3.2.1. Refinement of the nuclear structure

In the refinement of the neutron powder data, a pseudo-Voigt profile function and a background described by ten terms of Legendre polynomials combined with 70 manually assigned background points were used. An absorption correction according to Larson & Von Dreele (2004) and a correction for preferred orientation according to March–Dollase were applied (Larson & Von Dreele, 2004). Coordinates and displacement parameters of atoms occupying the same site were restricted to be equal. The sums of occupancies of Mn1/Fe1 and Mn2/Fe2 were restricted to the ideal values and the overall chemical composition was restricted to Mn₃Fe₂Si₃ in accordance with the result from chemical analysis (Table S1 in the supporting information).

For the single-crystal refinements, the occupancies for the Mn and Fe sites were fixed to the values obtained from refinement of the neutron powder data. Further details concerning the refinement, together with atomic coordinates and displacement parameters, are given in Tables S2–S4 in the supporting information: CCDC reference numbers 2202008–2202017.

3.2.2. Temperature dependence of the crystal structure of Mn₃Fe₂Si₃

Refinement of the synchrotron single-crystal diffraction data shows that Mn₃Fe₂Si₃ crystallizes in the hexagonal space group P6₃/mcm at all measured temperatures with unit-cell parameters a = 6.8534 (3) Å and c = 4.7556 (2) Å [V = 193.437 (15) ų] at room temperature, in good agreement with the literature (Bińczycka et al., 1973). Atomic positions and interatomic distances of Mn₃Fe₂Si₃ refined from synchrotron single-crystal diffraction data as a function of temperature are presented in Tables S4 and S5, respectively.

To determine the distribution of the Mn and Fe atoms on the distinct crystallographic sites, a combined refinement of the synchrotron single-crystal and the room-temperature neutron powder data was performed. It shows that the M1 (Wyckoff position 4d) site in the [(M1)Si₆] octahedra is occupied by 76.5 (1) at.% Fe and 23.4 (1) at.% Mn, while the M2 (Wyckoff position 6g) site is occupied by 15.6 (1) at.% Fe and 84.4 (1) at.% Mn. This preferential incorporation of Fe and Mn atoms onto the two sites is in agreement with earlier observations (Bińczycka et al., 1973; Hering et al., 2015).

The unit-cell parameters and unit-cell volume of Mn₃Fe₂Si₃ decrease smoothly as the temperature decreases, with the slope decreasing towards lower temperatures (Fig. 5; see also Table S3).

Figure 5 Unit-cell parameters a and c and unit-cell volume of Mn3Fe2Si3 as a function of temperature obtained from synchrotron X-ray single-crystal diffraction data measured during cooling. The figure at the bottom right shows the values of a (b), c, the c/a ratio and the unit-cell volume of Mn3Fe2Si3 normalized to the values at 300 K. Temperatures corresponding to the AF1–AF2 and AF2–PM transitions are indicated by dashed lines. Estimated standard deviations are smaller than the size of the symbols.

Within the standard deviations, all interatomic distances between paramagnetic atoms in Mn₃Fe₂Si₃ decrease with decreasing temperature, with no clear sign of a response to the transition from the antiferromagnetic AF1 to the antiferro­magnetic AF2 phase, or to the transition from the antiferromagnetic AF2 phase to the paramagnetic PM phase (Fig. 6; see also Fig. S2 and Table S5 in the supporting information). The interatomic distances between metal atoms located on the same sites are reduced more significantly than the distances between metal atoms located on different sites (interatomic M1—Si and Si—Si distances decrease in general less than M—M distances; Fig. S3).

Figure 6 Temperature dependence of M–M interatomic distances of (left) Mn3Fe2Si3 and (right) Mn5Si3 as a function of temperature, normalized to the value at 300 K, obtained on the basis of refinements from synchrotron X-ray single-crystal diffraction data (Mn3Fe2Si3) and extracted from the literature data (Mn5Si3; Gottschilch et al., 2012). Temperatures of the AF1–AF2 and AF2–PM transitions are indicated by dashed lines. The assignment of the distances is shown in Fig. S2 in the supporting information. Note that in Mn5Si3 the M1—M1 distances are split in the monoclinic AF1 phase. Estimated standard deviations are smaller than the size of the symbols, if not shown otherwise. Symmetry codes: (i) x, y, −z − ; (ii) −x + 1, −y, −z; (iii) −y + 1, x − y, z; (iv) −y + 1, x − y, z.

If one compares the temperature dependence of the structure of Mn₃Fe₂Si₃ with that of Mn₅Si₃ (Brown & Forsyth, 1995; Brown et al., 1992; Gottschilch et al., 2012) some major differences can be identified:

(i) While the symmetry remains hexagonal in Mn₃Fe₂Si₃ over the whole investigated temperature range, i.e. in the stability fields of the AF2 and AF1 phases, in Mn₅Si₃ the PM–AF2 transition is accompanied by a reduction of the symmetry from hexagonal to orthorhombic. In addition, for Mn₅Si₃ a further decrease of the symmetry to monoclinic was observed by Gottschilch et al. (2012) for the AF1 phase, which was, however, not reported by Brown et al. (1992).

