Preliminary observations of the interplay of radiation damage with spin crossover

Chernyshov, D.; Dyadkin, V.; Törnroos, K.W.

doi:10.1107/S205252062200467X

Hans-Beat Bürgi tribute

STRUCTURAL SCIENCE
CRYSTAL ENGINEERING
MATERIALS

ISSN: 2052-5206

Volume 78| Part 3| June 2022| Pages 392-396

https://doi.org/10.1107/S205252062200467X

Preliminary observations of the interplay of radiation damage with spin crossover

Dmitry Chernyshov,^a ^* Vadim Dyadkin ^a and Karl Wilhelm Törnroos ^b

^aSwiss–Norwegian BeamLines at the European Synchrotron Radiation Facility, 38000 Grenoble, France, and ^bDepartment of Chemistry, University of Bergen, Allégaten 41, 5007 Bergen, Norway
^*Correspondence e-mail: dmitry.chernyshov@esrf.fr

Edited by S. Grabowsky, University of Bern, Switzerland (Received 22 November 2021; accepted 2 May 2022; online 28 May 2022)

Intense synchrotron radiation makes time-resolved structural experiments with increasingly finer time sampling possible. On the other hand, radiation heating, radiation-induced volume change and structural disorder become more frequent. Temperature, volume change and disorder are known to be coupled with equilibrium in molecular spin complexes, balancing between two or more spin state configurations. Combining single-crystal diffraction and synchrotron radiation it is illustrated how the radiation damage and associated effects can affect the spin crossover process and may serve as yet another tool to further manipulate the spin crossover properties.

Keywords: radiation damage; synchrotron radiation; spin crossover compound.

CCDC references: 2169944; 2169945; 2169946

1. Introduction

Some octahedral complexes of 3d block transition metals can be found in a few stable electronic states. Thus, for Fe²⁺ the Low Spin (LS) configuration is less degenerate than the High Spin (HS) state and the entropy difference makes the HS states energetically favourable if the temperature is sufficiently high (Nicolazzi & Bousseksou, 2018 ).

The change of the spin state can alter colour, magnetization, density, crystal and molecular structures; this is why spin crossover materials are considered to be useful for many applications, ranging from medicine to electronics (Murray, 2013 ). Spin crossover phenomena are also of fundamental interest as they deal with complex spatio-temporal responses of interacting molecular complexes to external perturbations. The structure and properties of an individual spin-active molecule can be well understood through quantum chemistry, providing that intermolecular interactions are reduced to a mean-field (Paulsen et al., 2013 ). The interactions between molecular units may be modelled with mechanistic toy models based on Ising-like Hamiltonians [electro-lattice models, e.g. Ndiaye et al. (2021 )], as by its very nature this approach neglects many intra-molecular degrees of freedom. For any real spin crossover material however, change of properties associated with the change of spin states can neither be reduced to a behaviour of an isolated individual molecule nor simplified to mechanistic models; this is why, together with theoretical modelling, the structural experiment remains the most important source of information on the microscopic processes comprising spin crossover phenomena (Pillet, 2021 ).

Synchrotron radiation offers unique tools to characterize spin crossover, in particular fast diffraction probes of the crystal structure as a function of temperature, pressure, laser irradiation and any other external perturbation that may change the spin state (Collet & Guionneau, 2018 ). Switching of the spin state by high-energy X-ray radiation (synchrotron) is also reported (Vankó et al., 2007 ). However, synchrotron radiation interacts with matter in a complex way (Bras et al., 2021 ). Radiation heating (Lawrence Bright et al., 2021 ), radiation damage (Bogdanov et al., 2021 ), radiation-induced volume change (Coates et al., 2021 ) and structural disorder (Christensen et al., 2019 ) exemplify some of the radiation-induced phenomena commonly observed. With temperature, volume change, and disorder known to be linked to the spin equilibrium; thus far we are not aware of any reports on radiation damage as a mechanism to influence the spin states in spin crossover materials. Here we present, as a first step, a spin crossover scenario for radiation-damaged [Fe²⁺(tame)₂]Br₂·MeOH [tame = 1,1,1-tris(aminomethyl)ethane], derived from a multi-temperature (60 data sets) single-crystal synchrotron diffraction experiment and the ensuing sequential structure refinement.

2. Experiment

Data were collected at the BM01 end station of the Swiss-Norwegian Beamlines, at the ESRF (Grenoble, France), with the Pilatus@SNBL diffractometer (Dyadkin et al., 2016 ). The temperature was controlled with a Cryostream 700+, with diffraction data measured every 3 K on cooling in a range of 260–83 K with λ = 0.78405 Å (15.8 keV) with a single axis full rotation and one second per one degree sampling. The temperature range was expected to cover the full spin state change, from nearly pure HS to nearly pure LS state, based on a previous report for Cl-based analogue (Bernhardt et al., 2018 ). The data were processed sequentially with CrysAlis Pro software (Rigaku, 2015 $[Rigaku Oxford Diffraction (2015). CrysAlis Pro, Version 1.171.38.41. Rigaku Oxford Diffraction, Yarnton, England.]$ ), the initial structural model was derived with SHELXT (Sheldrick, 2015a ) and then refined with SHELXL (Sheldrick, 2015b ) in a sequential manner, as described by Chernyshov et al. (2019 ) and Bogdanov et al. (2021). Representative parameters characterizing the data at 257 (2) K and refinement are given in the Table 1.

Table 1
Crystal data and structure refinement at 257 K

Empirical formula	C₁₁H₃₄Br₂FeN₆O
Formula weight	482.11
Temperature	257 (2)
Wavelength (Å)	0.78405
Crystal system, space group	Trigonal, $[R {\bar 3}m: H]$
Unit-cell dimensions, a (=b), c, γ (Å, °)	7.3806 (2), 31.5783 (16), 120
Volume (Å³)	1489.71 (2)
Z, calculated density (Mg m⁻³)	4, 1.612
Absorption coefficient (mm⁻¹)	6.110
F(000)	738
Crystal size (mm)	0.16 × 0.220 × 0.240
Theta range (°) for data collection	2.134–29.331
No. of reflections collected, unique, R_int	2292, 393, 0.0074
Completeness to θ = 28.062°	94.8
Refinement method	Full-matrix least-squares on F²
No. of data, restraints, parameters	397, 1, 33
Goodness-of-fit on F²	1.234
Final R indices [I > 2σ(I)]	R1 = 0.0379, wR2 = 0.1074
R indices (all data)	R1 = 0.0381, wR2 = 0.1076
Largest difference peak and hole (e Å⁻³)	0.437, −0.582

The crystal structure is found to be disordered, for both the MeOH solvent molecule and also for the spin-crossover unit.

As shown by previous DFT calculations (Bernhardt et al., 2018), the [Fe(tame)₂]²⁺ cation is stabilized by a torsional libration of the each tripodal claw about its C3 axis onto either side of the vertical glide plane hosting an aminomethylene arm. The disorder is fixed by symmetry and we observe neither additional Bragg reflections nor diffuse scattering indicating long- or short-range ordering of the spin-active cations. The crystal structure is layered, with layers of the [Fe(tame)₂]²⁺ cations and the Br⁻ anions separated by layers of the disordered MeOH solvent molecules; all the layers are orthogonal to the threefold c-axis, isomorphous to the Cl analogue (Bernhardt et al., 2018), see Fig. 1 (left). One more sign of disorder is the apparent C—N distances (1.45 Å at 275 K) that are lower than expected 1.49 Å and abnormally decrease on cooling (1.41 Å at 83 K) together with ADPs. The quality of refinement was progressively degraded on cooling together with an increase of the anisotropic displacement parameters (ADPs) for all atoms (Figs. 1 and 2). However, R_int values were practically the same for the all data sets. R_int is normally examined during in situ synchrotron experimentation to characterize the data quality, we see that monitoring of this descriptor only is not sufficient to detect radiation damage effects.

