packed in an antiphase manner (i.e., ⋅⋅⋅D⋅⋅⋅A⋅⋅⋅D⋅⋅⋅A⋅⋅⋅) along the <1−10> direction, with the interchain π‐stack stabilization related to each of the TCNQ molecules sandwiched from the top and bottom by the phenyl ring of the benzoate moieties in the neighboring chains (red circles in Figure ), leading to a relatively short interchain [Ru₂]⋅⋅⋅TCNQ (centroid to centroid) distance of 7.39 Å at 103 K (the <1−10> direction, Table S5, Supporting Information). One DCE molecule was present as an interstitial crystallization solvent between the chain layers, occupying an isolated pore with a solvent‐accessible volume of 118 ų (9%) at 103 K (Figure d shows the Connolly surfaces). Thus, the chains along the <001> direction (i.e., between chain layers) are significantly separated with 12.10 Å at 103 K (Table S5, Supporting Information), although π–π stacks are formed between benzoate groups because of the in‐phase alignment (i.e., ⋅⋅⋅D⋅⋅⋅D⋅⋅⋅D⋅⋅⋅ or ⋅⋅⋅A⋅⋅⋅A⋅⋅⋅A⋅⋅⋅) along the <001> direction (blue circles in Figure ).

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Crystal structure of 1‐DCE at 103 K. a) Thermal ellipsoid plot showing the formula unit and atom numbering scheme. Displacement ellipsoids are drawn at a 50% probability level. Gray bond indicates the minor component of the positional disorder. Packing diagrams projected along the b) <110> direction (chain‐running direction), c) c axis (top view of the chain layer), and d) <1−10> direction (side view of the chain layer). Blue, red, gray, green, and purple represent N, O, C, F, and Ru, respectively. Hydrogen atoms and crystal solvents in (a) are omitted for clarity. Crystal solvents in (b)–(d) are colored in cyan. Connolly surfaces are also depicted in (d).

The RuO_eq length (O_eq = equatorial oxygen atoms) was extremely sensitive to the oxidation state of the [Ru₂] unit. Typically, this length has been reported to be 2.06–2.07 Å for [Ru₂^II,II] and 2.02–2.03 Å for [Ru₂^II,III]⁺. Figure 2a plots the average RuO_eq bond length (Table S3, Supporting Information) as a function of temperature. At 270 K, the average RuO_eq bond length was 2.056(4) Å, indicative of the [Ru₂^II,II] oxidation state. As a result of cooling, the average bond length decreased to around 2.02 Å in the temperature range of 237–213 K. At temperatures less than 213 K, the RuO_eq bond length was maintained at ≈2.02 Å for [Ru₂^II,III]⁺. In addition, the axial bond length (RuN_ax), which was also sensitive to the oxidation state of the [Ru₂] unit, suddenly became shorter on cooling at temperatures less than 237 K (Table S3 (Supporting Information) and inset of Figure a). In addition, the RuRu bond length exhibited a small anomaly around 230 K (Table S3 (Supporting Information) and inset of Figure a).

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Variation in the structure of 1‐DCE as a function of temperature. a) Variation in the average RuOeq bond (Oeq = carboxylate oxygen atoms), where the inset shows the variations in the RuRu and RuNax bonds (Nax = cyano nitrogen atom of TCNQ(EtO)2). b) The degree of charge ρ on the TCNQ(EtO)2 subunit estimated by the Kistenmacher relationship.

The bond lengths in the TCNQ(EtO)₂ moieties reflected the oxidation state (ρ) of the TCNQ(EtO)₂ moieties (Table S4, Supporting Information), which can be typically evaluated using the Kistenmacher relationship: ρ = −{A[c/(b + d)] + B}, where b, c, and d are the CC bond distances between 7,9‐, 1,7‐, and 1,2‐positions in the TCNQ(EtO)₂ moiety, respectively, and the parameters A = −41.667 and B = 19.833 are determined by assuming a completely neutral form of TCNQ⁰ (ρ = 0) and a one‐electron‐reduced form Rb⁺TCNQ^•− (ρ = −1). Figure b plots the estimated ρ values at respective temperatures for 1‐DCE, indicating that the TCNQ(EtO)₂ moiety exhibits a quinonoid structure (N‐form) at room temperature, whereas it changes into a quasibenzenoid form (I‐form) on cooling at 230 K. Thus, the variation in the charge of TCNQ(EtO)₂ moiety is completely consistent with that observed for the [Ru₂] unit, confirming the occurrence of the one‐step N–I phase transition at 230 K.