(ii) The M1—M1 distance in Mn₅Si₃ is clearly changed at the AF2–AF1 transition, while this is not observed for Mn₃Fe₂Si₃. Assuming that the monoclinic model from the literature for the AF1 phase of Mn₅Si₃ is correct (Gottschilch et al., 2012), the M1 position is split into two symmetrically independent positions, which in turn leads to two different M1—M1 distances parallel to c, one of them being significantly increased at the transition while the second one is significantly decreased (Fig. 6).

(iii) At the AF2–AF1 transition, the M2—M2 distances in Mn₅Si₃ clearly show a change of slope, a trend that is not observed for Mn₃Fe₂Si₃.

To compare the temperature-dependent behaviour of both compounds further, the normalized angular distortion Σ and distance distortion Δ of the [(M1)Si₆] and [□(M2)₆] octahedra were calculated using the program Octadist (Ketkaew et al., 2021)² and normalized to the values for 300 K (Fig. 7). It is striking that, in both compounds, the [□(M2)₆] octahedra show a more pronounced distortion than the [(M1)Si₆] octahedra. However, while for Mn₃Fe₂Si₃ the angular distortion of the [□(M2)₆] octahedra is decreased at the PM to AF2 transition and the distortion of [(M1)Si₆] stays nearly constant over the whole temperature range, in Mn₅Si₃ the distortion of the [□(M2)₆] octahedra seems to increase at the PM–AF2 transition, while the distortion of the [(M1)Si₆] octahedra seems to decrease at the AF2–AF1 transition. Furthermore, in contrast to Mn₃Fe₂Si₃ where all six Mn—Si distances in an octahedron are equal at all temperatures (and therefore Δ = 0), in Mn₅Si₃ a sudden increase in the distance distortion parameter Δ of the [□(M2)₆] octahedra is observed at the temperature of the PM–AF2 transition and an additional sharp increase in the distance distortion is observed for the [(M1)Si₆] octahedra at the AF2–AF1 transition (Fig. 7).

Figure 7 Normalized angular distortion Σ of [(M1)Si6] and [□(M2)6] octahedra as a function of temperature in (a) Mn3Fe2Si3 and (b) Mn5Si3 based on data from Gottschilch et al. (2012). (c) Normalized distance distortion Δ of [(M1)Si6] and [□(M2)6] octahedra as a function of temperature in Mn5Si3 based on data from Gottschilch et al. (2012) (values are normalized to the volumes at 300 K). Estimated standard deviations are smaller than the size of the symbols. Temperatures of the AF1–AF2 and AF2–PM transitions are indicated by dashed lines.

3.2.3. Refinement of the magnetic structure of Mn₃Fe₂Si₃

The neutron powder diffraction diagrams of Mn₃Fe₂Si₃ (Fig. 8) show the first peaks of magnetic origin at 105 K. At 50 K, additional weak peaks resulting from magnetic order are visible. For the derivation of the magnetic space-group symmetries the built-in algorithms of JANA2006 (Petříček et al., 2014) were used. Starting from the space group P6₃/mcm of the nuclear structure (Tables S6 and S7) and assuming one magnetic propagation vector [k_hex = = k_ortho = (010)], eight different orthorhombic models with different magnetic moment directions are derived (Table S8).

Figure 8 Mn3Fe2Si3 neutron powder diffraction data obtained on POWGEN at different temperatures for a central wavelength of 2.665 Å. The d regions with the strongest magnetic Bragg reflections are shown. Indices of the magnetic Bragg peaks refer to all temperatures and are based on the orthorhombic Ccmm setting.

For the refinements, the nuclear structure of Mn₃Fe₂Si₃ was transformed to the orthohexagonal setting (a_ortho = a_hex, b_ortho = a_hex + 2b_hex, c_ortho = c_hex), space group Ccmm.³ Magnetic atoms occupying the same site were restricted to have identical magnetic moments. Only magnetic moments and polynomial background parameters, which were combined with a manual background, were refined, while all other parameters were fixed to the values obtained from the refinement of the nuclear structure.

From the eight refined models, the one in magnetic space group P_Cnan clearly gives the best agreement factor, both at 90 and 20 K (Table S9). Figs. 9(a) and 9(b) show the corresponding Rietveld refinements.

Figure 9 Rietveld refinements of the neutron powder data (central wavelength of 2.665 Å) of Mn3Fe2Si3 in magnetic space group PCnan at (a) 90 K and (b) 20 K, and (c) in magnetic space group PC2221 at 20 K. Grey tick marks indicate the positions of nuclear and magnetic reflections. The difference curve is shown below. The insets present selected characteristic magnetic peaks in the 2–12.5 Å region.