Figure 1
Top left: molecular structure of the spin-active cation [Fe(tame)₂]²⁺ and Fe—N bond distances characteristic for HS (257 K) and LS (83 K) states, hydrogen atoms are omitted for clarity. Right: ionic layers of [Fe(tame)₂]²⁺ cations and Br⁻ anions separated by van der Waals layers of ligands and disordered solvent. Bottom left: ionic layers with Br⁻ anions (red) and spin-active molecules, with ADPs at the 80% level, at the end (83 K) and at the beginning (257 K).

Figure 2
(Left) Isotropic displacement parameters for Fe and Br atoms. (Right) ADPs from C1 (top and bottom terminal atoms of the spin crossover cation, see Fig. 1

3. Results

3.1. Unit-cell dimensions

The isomorphous [Fe²⁺(tame)₂]Cl₂·MeOH (Bernhardt et al., 2018) shows an expected volume contraction upon cooling with spin conversion towards the LS state. In accordance with the layered structure the contraction is mostly seen along the c-axis, while the a-axis is practically invariant. Conversely, the Br analogue, studied here subject to radiation damage, shows a very different behaviour (Fig. 3). The volume thermal contraction changes to an expansion at ≈ 160 K and at 80 K we observe a unit-cell volume similar to that at 250 K. Note that the dose of absorbed radiation was accumulated upon cooling and that the volume expansion can therefore be related to radiation damage, similar to what was observed previously (Coates et al., 2021).

Figure 3
Volume and unit-cell dimensions as functions of temperature. (Left) unit-cell volume (Å³). (Center) a-axis (Å). (Right) c-axis (Å).

Unit-cell dimensions however behave anisotropically, the more rigid intra-layer a-direction stays nearly constant down to 200 K and then expands at lower temperatures. The inter-layer c-direction contracts down to 150 K and then slowly increases. Such a behaviour suggests that the radiation damage induces some atomic displacements, firstly along the layer planes and then normal to layer direction.

3.2. Bonds and spin states

Conversion from LS to HS leads to an elongation of the Fe—N bonds by ≈ 0.15 Å. For the average structure, the Fe—N bonds change their length with temperature as a function of spin state. The temperature dependence of the Fe—N bonds therefore characterizes a transition scenario. A crossover between HS and LS states was observed for the Cl analogue with Fe—N bonds changing from 2.035 Å (LS) to 2.189 Å (HS) (Bernhardt et al., 2018). An overlay of previously reported data with those for [Fe²⁺(tame)₂]Br₂·MeOH shows a very different behaviour for the latter, suffering from radiation damage (Fig. 4). We assume that radiation damage slows down the spin conversion. One may expect that the temperature of the spin state equilibrium, T1_1/2, is higher for the Br-based compound in comparison with the Cl analogue. Such a trend is also reported for other SCO materials (Kuroda-Sowa et al., 2017 ; Lemercier et al., 2006 ). The scenario observed here may therefore be seen as a radiation-induced crossover between two transition curves as schematically shown in Fig. 4.

Figure 4
(Left) Fe—N bond distance as a function of temperature for the Cl (blue) and Br (red) analogues. (Right) HS fraction as a function of temperature, points with error bars are calculated from the bond lengths, the solid line represents a model curve derived by Bernhardt et al. (2018

), the dashed curve shows a possible transition scenario for the Br analogue without radiation damage.

4. Conclusion

The present finding are preliminary observations of a truly interesting phenomenon that needs further work to be properly understood, rationalized, and controlled.

The wavelength (0.7805 Å), of the synchrotron radiation was relatively close to the Br absorption edge (0.9202 Å), and the data collected upon cooling show the effect of the radiation dose accumulated progressively with time and temperature. The radiation damage manifests itself in the anisotropic expansion of the unit cell with a dose increase that overcompensates the expected temperature and spin-state related thermal contraction. An increase of the ADPs for all atoms with dose on cooling also serves as an indication of the disorder induced by the radiation, in agreement with the previous reports (Christensen et al., 2019).

We observed that the radiation damage slows down the spin conversion and a final LS state is reached at lower temperatures than expected. This effect may tentatively be attributed to the volume effects which were previously seen with an applied pressure (Gütlich et al., 2005 ). Indeed, application of a pressure normally favours formation of the LS states with its shorter Fe—N bonds shifting the transition curve to higher temperatures. It follows from Fig. 4 that the radiation-induced increase of the unit-cell volume might therefore favour HS extended states shifting the transition curve to lower temperatures.

There still are many questions to be answered in future experimental studies. A precise control of the absorbed dose and a dose rate on the spin conversion has to be studied, either via measurement of the transmission or using estimates similar to the reported recently (Christensen et al., 2019). The increase of the ADPs with the absorbed dose may be used as an internal structural measure of the degree of damage. It would be necessary to combine the dose accumulation at the energy close to an absorption edge with the data collection at lower or much higher energies of the X-ray radiation; such a scheme allows for the study of the crystal structure with temperature for a given dose and to avoid accumulation of the radiation damage during the data acquisition. The light-induced spin state trapping (LIESST) and relaxation processes in radiation-damaged samples also need to be probed; the interplay of radiation-induced disorder with generation, growth and decay of photo-excited spin states thus still remain to be uncovered.

A link between spin state switching and radiation-induced disorder can be mapped with a help of Ising-like model for spin crossover with structural disorder (Chernyshov et al., 2007 ). This approach assumes that radiation-induced disorder merely shifts energy levels for HS and LS states, and the energy levels become dose dependent, see Appendix A for details.

All together these findings show that it is possible to have a low temperature LS state with the volume as large as for the virgin HT, HS state, and possibly record different transition scenarios for the same material but with different degrees of the radiation damage. The radiation damage can therefore play a constructive role as a tuning parameter for the premeditated control of SCO properties.

APPENDIX A

Phenomenological consideration of the radiation damage and spin equilibrium.

With an Ising-like model of spin crossover, the interactions between spin active molecules are given by the following Hamiltonian:

$[H_{0} = \Delta\sum\sigma_{i}+\sum J_{ij}\sigma_{i}\sigma_{j}, \eqno(1)]$

where σ_i is a pseudo spin (+1 for HS and −1 for LS state at the node i), Δ is the free energy difference between two states, and J_ij is an effective interaction constant.

$[\Delta = \Delta h-T\Delta s, \eqno(2)]$

where Δh and Δs are the enthalpy and entropy costs associated with a spin switch at single non-interacting site, respectively. In the mean field approximation, the single-site Hamiltonian reads:

$[h_{0} = \Delta\sigma+J\sigma\langle\sigma\rangle.\eqno(3)]$

Here every spin-active molecule is considered as a two-level system and surrounding spin states are replaced by the average value 〈σ〉:

$[\eqalign{E_{-1}& = -\Delta-J\langle\sigma\rangle\cr E_{+1}& = \Delta+J\langle\sigma\rangle} \eqno(4)]$

More information on the model and its current development can be found in the work by Pavlik & Linares (2018 ), here we focus on the possible effect of the disorder induced by radiation.

First, we assume that the radiation-induced disorder can be represented by an average value, 〈S〉 and that its effects can be approximated as an effective mean field:

$[h_{1} = \Delta\sigma+J\sigma\langle\sigma\rangle+K\sigma\langle S\rangle, \eqno(5)]$

where K is the corresponding effective coupling constant. This assumption implies that (i) radiation damage happens in uncorrelated/non-cooperative fashion, and (ii) the kinetics of spin conversion is much faster than that for the damage. The energy levels are now modified:

$[\eqalign{E_{-1}& = -\Delta-J\langle\sigma\rangle-K\langle S \rangle\cr E_{+1}& = \Delta+J\langle\sigma\rangle+K\langle S\rangle.} \eqno(6)]$

The expectation value for the spin-state operator is given by

$[\langle\sigma\rangle = \tanh\left({{K\langle S\rangle+J\langle\sigma\rangle- \Delta H+T\Delta S} \over {T}}\right), \eqno(7)]$

where 〈S〉 is an average measure of radiation-induced disorder, it depends on dose, dose rate, temperature, energy of radiation, composition, density and structure of the material, even an approximate form of these dependencies is not known. For the considered case of harvesting the dose on cooling, we simply assume that 〈S〉 increases while temperature decreases, 〈S〉 ≈ α(T_start − T). The numerical solutions of equation (7) are shown in Fig. 5, it is qualitatively mimicking the real scenario. Higher-order polynomial functions for the increase of disorder on cooling might be helpful for a quantitative modelling of the real scenario.