The N–I phase transition in 1‐DCE was additionally confirmed by infrared absorption spectroscopy. Characteristic CN stretching modes (ν_CN) of TCNQ(EtO)₂ were observed at frequencies ranging from 2100 to 2250 cm⁻¹ (Figure 3a; heating process). At temperatures 300–230 K, ν_CN was observed as a single band at 2216 cm⁻¹ corresponding to the N‐state of TCNQ(EtO)₂ (e.g., 2221 cm⁻¹ for free TCNQ(EtO)₂). However, at temperatures less than 225 K, two new bands were observed at 2188 and 2161 cm⁻¹, corresponding to the characteristic ν_CN for the I‐state of TCNQ(EtO)₂^•− (e.g., 2199 and 2172 cm⁻¹ for the anion radical salt Li⁺TCNQ(EtO)₂^•−). The variation in the temperature of the normalized peak intensities for the respective peaks exhibited an inflection point at 220–225 K (Figure b). This temperature variation is in good agreement with that observed for structures. A similar trend was observed for the CC stretching mode (ν_CC) (Figure S2, Supporting Information).

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a) Infrared absorption spectra of 1‐DCE at wavenumbers ranging from 2000 to 2300 cm−1 measured using a Nujol mull, wherein the band at 2216 cm−1 corresponds to the ν(CN) of neutral TCNQ(EtO)2 moieties and the bands at 2161 and 2188 cm−1 correspond to the ν(CN) of ionic TCNQ(EtO)2 moieties. b) Temperature dependence of peak intensities.

The most notable feature of 1‐DCE is that a ferrimagnetic 1D correlation can be observed between the I‐phase of 1‐DCE with S = 3/2 for [Ru₂^II,III]⁺ and S = 1/2 for TCNQ(EtO)₂^•−, whereas the N‐phase is paramagnetic with S = 1 for [Ru₂^II,II]. The χT product of 1‐DCE at 300 K was 1.34 cm³ K mol⁻¹. This value is in good agreement with the typical value observed for the isolated [Ru₂^II,II] species with S = 1. With decreasing temperature, the χT product monotonically decreased because of the effect of the anisotropic nature of [Ru₂^II,II]; however, it suddenly increased from 1.22 cm³ K mol⁻¹ at 250 K to 1.87 cm³ K mol⁻¹ at 200 K, and gradually to 6.01 cm³ K mol⁻¹ at 18 K, followed by an abrupt decrease to 0.52 cm³ K mol⁻¹ at 1.8 K (Figure 4a). In addition, this sudden shift of χT can be observed in the χ–T plot (see inset of Figure a), indicating the occurrence of the N–I phase transition with a magnetic change from isolated paramagnetic spins to ferrimagnetically correlated spins. By taking d(χT)/dT (peak top), T_c was determined to be 230 K (Figure a). The χ and χT data were simulated at temperatures ranging from 110 to 190 K using an alternating chain model with S_i = 3/2 and S_i+1 = 1/2 in the Hamiltonian H = −2JΣ^N_i=1S_i·S_i+1, and an adequate parameter set was obtained as g_[Ru2] = 2.181(2); g_Rad = 2.0 (fix); and J/k_B = −105.2(6) K (Figure a). The spins of [Ru₂^II,III]⁺ and TCNQ(EtO)₂^•− were strongly antiferromagnetically coupled, and the magnitude of J was in good agreement with that reported previously for chain compounds. The strong antiferromagnetic coupling can be caused by a considerable overlap between the frontier π* singly occupied molecular orbital (SOMO) of [Ru₂^II,III]⁺ and the π* SOMO of TCNQ(EtO)₂^•−. The 1D correlated spins eventually led to antiferromagnetic long‐range ordering at T_N = 9.6 K related to the presence of the interchain antiferromagnetic interactions (vide infra), similar to the ionic D⁺A⁻ chain, [Ru₂(4‐Cl‐2‐MeOPhCO₂)₄(BTDA‐TCNQ)]·n(solv). This result was confirmed by the AC susceptibility data (Figure S3a, Supporting Information); an H–T phase diagram (Figure b) was constructed using the data obtained from the field‐cooled magnetization (FCM) measured at several DC fields (Figure S3b, Supporting Information) and the field dependence of the magnetization measured at several temperatures (Figure S3c, Supporting Information). Using the mean‐field approximation with an effective spin S_eff = S_[Ru2] −S_Rad = 1, the interchain interaction was found to be zJ′/k_B = −0.27 K based on the equation 2|zJ′|S_eff² ≈ gS_effμ_BH_ex, with a spin‐flipping field H_ex = 0.40 T at 1.8 K and g = 2 (Figure S3c, Supporting Information) although zJ′ was only useful for comparison.