For the data at 90 K (and 105 K), which correspond to the stability region of the AF2 phase (T_AF1–AF2 ≃ 70 K < T < T_AF2–PM ≃ 120 K) the model in magnetic space group P_Cnan fits the measured neutron diffraction pattern very well. The only exception is the 010 reflection [see inset in Fig. 9(a)] which is significantly broader than all other magnetic peaks and only disappears completely at 150 K.

At 20 K, that is in the stability field of the AF1 phase (T_AF1–AF2 ≃ 70 K), the intensities of the newly arising magnetic peaks are underestimated in the refinement based on magnetic space group P_Cnan. In particular, the 230 reflection, which is weak but clearly visible, has an intensity that is calculated to be zero in this model [see inset in Fig. 9(b)]. We therefore decided to lower the magnetic symmetry for the 20 K data further. For this, the nuclear structure was transformed to the different maximum translationengleiche subgroups of Ccmm, while still restricting the nuclear structure to hexagonal symmetry. For each of the different subgroups, the different magnetic models were then derived and refined. On the basis of the agreement factors (Tables S10 and S11), the model in magnetic space group P_C222₁ (derived from the C222₁ space group) clearly appears to be the best of the 40 refined models. The Rietveld refinement of this model is shown in Fig. 9(c).

3.2.4. Magnetic structures of Mn₃Fe₂Si₃

The refinements of the magnetic structures of Mn₃Fe₂Si₃ based on the neutron diffraction data at 105, 90, 50 and 20 K show two different antiferromagnetic structures: the AF2 phase corresponding to the temperature range T_AF1–AF2 ≃ 70 K < T < T_AF2–PM ≃ 120 K and the AF1 phase corresponding to the temperature range T < T_AF1–AF2 ≃ 70 K, in accordance with the heat capacity and magnetization data.

In the centrosymmetric AF2 phase (magnetic space group P_Cnan), no components of magnetic moments are allowed parallel to the c axis (Table S8). Magnetic moments on the Mn1/Fe1 sites are aligned along the [010] direction. Moments are allowed along the [100] direction for the Fe21/Mn21 site, and in the ab plane for Fe22/Mn22. However, at 105 and 90 K, all refined M_x components for these sites are zero within error (Table 1) and consequently the AF2 structure is collinear, with all the spins aligned parallel or antiparallel to the b axis (Fig. 10). The Fe1/Mn1 and Fe22/Mn22 sites have refined magnetic moments of similar size, 0.70 (7) μ_B and 0.66 (7) μ_B at 105 K, respectively. When taking into account the standard deviations, the ordered moment on the Fe21/Mn21 sites is not significantly different from zero. Thus, of the Fe/Mn sites forming the empty octahedra, only two-thirds carry an ordered moment in the AF2 phase. Within these octahedra, the atoms at the same height z have their spins aligned in an antiparallel way. At 90 K, the observed magnetic ordering of the AF2 phase is very similar to the structure at 105 K and only the magnitude of the refined magnetic moments on Fe1/Mn1 and Fe22/Mn22 is slightly increased, with values of 0.82 (8) μ_B and 0.76 (8) μ_B, respectively (Table 1).

Figure 10 The magnetic structure of Mn3Fe2Si3 at 90 K (magnetic space group PCnan). (Left) A projection along the a direction and (right) a projection along the c direction. Note that the refined value of Mx for Fe21/Mn21 and Fe22/Mn22 is smaller than its respective standard deviation. For the drawings, this value was therefore set to zero.

At temperatures below T_AF1–AF2 ≃ 70 K, the magnetic structure changes to that of the AF1 phase with symmetry P_C222₁ (Fig. 11). The most significant difference between the AF2 and AF1 phases is that the magnetic moments on the Fe22/Mn22 sites acquire a component in the c direction and align now in the bc plane, forming an angle of ∼30° at 50 K and ∼40° at 20 K with the b axis (Fig. 11). It is this re-alignment of the spins which breaks the centrosymmetry of the magnetic structure and leads to the non-collinearity of the AF1 phase. The magnitude of the Fe22/Mn22 magnetic moment is increased slightly to 0.8 (3) μ_B at 50 K and 1.0 (5) μ_B at 20 K. Moments on the M1 sites (now split into two magnetically independent Wyckoff positions Fe11/Mn11 and Fe12/Mn12) keep their orientation parallel to the b axis, and all allowed M_x components on the M21/M22 sites are still refined to zero within their standard deviation (Table 2).

Figure 11 The magnetic structure of Mn3Fe2Si3 at 20 K (magnetic space group PC2221). (Left) A projection along the a direction and (right) a projection along the c direction. Note that the refined value of Mx for Fe21/Mn21 and Fe22/Mn22 is basically identical to its standard deviation. For the drawings, this value was therefore set to zero.