Figure 5
(Left) Expectation value 〈σ〉 as a function of temperature, red curve: ΔH = 400 K, ΔS = 2, no disorder, violet curve: ΔH = 300 K, ΔS = 2, no disorder, black curve: ΔH = 400 K, ΔS = 2, the disorder above T_st = 300 K is modelled with α = 0.1, K = 4 K; J = 100 K for all curves. (Right) a measure of radiation-induced disorder as a function of temperature.

The theoretical approach given above might also be interesting for radiation damage alone and for studying the effect of radiation on various structural processes that are frequently modelled with Ising-like models; order–disorder phase transitions, magnetic ordering and gas uptake by porous solids may serve as examples to be tested.

Supporting information

CCDC references: 2169944; 2169945; 2169946

Crystal structure: contains datablocks 1st_257K, 1st_152K, 1st_083K. DOI: https://doi.org/10.1107/S205252062200467X/wu5003sup1.cif

Structure factors: contains datablock 1st_257K. DOI: https://doi.org/10.1107/S205252062200467X/wu50031st_257Ksup3.hkl

Structure factors: contains datablock 1st_152K. DOI: https://doi.org/10.1107/S205252062200467X/wu50031st_152Ksup4.hkl

Structure factors: contains datablock 1st_083K. DOI: https://doi.org/10.1107/S205252062200467X/wu50031st_083Ksup5.hkl

Computing details top

For all structures, program(s) used to refine structure: SHELXL2014/7 (Sheldrick, 2014).

(1st_257K) top

Crystal data top

C_8.25H_25.50Br_1.50Fe_0.75N_4.50O_0.75	D_x = 1.612 Mg m⁻³
M_r = 361.58	Synchrotron radiation, λ = 0.78405 Å
Trigonal, R3m:H	Cell parameters from 1661 reflections
a = 7.3806 (2) Å	θ = 2.1–32.1°
c = 31.5783 (16) Å	µ = 6.11 mm⁻¹
V = 1489.71 (11) Å³	T = 257 K
Z = 4	Hexagonal flat prism, colourless
F(000) = 738	0.24 × 0.22 × 0.16 mm

Data collection top

Abstract diffractometer	393 reflections with I > 2σ(I)
Radiation source: synchrotron	R_int = 0.007
ω scans	θ_max = 29.3°, θ_min = 2.1°
Absorption correction: multi-scan CrysAlisPro 1.171.39.46 (Rigaku Oxford Diffraction, 2018) Empirical absorption correction using spherical harmonics, implemented in SCALE3 ABSPACK scaling algorithm.	h = −8→9
T_min = 0.873, T_max = 1.000	k = −9→9
2292 measured reflections	l = −37→37
397 independent reflections

Refinement top

Refinement on F²	1 restraint
Least-squares matrix: full	Hydrogen site location: mixed
R[F² > 2σ(F²)] = 0.042	H-atom parameters constrained
wR(F²) = 0.123	w = 1/[σ²(F_o²) + (0.0806P)² + 2.6123P] where P = (F_o² + 2F_c²)/3
S = 1.23	(Δ/σ)_max = 0.009
397 reflections	Δρ_max = 0.60 e Å⁻³
33 parameters	Δρ_min = −0.66 e Å⁻³

Special details top

Geometry. All esds (except the esd in the dihedral angle between two l.s. planes) are estimated using the full covariance matrix. The cell esds are taken into account individually in the estimation of esds in distances, angles and torsion angles; correlations between esds in cell parameters are only used when they are defined by crystal symmetry. An approximate (isotropic) treatment of cell esds is used for estimating esds involving l.s. planes.

Fractional atomic coordinates and isotropic or equivalent isotropic displacement parameters (Å²) top

	x	y	z	U_iso*/U_eq	Occ. (<1)
C1	0.0000	0.0000	0.15095 (16)	0.0580 (16)
H1A	−0.1487	−0.0744	0.1613	0.087*
C2	0.0000	0.0000	0.10217 (14)	0.0379 (11)
C3	−0.1146 (3)	0.1146 (3)	0.08746 (9)	0.0517 (7)
H3A	−0.2479	0.0604	0.1037	0.062*	0.5
H3B	−0.0253	0.2696	0.0949	0.062*	0.5
C4	0.1671 (7)	0.5835 (3)	0.13760 (16)	0.079 (7)*	0.1667
H4A	0.2217	0.5910	0.1090	0.118*	0.0833
H4B	0.0947	0.6643	0.1387	0.118*	0.0833
H4C	0.0688	0.4373	0.1448	0.118*	0.0833
O1	0.3333	0.6667	0.1667	0.164 (6)
H1	0.3665	0.5729	0.1728	0.246*	0.0833
Fe1	0.0000	0.0000	0.0000	0.02883 (19)
Br1	0.3333	0.6667	0.03711 (2)	0.04913 (15)
N1	−0.1589 (4)	0.1059 (4)	0.04252 (7)	0.0374 (6)	0.5
H1B	−0.1336	0.2373	0.0339	0.045*	0.5
H1C	−0.3022	0.0129	0.0397	0.045*	0.5

Atomic displacement parameters (Å²) top

	U¹¹	U²²	U³³	U¹²	U¹³	U²³
C1	0.073 (2)	0.073 (2)	0.028 (2)	0.0366 (12)	0.000	0.000
C2	0.0450 (15)	0.0450 (15)	0.0236 (18)	0.0225 (8)	0.000	0.000
C3	0.0711 (7)	0.0711 (7)	0.0323 (11)	0.0500 (9)	0.0033 (6)	−0.0033 (6)
O1	0.183 (9)	0.183 (9)	0.126 (9)	0.091 (4)	0.000	0.000
Fe1	0.0327 (2)	0.0327 (2)	0.0210 (3)	0.01637 (12)	0.000	0.000
Br1	0.04825 (19)	0.04825 (19)	0.0509 (3)	0.02413 (10)	0.000	0.000
N1	0.0399 (11)	0.0402 (11)	0.0351 (11)	0.0224 (7)	0.0029 (10)	0.0032 (9)

Geometric parameters (Å, º) top

C1—C2	1.540 (7)	Fe1—N1^ix	2.169 (3)
C2—C3ⁱ	1.536 (3)	Fe1—N1ⁱⁱ	2.169 (3)
C2—C3ⁱⁱ	1.536 (3)	Fe1—N1^x	2.169 (3)
C2—C3	1.536 (3)	Fe1—N1^xi	2.169 (3)
C3—N1	1.451 (4)	Fe1—N1ⁱⁱⁱ	2.169 (3)
C3—N1ⁱⁱⁱ	1.451 (4)	Fe1—N1^xii	2.169 (3)
C4—O1	1.404 (3)	Fe1—N1^xiii	2.169 (3)
C4—C4^iv	1.841 (8)	Fe1—N1^xiv	2.169 (3)
C4—C4^v	1.841 (8)	Fe1—N1^xv	2.169 (3)
O1—C4^vi	1.404 (3)	Fe1—N1^xvi	2.169 (3)
O1—C4^vii	1.404 (3)	Fe1—N1ⁱ	2.169 (3)
O1—C4^iv	1.404 (3)	Fe1—N1	2.169 (3)
O1—C4^v	1.404 (3)	N1—N1ⁱⁱⁱ	0.391 (5)
O1—C4^viii	1.405 (3)