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a) Temperature dependence of χT and −dχT/dT for 1‐DCE measured under a DC field of 1 kOe. Inset shows the temperature dependence of χ for temperatures ranging from 100 to 300 K. The solid line represents the best‐fit line with an alternating chain model of Si = 3/2 and Si+1 = 1/2 for the data at temperatures ranging from 110 to 190 K. b) H–T phase diagrams of 1‐DCE in the low‐temperature region.

Compound 1‐DCE was relatively stable even at room temperature compared with the first N–I transition compound; however, it gradually released the interstitial DCE molecules with increasing temperature under N₂, thereby affording DCE‐free compound (1). Compound 1 was considerably stable at high temperatures up to 450 K and simultaneously maintained its crystallinity as evidenced by thermogravimetric analysis (TGA) (Figure S4, Supporting Information). In addition, 1 could be prepared by evacuation at room temperature. Time‐course measurements for room temperature powder X‐ray diffraction patterns (PXRDs) under vacuum demonstrated that the structure undergoes a gradual, continuous modification over several days (Figure 5). Most of the diffraction peaks for 1 were almost identical with those in 1‐DCE, whereas some new peaks were observed for 1, leading to twice the cell volume (see below). The structure of 1 was considered to be a superstructure of 1‐DCE.

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Time‐course variations in the powder X‐ray diffraction (PXRD) pattern of 1‐DCE with evacuation at 298 K. a) PXRD patterns and b) time dependence of the peak A for 1‐DCE (in red) and peak B for 1 (in blue).

Although the unit cell contained two crystallographically unique DA pairs (distinguished hereafter as α‐ and β‐pairs), 1 also crystallized in the triclinic P‐1 space group (Tables S1–S5, Supporting Information), wherein the inversion centers were located at the midpoint of the RuRu bond and center of the TCNQ(EtO)₂ moiety in the respective DA pairs (Z = 2, Figure 6a). Hence, two crystallographically unique chains, α‐ and β‐chains, exist in a crystal. Both the chains ran along the <01−1> direction to form a chain layer on the (011) plane (Figure b,c). Within the chain layer, the α‐ and β‐chains were alternately arranged in an antiphase manner (i.e., ⋅⋅⋅D^α⋅⋅⋅A^β⋅⋅⋅D^α⋅⋅⋅A^β⋅⋅⋅ or ⋅⋅⋅A^α⋅⋅⋅D^β⋅⋅⋅A^α⋅⋅⋅D^β⋅⋅⋅) along the <100> direction with an interchain π‐stack as observed for 1‐DCE (red circles in Figure b), leading to a shorter [Ru₂]⋅⋅⋅TCNQ distance of 6.82 Å at 103 K (centroid to centroid) compared with that in 1‐DCE. 1D void space channels with a solvent‐accessible volume of 159 ų (6.4%) at 103 K were retained between the chain layers after the release of the DCE molecules from 1‐DCE, which ran along the <100> direction, i.e., perpendicular to the chain‐running direction (Figure c shows the Connolly surfaces). Thus, the interchain layers aligned in an in‐phase manner along the <011> direction (i.e., ⋅⋅⋅D^α⋅⋅⋅D^β⋅⋅⋅D^α⋅⋅⋅D^β⋅⋅⋅ or ⋅⋅⋅A^α⋅⋅⋅A^β⋅⋅⋅A^α⋅⋅⋅A^β⋅⋅⋅) are significantly separated by 11.71 Å at 103 K (Figure c) although the π‐stacks are still present between the benzoate groups (blue circles in Figure b). Thus, the orientation of DA unit is slightly modified by the desolvation for canceling the vacancy originally made by DCE in 1‐DCE. Since the chain layer comprised compact chains, only half of the void space canceled without any significant change in the interchain relationship.