C3ⁱ—C2—C3ⁱⁱ	111.27 (18)	N1^ix—Fe1—N1^xiv	87.76 (13)
C3ⁱ—C2—C3	111.27 (18)	N1ⁱⁱ—Fe1—N1^xiv	92.24 (13)
C3ⁱⁱ—C2—C3	111.27 (18)	N1^x—Fe1—N1^xiv	85.72 (10)
C3ⁱ—C2—C1	107.60 (19)	N1^xi—Fe1—N1^xiv	94.28 (10)
C3ⁱⁱ—C2—C1	107.60 (19)	N1ⁱⁱⁱ—Fe1—N1^xiv	85.72 (10)
C3—C2—C1	107.61 (19)	N1^xii—Fe1—N1^xiv	94.28 (10)
N1—C3—N1ⁱⁱⁱ	15.5 (2)	N1^xiii—Fe1—N1^xiv	101.81 (14)
N1—C3—C2	116.5 (3)	N1^ix—Fe1—N1^xv	92.24 (13)
N1ⁱⁱⁱ—C3—C2	116.5 (3)	N1ⁱⁱ—Fe1—N1^xv	87.76 (13)
O1—C4—C4^iv	49.06 (18)	N1^x—Fe1—N1^xv	94.28 (10)
O1—C4—C4^v	49.06 (18)	N1^xi—Fe1—N1^xv	85.72 (10)
C4^iv—C4—C4^v	60.001 (1)	N1ⁱⁱⁱ—Fe1—N1^xv	94.28 (10)
C4—O1—C4^vi	180.0	N1^xii—Fe1—N1^xv	85.72 (10)
C4—O1—C4^vii	98.1 (4)	N1^xiii—Fe1—N1^xv	78.19 (14)
C4^vi—O1—C4^vii	81.9 (4)	N1^xiv—Fe1—N1^xv	180.00 (17)
C4—O1—C4^iv	81.9 (4)	N1^ix—Fe1—N1^xvi	85.72 (10)
C4^vi—O1—C4^iv	98.1 (4)	N1ⁱⁱ—Fe1—N1^xvi	94.28 (10)
C4^vii—O1—C4^iv	180.0	N1^x—Fe1—N1^xvi	101.81 (14)
C4—O1—C4^v	81.9 (4)	N1^xi—Fe1—N1^xvi	78.19 (14)
C4^vi—O1—C4^v	98.1 (4)	N1ⁱⁱⁱ—Fe1—N1^xvi	87.76 (13)
C4^vii—O1—C4^v	98.1 (4)	N1^xii—Fe1—N1^xvi	92.24 (13)
C4^iv—O1—C4^v	81.9 (4)	N1^xiii—Fe1—N1^xvi	85.72 (10)
C4—O1—C4^viii	98.1 (4)	N1^xiv—Fe1—N1^xvi	169.65 (13)
C4^vi—O1—C4^viii	81.9 (4)	N1^xv—Fe1—N1^xvi	10.35 (13)
C4^vii—O1—C4^viii	81.9 (4)	N1^ix—Fe1—N1ⁱ	94.28 (10)
C4^iv—O1—C4^viii	98.1 (4)	N1ⁱⁱ—Fe1—N1ⁱ	85.72 (10)
C4^v—O1—C4^viii	180.0	N1^x—Fe1—N1ⁱ	78.19 (14)
N1^ix—Fe1—N1ⁱⁱ	180.00 (17)	N1^xi—Fe1—N1ⁱ	101.81 (14)
N1^ix—Fe1—N1^x	169.65 (13)	N1ⁱⁱⁱ—Fe1—N1ⁱ	92.24 (13)
N1ⁱⁱ—Fe1—N1^x	10.35 (13)	N1^xii—Fe1—N1ⁱ	87.76 (13)
N1^ix—Fe1—N1^xi	10.35 (13)	N1^xiii—Fe1—N1ⁱ	94.28 (10)
N1ⁱⁱ—Fe1—N1^xi	169.65 (13)	N1^xiv—Fe1—N1ⁱ	10.35 (13)
N1^x—Fe1—N1^xi	180.00 (19)	N1^xv—Fe1—N1ⁱ	169.65 (13)
N1^ix—Fe1—N1ⁱⁱⁱ	101.81 (14)	N1^xvi—Fe1—N1ⁱ	180.00 (16)
N1ⁱⁱ—Fe1—N1ⁱⁱⁱ	78.19 (14)	N1^ix—Fe1—N1	94.28 (10)
N1^x—Fe1—N1ⁱⁱⁱ	85.72 (10)	N1ⁱⁱ—Fe1—N1	85.72 (10)
N1^xi—Fe1—N1ⁱⁱⁱ	94.28 (10)	N1^x—Fe1—N1	92.24 (13)
N1^ix—Fe1—N1^xii	78.19 (14)	N1^xi—Fe1—N1	87.76 (13)
N1ⁱⁱ—Fe1—N1^xii	101.81 (14)	N1ⁱⁱⁱ—Fe1—N1	10.35 (13)
N1^x—Fe1—N1^xii	94.28 (10)	N1^xii—Fe1—N1	169.65 (13)
N1^xi—Fe1—N1^xii	85.72 (10)	N1^xiii—Fe1—N1	180.0
N1ⁱⁱⁱ—Fe1—N1^xii	180.00 (16)	N1^xiv—Fe1—N1	78.19 (14)
N1^ix—Fe1—N1^xiii	85.72 (10)	N1^xv—Fe1—N1	101.81 (14)
N1ⁱⁱ—Fe1—N1^xiii	94.28 (10)	N1^xvi—Fe1—N1	94.28 (10)
N1^x—Fe1—N1^xiii	87.76 (13)	N1ⁱ—Fe1—N1	85.72 (10)
N1^xi—Fe1—N1^xiii	92.24 (13)	N1ⁱⁱⁱ—N1—C3	82.26 (10)
N1ⁱⁱⁱ—Fe1—N1^xiii	169.65 (13)	N1ⁱⁱⁱ—N1—Fe1	84.82 (7)
N1^xii—Fe1—N1^xiii	10.35 (13)	C3—N1—Fe1	118.1 (2)

C3ⁱ—C2—C3—N1	−53.7 (3)	C4^v—C4—O1—C4^iv	82.9 (3)
C3ⁱⁱ—C2—C3—N1	71.0 (2)	C4^iv—C4—O1—C4^v	−82.9 (3)
C1—C2—C3—N1	−171.34 (11)	C4^iv—C4—O1—C4^viii	97.1 (3)
C3ⁱ—C2—C3—N1ⁱⁱⁱ	−71.0 (2)	C4^v—C4—O1—C4^viii	180.001 (1)
C3ⁱⁱ—C2—C3—N1ⁱⁱⁱ	53.7 (3)	C2—C3—N1—N1ⁱⁱⁱ	−93.88 (7)
C1—C2—C3—N1ⁱⁱⁱ	171.34 (11)	N1ⁱⁱⁱ—C3—N1—Fe1	79.88 (14)
C4^iv—C4—O1—C4^vii	179.995 (1)	C2—C3—N1—Fe1	−14.01 (18)
C4^v—C4—O1—C4^vii	−97.1 (3)

Symmetry codes: (i) −y, x−y, z; (ii) −x+y, −x, z; (iii) −y, −x, z; (iv) −x+y, −x+1, z; (v) −y+1, x−y+1, z; (vi) −x+2/3, −y+4/3, −z+1/3; (vii) x−y+2/3, x+1/3, −z+1/3; (viii) y−1/3, −x+y+1/3, −z+1/3; (ix) x−y, x, −z; (x) −x+y, y, z; (xi) x−y, −y, −z; (xii) y, x, −z; (xiii) −x, −y, −z; (xiv) x, x−y, z; (xv) −x, −x+y, −z; (xvi) y, −x+y, −z.