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Crystal structure of 1 at 103 K. a) Thermal ellipsoid plot showing the formula unit and atom numbering scheme for α‐ (top) and β‐units (bottom). Displacement ellipsoids are drawn at a 50% probability level. Gray bond indicates the minor component of the positional disorder: Packing diagrams projected along the b) <01−1> direction (chain‐running direction) and c) a axis (side view of the chain layer). Blue, red, gray, green, and purple represent N, O, C, F, and Ru, respectively. Hydrogen atoms are omitted for clarity. Connolly surfaces are also depicted in (c).

Temperature variation was the most important aspect in the structure of 1. The average RuO_eq bond lengths for the α‐ and β‐chains in 1 were in the range of [Ru₂^II,II] in the entire temperature range investigated (103–270 K) (Table S3, Supporting Information). Corresponding to the oxidation state of [Ru₂^II,II], the charge of the TCNQ(EtO)₂ moieties corresponded to the neutral form at all the investigated temperatures (Table S4, Supporting Information). Hence, the α‐ and β‐chains in 1 are in the N‐state at T ≥ 103 K, which is completely different from the observation of the N–I phase transition in 1‐DCE. This result was confirmed by the temperature variation of infrared (IR) spectra of 1 (Figure S5, Supporting Information).

A microcrystal sample of 1‐DCE in a gelatin capsule was inserted into an MPMS‐7X system (Quantum Design Ltd), and in situ magnetic measurements with stepwise desolvation treatment were conducted. After the measurement of the fresh 1‐DCE sample (Figure ), it was desolvated in situ by evacuation for a designated time at 310 K. After evacuation, the cell was filled with He gas to enhance the thermal conductivity, and the FCM under a field of 1 kOe was recorded from 300 K (Figure 7a). With desolvation, the T_c continuously shifted to lower temperatures than the original T_c = 230 K (Figure b) although the temperature width for the N–I transition slightly increased (obtained from the dχT/dT–T plot; Figure S6, Supporting Information), and the peaks in the χT–T plots certainly decreased. After evacuating for 18 h, the T_c was no longer detected from the dχT/dT–T plot because of the absence of peaks (Figure S6, Supporting Information). The peak in the χ–T plots (Figure S7a, Supporting Information) depicted that the desolvation gradually progressed after the 18 h evacuation. However, it was almost completed after the evacuation for 96 h (Figure S7b, Supporting Information); the final χT–T feature was observed for 1 with the isolated [Ru₂^II,II] species. The magnetic behavior of 1 was interpreted as a typical case for the [Ru₂^II,II] species with S = 1 considering the zero‐field splitting (D), the temperature‐independent paramagnetism (χ_TIP), and an impurity with S = 3/2(ρ_imp) (Figure S8, Supporting Information).

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Time‐course magnetic variation of 1‐DCE. a) χT–T plots measured at 1 kOe. b) Time dependence of the N–I transition temperature defined by the temperature at which a peak appears in the −dχT/dT versus T plots. Error bar indicates the temperature width for the N–I phase transition defined by the half‐width of the peak in the −dχT/dT versus T plots. c) Variation in the χT–T plots measured at 1 kOe by the transformation between 1‐DCE and 1 by desorption/sorption (SD) cycles. Inset shows the χT value at 18 K for each step.