(1st_152K) top

Crystal data top

C_8.25H_25.50Br_1.50Fe_0.75N_4.50O_0.75	D_x = 1.628 Mg m⁻³
M_r = 361.58	Synchrotron radiation, λ = 0.78405 Å
Trigonal, R3m:H	Cell parameters from 1210 reflections
a = 7.3869 (3) Å	θ = 3.6–32.5°
c = 31.2243 (14) Å	µ = 6.17 mm⁻¹
V = 1475.53 (14) Å³	T = 152 K
Z = 4	Hexagonal flat prism, colourless
F(000) = 738	0.24 × 0.22 × 0.16 mm

Data collection top

Abstract diffractometer	361 reflections with I > 2σ(I)
Radiation source: synchrotron	R_int = 0.007
ω scans	θ_max = 29.3°, θ_min = 2.2°
Absorption correction: multi-scan CrysAlisPro 1.171.39.46 (Rigaku Oxford Diffraction, 2018) Empirical absorption correction using spherical harmonics, implemented in SCALE3 ABSPACK scaling algorithm.	h = −8→8
T_min = 0.833, T_max = 1.000	k = −9→9
2246 measured reflections	l = −37→37
391 independent reflections

Refinement top

Refinement on F²	1 restraint
Least-squares matrix: full	Hydrogen site location: mixed
R[F² > 2σ(F²)] = 0.049	H-atom parameters constrained
wR(F²) = 0.141	w = 1/[σ²(F_o²) + (0.0871P)² + 5.7826P] where P = (F_o² + 2F_c²)/3
S = 1.09	(Δ/σ)_max = 0.032
391 reflections	Δρ_max = 0.76 e Å⁻³
33 parameters	Δρ_min = −0.51 e Å⁻³

Special details top

Fractional atomic coordinates and isotropic or equivalent isotropic displacement parameters (Å²) top

	x	y	z	U_iso*/U_eq	Occ. (<1)
C1	0.0000	0.0000	0.1505 (3)	0.085 (3)
H1A	−0.1487	−0.0744	0.1609	0.128*
C2	0.0000	0.0000	0.1010 (2)	0.0627 (19)
C3	−0.1135 (4)	0.1135 (4)	0.08615 (13)	0.0733 (11)
H3A	−0.2468	0.0604	0.1024	0.088*	0.5
H3B	−0.0242	0.2696	0.0935	0.088*	0.5
C4	0.1621 (7)	0.5811 (3)	0.13848 (17)	0.116 (13)*	0.1667
H4A	0.2074	0.5612	0.1102	0.174*	0.0833
H4B	0.1064	0.6763	0.1360	0.174*	0.0833
H4C	0.0532	0.4459	0.1496	0.174*	0.0833
O1	0.3333	0.6667	0.1667	0.199 (9)
H1	0.3665	0.5729	0.1728	0.299*	0.0833
Fe1	0.0000	0.0000	0.0000	0.0432 (3)
Br1	0.3333	0.6667	0.03682 (3)	0.0686 (2)
N1	−0.1539 (6)	0.1033 (6)	0.04134 (10)	0.0595 (10)	0.5
H1B	−0.1287	0.2346	0.0327	0.071*	0.5
H1C	−0.2973	0.0103	0.0385	0.071*	0.5

Atomic displacement parameters (Å²) top

	U¹¹	U²²	U³³	U¹²	U¹³	U²³
C1	0.101 (4)	0.101 (4)	0.053 (4)	0.051 (2)	0.000	0.000
C2	0.073 (3)	0.073 (3)	0.043 (3)	0.0363 (13)	0.000	0.000
C3	0.0899 (13)	0.0899 (13)	0.055 (2)	0.0560 (15)	0.0045 (10)	−0.0045 (10)
O1	0.227 (13)	0.227 (13)	0.144 (13)	0.113 (6)	0.000	0.000
Fe1	0.0469 (4)	0.0469 (4)	0.0357 (5)	0.02344 (18)	0.000	0.000
Br1	0.0680 (3)	0.0680 (3)	0.0697 (5)	0.03399 (14)	0.000	0.000
N1	0.0616 (18)	0.0672 (19)	0.0546 (18)	0.0359 (11)	0.0017 (16)	0.0050 (16)

Geometric parameters (Å, º) top

C1—C2	1.548 (11)	Fe1—N1^ix	2.100 (4)
C2—C3	1.523 (5)	Fe1—N1ⁱⁱ	2.100 (4)
C2—C3ⁱ	1.523 (5)	Fe1—N1^x	2.100 (4)
C2—C3ⁱⁱ	1.523 (5)	Fe1—N1^xi	2.100 (4)
C3—N1	1.425 (5)	Fe1—N1ⁱⁱⁱ	2.100 (4)
C3—N1ⁱⁱⁱ	1.425 (5)	Fe1—N1^xii	2.100 (4)
C4—O1	1.405 (3)	Fe1—N1^xiii	2.100 (4)
C4—C4^iv	1.897 (8)	Fe1—N1^xiv	2.100 (4)
C4—C4^v	1.897 (8)	Fe1—N1^xv	2.100 (4)
O1—C4^v	1.405 (3)	Fe1—N1^xvi	2.100 (4)
O1—C4^iv	1.405 (3)	Fe1—N1ⁱ	2.100 (4)
O1—C4^vi	1.405 (3)	Fe1—N1	2.100 (4)
O1—C4^vii	1.405 (3)	N1—N1ⁱⁱⁱ	0.374 (8)
O1—C4^viii	1.405 (3)

C3—C2—C3ⁱ	111.2 (3)	N1^ix—Fe1—N1^xiv	87.4 (2)
C3—C2—C3ⁱⁱ	111.2 (3)	N1ⁱⁱ—Fe1—N1^xiv	92.6 (2)
C3ⁱ—C2—C3ⁱⁱ	111.2 (3)	N1^x—Fe1—N1^xiv	86.17 (15)
C3—C2—C1	107.7 (3)	N1^xi—Fe1—N1^xiv	93.83 (15)
C3ⁱ—C2—C1	107.7 (3)	N1ⁱⁱⁱ—Fe1—N1^xiv	86.17 (15)
C3ⁱⁱ—C2—C1	107.7 (3)	N1^xii—Fe1—N1^xiv	93.83 (15)
N1—C3—N1ⁱⁱⁱ	15.1 (3)	N1^xiii—Fe1—N1^xiv	101.3 (2)
N1—C3—C2	115.3 (4)	N1^ix—Fe1—N1^xv	92.6 (2)
N1ⁱⁱⁱ—C3—C2	115.3 (4)	N1ⁱⁱ—Fe1—N1^xv	87.4 (2)
O1—C4—C4^iv	47.54 (18)	N1^x—Fe1—N1^xv	93.83 (15)
O1—C4—C4^v	47.54 (18)	N1^xi—Fe1—N1^xv	86.17 (15)
C4^iv—C4—C4^v	60.000 (1)	N1ⁱⁱⁱ—Fe1—N1^xv	93.83 (15)
C4—O1—C4^v	84.9 (4)	N1^xii—Fe1—N1^xv	86.17 (15)
C4—O1—C4^iv	84.9 (4)	N1^xiii—Fe1—N1^xv	78.7 (2)
C4^v—O1—C4^iv	84.9 (4)	N1^xiv—Fe1—N1^xv	180.0 (3)
C4—O1—C4^vi	180.0	N1^ix—Fe1—N1^xvi	86.17 (15)
C4^v—O1—C4^vi	95.1 (4)	N1ⁱⁱ—Fe1—N1^xvi	93.83 (15)
C4^iv—O1—C4^vi	95.1 (4)	N1^x—Fe1—N1^xvi	101.3 (2)
C4—O1—C4^vii	95.1 (4)	N1^xi—Fe1—N1^xvi	78.7 (2)
C4^v—O1—C4^vii	180.0	N1ⁱⁱⁱ—Fe1—N1^xvi	87.4 (2)
C4^iv—O1—C4^vii	95.1 (4)	N1^xii—Fe1—N1^xvi	92.6 (2)
C4^vi—O1—C4^vii	84.9 (4)	N1^xiii—Fe1—N1^xvi	86.17 (15)
C4—O1—C4^viii	95.1 (4)	N1^xiv—Fe1—N1^xvi	169.8 (2)
C4^v—O1—C4^viii	95.1 (4)	N1^xv—Fe1—N1^xvi	10.2 (2)
C4^iv—O1—C4^viii	180.0	N1^ix—Fe1—N1ⁱ	93.83 (15)
C4^vi—O1—C4^viii	84.9 (4)	N1ⁱⁱ—Fe1—N1ⁱ	86.17 (15)
C4^vii—O1—C4^viii	84.9 (4)	N1^x—Fe1—N1ⁱ	78.7 (2)
N1^ix—Fe1—N1ⁱⁱ	180.0 (3)	N1^xi—Fe1—N1ⁱ	101.3 (2)
N1^ix—Fe1—N1^x	169.8 (2)	N1ⁱⁱⁱ—Fe1—N1ⁱ	92.6 (2)
N1ⁱⁱ—Fe1—N1^x	10.2 (2)	N1^xii—Fe1—N1ⁱ	87.4 (2)
N1^ix—Fe1—N1^xi	10.2 (2)	N1^xiii—Fe1—N1ⁱ	93.83 (15)
N1ⁱⁱ—Fe1—N1^xi	169.8 (2)	N1^xiv—Fe1—N1ⁱ	10.2 (2)
N1^x—Fe1—N1^xi	180.00 (13)	N1^xv—Fe1—N1ⁱ	169.8 (2)
N1^ix—Fe1—N1ⁱⁱⁱ	101.3 (2)	N1^xvi—Fe1—N1ⁱ	180.0 (2)
N1ⁱⁱ—Fe1—N1ⁱⁱⁱ	78.7 (2)	N1^ix—Fe1—N1	93.83 (15)
N1^x—Fe1—N1ⁱⁱⁱ	86.17 (15)	N1ⁱⁱ—Fe1—N1	86.17 (15)
N1^xi—Fe1—N1ⁱⁱⁱ	93.83 (15)	N1^x—Fe1—N1	92.6 (2)
N1^ix—Fe1—N1^xii	78.7 (2)	N1^xi—Fe1—N1	87.4 (2)
N1ⁱⁱ—Fe1—N1^xii	101.3 (2)	N1ⁱⁱⁱ—Fe1—N1	10.2 (2)
N1^x—Fe1—N1^xii	93.83 (15)	N1^xii—Fe1—N1	169.8 (2)
N1^xi—Fe1—N1^xii	86.17 (15)	N1^xiii—Fe1—N1	180.0
N1ⁱⁱⁱ—Fe1—N1^xii	180.0 (2)	N1^xiv—Fe1—N1	78.7 (2)
N1^ix—Fe1—N1^xiii	86.17 (15)	N1^xv—Fe1—N1	101.3 (2)
N1ⁱⁱ—Fe1—N1^xiii	93.83 (15)	N1^xvi—Fe1—N1	93.83 (15)
N1^x—Fe1—N1^xiii	87.4 (2)	N1ⁱ—Fe1—N1	86.17 (15)
N1^xi—Fe1—N1^xiii	92.6 (2)	N1ⁱⁱⁱ—N1—C3	82.47 (16)
N1ⁱⁱⁱ—Fe1—N1^xiii	169.8 (2)	N1ⁱⁱⁱ—N1—Fe1	84.88 (10)
N1^xii—Fe1—N1^xiii	10.2 (2)	C3—N1—Fe1	119.0 (3)

C3ⁱ—C2—C3—N1	−53.9 (4)	C4^iv—C4—O1—C4^vii	−94.7 (3)
C3ⁱⁱ—C2—C3—N1	70.6 (4)	C4^v—C4—O1—C4^vii	179.997 (1)
C1—C2—C3—N1	−171.65 (17)	C4^iv—C4—O1—C4^viii	180.001 (1)
C3ⁱ—C2—C3—N1ⁱⁱⁱ	−70.6 (4)	C4^v—C4—O1—C4^viii	94.7 (3)
C3ⁱⁱ—C2—C3—N1ⁱⁱⁱ	53.9 (4)	C2—C3—N1—N1ⁱⁱⁱ	−93.59 (10)
C1—C2—C3—N1ⁱⁱⁱ	171.65 (17)	N1ⁱⁱⁱ—C3—N1—Fe1	79.8 (2)
C4^iv—C4—O1—C4^v	85.3 (3)	C2—C3—N1—Fe1	−13.7 (3)
C4^v—C4—O1—C4^iv	−85.3 (3)

Symmetry codes: (i) −y, x−y, z; (ii) −x+y, −x, z; (iii) −y, −x, z; (iv) −y+1, x−y+1, z; (v) −x+y, −x+1, z; (vi) −x+2/3, −y+4/3, −z+1/3; (vii) x−y+2/3, x+1/3, −z+1/3; (viii) y−1/3, −x+y+1/3, −z+1/3; (ix) x−y, x, −z; (x) −x+y, y, z; (xi) x−y, −y, −z; (xii) y, x, −z; (xiii) −x, −y, −z; (xiv) x, x−y, z; (xv) −x, −x+y, −z; (xvi) y, −x+y, −z.

(1st_083K) top

Crystal data top

C_8.25H_25.50Br_1.50Fe_0.75N_4.50O_0.75	D_x = 1.618 Mg m⁻³
M_r = 361.58	Synchrotron radiation, λ = 0.78405 Å
Trigonal, R3m	Cell parameters from 860 reflections
a = 7.4091 (4) Å	θ = 2.2–27.7°
c = 31.216 (2) Å	µ = 6.13 mm⁻¹
V = 1484.02 (19) Å³	T = 83 K
Z = 4	Hexagonal flat prism, colourless
F(000) = 738	0.24 × 0.22 × 0.16 mm

Data collection top

Abstract diffractometer	335 reflections with I > 2σ(I)
Radiation source: synchrotron	R_int = 0.008
ω scans	θ_max = 29.3°, θ_min = 2.2°
Absorption correction: multi-scan CrysAlisPro 1.171.39.46 (Rigaku Oxford Diffraction, 2018) Empirical absorption correction using spherical harmonics, implemented in SCALE3 ABSPACK scaling algorithm.	h = −8→9
T_min = 0.789, T_max = 1.000	k = −9→9
2197 measured reflections	l = −37→37
396 independent reflections

Refinement top

Refinement on F²	1 restraint
Least-squares matrix: full	Hydrogen site location: mixed
R[F² > 2σ(F²)] = 0.086	H-atom parameters constrained
wR(F²) = 0.243	w = 1/[σ²(F_o²) + (0.1376P)² + 10.4317P] where P = (F_o² + 2F_c²)/3
S = 1.14	(Δ/σ)_max = 0.403
396 reflections	Δρ_max = 1.20 e Å⁻³
33 parameters	Δρ_min = −0.42 e Å⁻³

Special details top

Fractional atomic coordinates and isotropic or equivalent isotropic displacement parameters (Å²) top

	x	y	z	U_iso*/U_eq	Occ. (<1)
C1	0.0000	0.0000	0.1511 (5)	0.118 (6)
H1A	−0.1487	−0.0744	0.1615	0.177*
C2	0.0000	0.0000	0.0997 (4)	0.090 (4)
C3	−0.1129 (7)	0.1129 (7)	0.0847 (2)	0.096 (2)
H3A	−0.2462	0.0604	0.1010	0.115*	0.5
H3B	−0.0236	0.2696	0.0921	0.115*	0.5
C4	0.1624 (7)	0.5812 (3)	0.13854 (17)	0.13 (2)*	0.1667
H4A	0.1539	0.4600	0.1240	0.199*	0.0833
H4B	0.1801	0.6860	0.1172	0.199*	0.0833
H4C	0.0340	0.5380	0.1548	0.199*	0.0833
O1	0.3333	0.6667	0.1667	0.254 (18)
H1	0.3665	0.5729	0.1728	0.381*	0.0833
Fe1	0.0000	0.0000	0.0000	0.0589 (5)
Br1	0.3333	0.6667	0.03649 (5)	0.0923 (5)
N1	−0.1449 (11)	0.1060 (13)	0.04029 (18)	0.0917 (19)	0.5
H1B	−0.1197	0.2373	0.0317	0.110*	0.5
H1C	−0.2883	0.0130	0.0374	0.110*	0.5