Desolvated compound 1 completely reverted to 1‐DCE by the resolvation of DCE. With the exposure of 1 to a DCE vapor for 72 h at 298 K in a sealed MPMS cell, the magnetic behavior of the compound (denoted as 1‐DCE′) was essentially the same as that of the original 1‐DCE (Figure c and Figure S9 (Supporting Information)). These results indicated that both 1‐DCE and 1 undergo excellent reversibility between a spin‐correlated system with the N–I phase transition (1‐DCE) and a paramagnetic system (1) by the application of SD treatments; a magnetic switch via SD cycles was demonstrated (inset of Figure c).

A DCE vapor adsorption isotherm at 298 K revealed that 1 adsorbs ≈1 mole of DCE (Figure S10, Supporting Information), which is consistent with the formula of 1‐DCE. This reversibility can be confirmed by the structural change; the PXRD pattern of 1 changed to its original pattern for 1‐DCE by exposing 1 to DCE vapor for 24 h (Figure a).

The pressure variation of the N–I phase transitions of 1‐DCE was investigated by applying hydrostatic pressure using a piston‐cylinder‐type cell made of CuBe alloy in a SQUID magnetometer. Figure S11a–c (Supporting Information) shows the temperature dependence of the magnetization under various applied pressures, and Figure S11d (Supporting Information) shows the diagram of pressure versus T. The T_c was dependent on the hydrostatic pressure. Even at low pressures of less than 1 kbar, T_c sensitively shifted to high temperature and exceeded the upper limit of the measurement temperature range. We also applied pressures up to 10.5 kbar to 1, though, magnetic properties remained unchanged.

The electronic state of simple charge‐transfer complexes is approximately represented as follows$$E=\left(I_{\mathrm{D}}-E_{\mathrm{A}}\right)-\alpha V$$where V is the Coulombic attractive force (>0) between the nearest DA pairs, and α is the Madelung constant depending on the crystal structure. The N‐ and I‐ phases were expected in the regimes (I_D − E_A) > αV and (I_D − E_A) < αV, respectively, and the N–I transformation was expected to occur at (I_D − E_A) = αV. As I_D and E_A are the basic intrinsic parameters for D and A, respectively, the (I_D − E_A) value could be the same between 1‐DCE and 1. In contrast, the Madelung energy αV was extremely sensitive to structural changes, i.e., the orbital overlap between the D and A units; with the increasing overlap, the αV value tended to increase and vice versa. The application of hydrostatic pressures to 1‐DCE, which possibly increased the orbital overlap between the D and A units, and the distance between D and A, promoted the shift of the N–I transition boundary to high temperatures (Figure S11d, Supporting Information). In particular, the orbital overlap in 1 has been proposed to decrease from that in 1‐DCE via desolvation. A simple structural comparison between 1‐DCE and 1 revealed that the chain form of 1‐DCE is considerably more linear than that of 1, indicative of a larger overlap between the π* orbitals of TCNQ(EtO)₂ and the [Ru₂] core for 1‐DCE. To evaluate this hypothesis, an angular overlap model was considered (Table S3, Supporting Information). The angular part of π components (A_π) that can overlap between [Ru₂^II,II] π* and TCNQ(EtO)₂π* was expressed as A_π = {1 − (sinδ·sinτ)²}^0.5, where δ represents the RuNC angle and τ represents the dihedral angle between the least‐square planes composed of CC(CN)₂ and RuRuNCC (Table S3, Supporting Information). The crystal structure for 1‐DCE at 270 K (N‐phase) exhibited A_π = 1.00, whereas the structure for 1 at 270 K exhibited A_π = 0.95 and 0.97 for α‐ and β‐chain, respectively (Table S3, Supporting Information). Compound 1 exhibited a less‐overlapped form. The structural deformation induced by the desolvation slightly weakened the CT interactions in 1, leading to the suppressed N–I phase transition. As described above, even a subtle structural difference is crucial for the observation of the N–I phase transition in covalently bonded DA chain systems, possibly explaining the inability of applied pressure to induce the N–I phase transition in 1 although 1‐DCE is extremely sensitive to pressure (Figure S11d, Supporting Information).