Atomic displacement parameters (Å²) top

	U¹¹	U²²	U³³	U¹²	U¹³	U²³
C1	0.132 (8)	0.132 (8)	0.090 (9)	0.066 (4)	0.000	0.000
C2	0.107 (6)	0.107 (6)	0.058 (6)	0.053 (3)	0.000	0.000
C3	0.114 (2)	0.114 (2)	0.077 (4)	0.069 (3)	0.0081 (19)	−0.0081 (19)
O1	0.28 (3)	0.28 (3)	0.20 (3)	0.141 (13)	0.000	0.000
Fe1	0.0618 (6)	0.0618 (6)	0.0529 (9)	0.0309 (3)	0.000	0.000
Br1	0.0895 (6)	0.0895 (6)	0.0979 (10)	0.0447 (3)	0.000	0.000
N1	0.086 (3)	0.130 (4)	0.080 (4)	0.070 (2)	0.008 (3)	0.010 (4)

Geometric parameters (Å, º) top

C1—C2	1.60 (2)	Fe1—N1	2.048 (7)
C2—C3ⁱ	1.522 (10)	Fe1—N1^ix	2.048 (7)
C2—C3ⁱⁱ	1.522 (10)	Fe1—N1^x	2.048 (7)
C2—C3	1.522 (10)	Fe1—N1ⁱ	2.048 (7)
C3—N1ⁱⁱⁱ	1.404 (9)	Fe1—N1^xi	2.048 (7)
C3—N1	1.404 (9)	Fe1—N1ⁱⁱ	2.048 (7)
C4—O1	1.405 (3)	Fe1—N1^xii	2.048 (7)
C4—C4^iv	1.900 (8)	Fe1—N1^xiii	2.048 (7)
C4—C4^v	1.900 (8)	Fe1—N1^xiv	2.048 (7)
O1—C4^iv	1.405 (3)	Fe1—N1ⁱⁱⁱ	2.048 (7)
O1—C4^v	1.405 (3)	Fe1—N1^xv	2.048 (7)
O1—C4^vi	1.405 (3)	Fe1—N1^xvi	2.048 (7)
O1—C4^vii	1.405 (3)	N1—N1ⁱⁱⁱ	0.289 (15)
O1—C4^viii	1.405 (3)

C3ⁱ—C2—C3ⁱⁱ	111.0 (5)	N1—Fe1—N1^xiii	80.4 (4)
C3ⁱ—C2—C3	111.0 (5)	N1^ix—Fe1—N1^xiii	86.2 (3)
C3ⁱⁱ—C2—C3	111.0 (5)	N1^x—Fe1—N1^xiii	93.8 (3)
C3ⁱ—C2—C1	107.9 (5)	N1ⁱ—Fe1—N1^xiii	8.1 (4)
C3ⁱⁱ—C2—C1	107.9 (5)	N1^xi—Fe1—N1^xiii	171.9 (4)
C3—C2—C1	107.9 (5)	N1ⁱⁱ—Fe1—N1^xiii	91.4 (4)
N1ⁱⁱⁱ—C3—N1	11.8 (6)	N1^xii—Fe1—N1^xiii	88.6 (4)
N1ⁱⁱⁱ—C3—C2	114.4 (8)	N1—Fe1—N1^xiv	99.6 (4)
N1—C3—C2	114.4 (8)	N1^ix—Fe1—N1^xiv	93.8 (3)
O1—C4—C4^iv	47.46 (18)	N1^x—Fe1—N1^xiv	86.2 (3)
O1—C4—C4^v	47.46 (18)	N1ⁱ—Fe1—N1^xiv	171.9 (4)
C4^iv—C4—C4^v	60.0	N1^xi—Fe1—N1^xiv	8.1 (4)
C4^iv—O1—C4^v	85.1 (4)	N1ⁱⁱ—Fe1—N1^xiv	88.6 (4)
C4^iv—O1—C4^vi	94.9 (4)	N1^xii—Fe1—N1^xiv	91.4 (4)
C4^v—O1—C4^vi	94.9 (4)	N1^xiii—Fe1—N1^xiv	180.0 (5)
C4^iv—O1—C4^vii	180.0	N1—Fe1—N1ⁱⁱⁱ	8.1 (4)
C4^v—O1—C4^vii	94.9 (4)	N1^ix—Fe1—N1ⁱⁱⁱ	86.2 (3)
C4^vi—O1—C4^vii	85.1 (4)	N1^x—Fe1—N1ⁱⁱⁱ	93.8 (3)
C4^iv—O1—C4	85.1 (4)	N1ⁱ—Fe1—N1ⁱⁱⁱ	91.4 (4)
C4^v—O1—C4	85.1 (4)	N1^xi—Fe1—N1ⁱⁱⁱ	88.6 (4)
C4^vi—O1—C4	180.0 (3)	N1ⁱⁱ—Fe1—N1ⁱⁱⁱ	80.4 (4)
C4^vii—O1—C4	94.9 (4)	N1^xii—Fe1—N1ⁱⁱⁱ	99.6 (4)
C4^iv—O1—C4^viii	94.9 (4)	N1^xiii—Fe1—N1ⁱⁱⁱ	86.2 (3)
C4^v—O1—C4^viii	180.0	N1^xiv—Fe1—N1ⁱⁱⁱ	93.8 (3)
C4^vi—O1—C4^viii	85.1 (4)	N1—Fe1—N1^xv	171.9 (4)
C4^vii—O1—C4^viii	85.1 (4)	N1^ix—Fe1—N1^xv	93.8 (3)
C4—O1—C4^viii	94.9 (4)	N1^x—Fe1—N1^xv	86.2 (3)
N1—Fe1—N1^ix	91.4 (4)	N1ⁱ—Fe1—N1^xv	88.6 (4)
N1—Fe1—N1^x	88.6 (4)	N1^xi—Fe1—N1^xv	91.4 (4)
N1^ix—Fe1—N1^x	180.0 (2)	N1ⁱⁱ—Fe1—N1^xv	99.6 (4)
N1—Fe1—N1ⁱ	86.2 (3)	N1^xii—Fe1—N1^xv	80.4 (4)
N1^ix—Fe1—N1ⁱ	80.4 (4)	N1^xiii—Fe1—N1^xv	93.8 (3)
N1^x—Fe1—N1ⁱ	99.6 (4)	N1^xiv—Fe1—N1^xv	86.2 (3)
N1—Fe1—N1^xi	93.8 (3)	N1ⁱⁱⁱ—Fe1—N1^xv	180.0 (5)
N1^ix—Fe1—N1^xi	99.6 (4)	N1—Fe1—N1^xvi	180.0
N1^x—Fe1—N1^xi	80.4 (4)	N1^ix—Fe1—N1^xvi	88.6 (4)
N1ⁱ—Fe1—N1^xi	180.0 (4)	N1^x—Fe1—N1^xvi	91.4 (4)
N1—Fe1—N1ⁱⁱ	86.2 (3)	N1ⁱ—Fe1—N1^xvi	93.8 (3)
N1^ix—Fe1—N1ⁱⁱ	8.1 (4)	N1^xi—Fe1—N1^xvi	86.2 (3)
N1^x—Fe1—N1ⁱⁱ	171.9 (4)	N1ⁱⁱ—Fe1—N1^xvi	93.8 (3)
N1ⁱ—Fe1—N1ⁱⁱ	86.2 (3)	N1^xii—Fe1—N1^xvi	86.2 (3)
N1^xi—Fe1—N1ⁱⁱ	93.8 (3)	N1^xiii—Fe1—N1^xvi	99.6 (4)
N1—Fe1—N1^xii	93.8 (3)	N1^xiv—Fe1—N1^xvi	80.4 (4)
N1^ix—Fe1—N1^xii	171.9 (4)	N1ⁱⁱⁱ—Fe1—N1^xvi	171.9 (4)
N1^x—Fe1—N1^xii	8.1 (4)	N1^xv—Fe1—N1^xvi	8.1 (4)
N1ⁱ—Fe1—N1^xii	93.8 (3)	N1ⁱⁱⁱ—N1—C3	84.1 (3)
N1^xi—Fe1—N1^xii	86.2 (3)	N1ⁱⁱⁱ—N1—Fe1	86.0 (2)
N1ⁱⁱ—Fe1—N1^xii	180.0 (2)	C3—N1—Fe1	120.6 (6)

C3ⁱ—C2—C3—N1ⁱⁱⁱ	−68.5 (7)	C4^iv—C4—O1—C4^vii	179.997 (1)
C3ⁱⁱ—C2—C3—N1ⁱⁱⁱ	55.5 (8)	C4^v—C4—O1—C4^vii	−94.5 (3)
C1—C2—C3—N1ⁱⁱⁱ	173.5 (3)	C4^iv—C4—O1—C4^viii	94.5 (3)
C3ⁱ—C2—C3—N1	−55.5 (8)	C4^v—C4—O1—C4^viii	180.001 (1)
C3ⁱⁱ—C2—C3—N1	68.5 (7)	C2—C3—N1—N1ⁱⁱⁱ	−92.70 (17)
C1—C2—C3—N1	−173.5 (3)	N1ⁱⁱⁱ—C3—N1—Fe1	81.7 (4)
C4^v—C4—O1—C4^iv	85.5 (3)	C2—C3—N1—Fe1	−10.9 (6)
C4^iv—C4—O1—C4^v	−85.5 (3)

Symmetry codes: (i) −y, x−y, z; (ii) −x+y, −x, z; (iii) −y, −x, z; (iv) −x+y, −x+1, z; (v) −y+1, x−y+1, z; (vi) −x+2/3, −y+4/3, −z+1/3; (vii) x−y+2/3, x+1/3, −z+1/3; (viii) y−1/3, −x+y+1/3, −z+1/3; (ix) −x+y, y, z; (x) x−y, −y, −z; (xi) y, −x+y, −z; (xii) x−y, x, −z; (xiii) x, x−y, z; (xiv) −x, −x+y, −z; (xv) y, x, −z; (xvi) −x, −y, −z.

Acknowledgements

The sample used was originally supplied by Dr Paul V. Bernhardt et al., School of Chemistry and Molecular Biosciences, University of Queensland, Brisbane, Australia. The authors also are grateful to the staff of the Swiss–Norwegian BeamLines at the ESRF, Grenoble, France for friendly support, and Dr Chloe Fuller for her help with modeling spin transition curves.

References

Bernhardt, P. V., Bilyj, J. K., Brosius, V., Chernyshov, D., Deeth, R. J., Foscato, M., Jensen, V. R., Mertes, N., Riley, M. J. & Törnroos, K. W. (2018). Chem. Eur. J. 24, 5082–5085. Web of Science CrossRef CAS PubMed Google Scholar
Bogdanov, N. E., Zakharov, B. A., Chernyshov, D., Pattison, P. & Boldyreva, E. V. (2021). Acta Cryst. 77, 365–370. Google Scholar
Bras, W., Myles, D. A. A. & Felici, R. (2021). J. Phys. Condens. Matter, 33, 423002. Web of Science CrossRef Google Scholar
Chernyshov, D., Dyadkin, V. & Törnroos, K. W. (2019). Acta Cryst. 75, 678–678. Google Scholar
Chernyshov, D., Klinduhov, N., Törnroos, K. W., Hostettler, M., Vangdal, B. & Bürgi, H.-B. (2007). Phys. Rev. B, 76, 014406. Web of Science CrossRef Google Scholar
Christensen, J., Horton, P. N., Bury, C. S., Dickerson, J. L., Taberman, H., Garman, E. F. & Coles, S. J. (2019). IUCrJ, 6, 703–713. Web of Science CSD CrossRef CAS PubMed IUCr Journals Google Scholar
Coates, C. S., Murray, C. A., Boström, H. L. B., Reynolds, E. M. & Goodwin, A. L. (2021). Mater. Horiz. 8, 1446–1453. Web of Science CrossRef CAS PubMed Google Scholar
Collet, E. & Guionneau, P. (2018). C. R. Chim. 21, 1133–1151. Web of Science CrossRef CAS Google Scholar
Dyadkin, V., Pattison, P., Dmitriev, V. & Chernyshov, D. (2016). J. Synchrotron Rad. 23, 825–829. Web of Science CrossRef CAS IUCr Journals Google Scholar
Gütlich, P., Ksenofontov, V. & Gaspar, A. B. (2005). Coord. Chem. Rev. 249, 1811–1829. Google Scholar
Kuroda-Sowa, T., Isobe, R., Yamao, N., Fukumasu, T., Okubo, T. & Maekawa, M. (2017). Polyhedron, 136, 74–78. CAS Google Scholar
Lawrence Bright, E., Giacobbe, C. & Wright, J. P. (2021). J. Synchrotron Rad. 28, 1377–1385. Web of Science CrossRef IUCr Journals Google Scholar
Lemercier, G., Bréfuel, N., Shova, S., Wolny, J. A., Dahan, F., Verelst, M., Paulsen, H., Trautwein, A. X. & Tuchagues, J.-P. (2006). Chem. Eur. J. 12, 7421–7432. . Web of Science CSD CrossRef PubMed CAS Google Scholar
Murray, K. S. (2013). The Development of Spin-Crossover Research. John Wiley and Sons, Ltd. Google Scholar
Ndiaye, M., Belmouri, N. E. I., Linares, J. & Boukheddaden, K. (2021). Symmetry, 13, 828. Web of Science CrossRef Google Scholar
Nicolazzi, W. & Bousseksou, A. (2018). C. R. Chim. 21, 1060–1074. Web of Science CrossRef CAS Google Scholar
Paulsen, H., Schünemann, V. & Wolny, J. A. (2013). Eur. J. Inorg. Chem. 2013, 628–641. Web of Science CrossRef CAS Google Scholar
Pavlik, J. & Linares, J. (2018). C. R. Chim. 21, 1170–1178. Web of Science CrossRef CAS Google Scholar
Pillet, S. (2021). J. Appl. Phys. 129, 181101. Web of Science CrossRef Google Scholar
Rigaku Oxford Diffraction (2015). CrysAlis Pro, Version 1.171.38.41. Rigaku Oxford Diffraction, Yarnton, England. Google Scholar
Sheldrick, G. M. (2015a). Acta Cryst. A71, 3–8. Web of Science CrossRef IUCr Journals Google Scholar
Sheldrick, G. M. (2015b). Acta Cryst. C71, 3–8. Web of Science CrossRef IUCr Journals Google Scholar
Vankó, G., Renz, F., Molnár, G., Neisius, T. & Kárpáti, S. (2007). Angew. Chem. Int. Ed. 46, 5306–5309. Google Scholar

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Volume 78| Part 3| June 2022| Pages 392-396

https://doi.org/10.1107/S205252062200467X

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Hans-Beat Bürgi tribute\(\def\hfill{\hskip 5em}\def\hfil{\hskip 3em}\def\eqno#1{\hfil {#1}}\)

Preliminary observations of the interplay of radiation damage with spin crossover

1. Introduction

2. Experiment

3. Results

3.1. Unit-cell dimensions

3.2. Bonds and spin states

4. Conclusion

APPENDIX A

Phenomenological consideration of the radiation damage and spin equilibrium.

Supporting information

Acknowledgements

References

Hans-Beat Bürgi tribute