1. Chemical context

Several inter­metallic compounds, such as CrB₄ (ortho­rhom­bic, Immm), CrB₂ (hexa­gonal, P6/mmm), Cr₃B₄ (ortho­rhom­bic, Immm), CrB (ortho­rhom­bic, Cmcm), Cr₅B₃ (tetra­gonal, I4/mcm), t-Cr₂B (tetra­gonal, I4/mcm) and o-Cr₂B (ortho­rhom­bic, Fddd), exist in the binary Cr–B system (Lundström, 1969; Guy & Uraz, 1976; Massalski et al., 2016). These binary chromium borides have attracted research attention as high-strength materials with excellent thermal, corrosion, and wear resistance. In addition to synthesis techniques (Okada et al., 1996; Iizumi et al., 1998), their applications in industrial fields have been also developed.

Notable magnetic (Guy, 1976; Leyarovska et al., 1979), thermal (Leyarovska et al., 1979) and transportation (Cruceanu et al., 1975) properties have been reported in more than 130 inter­metallic compounds with a Cr₅B₃ prototype (ICSD, 2025). Anti­ferromagnetic ordering occurs in Cr₅B₃ at T_N = 91.5 K (Leyarovska et al., 1979). The magnetic susceptibility and specific heat measurements of Cr₅B₃ suggest that its magnetic behavior originates from anti­ferromagnetic spin fluctuations in an itinerant electron system, rather than from localized magnetic moments (Leyarovska et al., 1979). The observed effective magnetic moment of 0.02 μ_B per Cr atom indicates a low-spin state with significant d-electron delocalization. These findings imply that the formal oxidation state of Cr lies between +2 and +3. In the Cr₅B₃-type structure, metal atoms locate the two non-equivalent crystallographic sites. A two-dimensional square lattice formed by one of these metal sites can host magnetically frustrated orthogonal dimer systems. This square lattice is classified the Sharstry–Sutherland lattice (SSL; Shastry & Sutherland, 1981; Kageyama et al., 1999; Siemensmeyer et al., 2008; Coleman & Nevidomskyy, 2010). In particular, Ce₅Si₃, which has the Cr₅B₃-type structure, features a bilayer system of the SSL layers formed by Ce atoms, with additional inter­actions from out-of-plane Ce atoms contributing to its complex magnetic properties. (Ueta et al., 2024).

The first structural investigation of Cr₅B₃ was conducted using a single crystalline sample (Bertaut & Blum, 1953). Both Cr and B atoms in the tetra­gonal Cr₅B₃ occupy two different Wyckoff sites, namely, 4c (0, 0, 0) and 16l (x, x + , z) denoted as the Cr2 and Cr1 sites, respectively, and 4a (0, 0, 1/4) and 8h (x, x + , 0) denoted as the B1 and B2 sites, respectively. Subsequent structural studies on Cr₅B₃ have been limited to determining the lattice parameters, and the structural parameters have remained unchanged for over half a century (Portnoi et al., 1969; von Robitsch, 1974; Paradelli & Gian­oglio, 1976; Hu et al., 2014). Furthermore, regarding the atomic displacement parameters (ADPs) Bertaut & Blum (1953) did not determine them. Therefore, refining the anisotropic ADPs is essential for a more accurate structural description. Authors have reported that ADPs provide useful information about the structural properties of several metal boride compounds, such as YCrB₄ (Tokuda et al., 2022) and RERh₃B₂ (RE = Pr, Nd, and Sm) (Tokuda et al., 2023). In this study, we update the structural parameters of Cr₅B₃ and perform a refinement, including the anisotropic ADPs.

Cr₅B₃-type (called T₂-phase) analogous compounds have been studied using various experimental and theoretical methods, because they have many derivatives of the form M₅XB₂ (M = metal, X = non-metal or semi-metal such as Si, P, and Ge; Dahlqvist & Rosen, 2022). The structures of M₅XB₂ and Cr₅B₃ are related to the order–disorder atomic arrangements, in which M₅XB₂ and X atoms solely occupy the 4a site. Recently, several compounds of the form M₅XB₂ have been reported to exhibit superconductivity, such as Ta₅GeB₂ (T_c ∼3.8 K; Hadi et al., 2016; Corrêa et al., 2016), Mo₅GeB₂ (T_c = 5.8 K; Ruan et al., 2021), Mo₅SiB₂ (T_c = 5.8 K; Machado et al., 2011), Mo₅PB₂ (T_c = 9 K; McGuire & Parker, 2016), and (W, Ta)₅SiB₂ (T_c = 6.5 K; Fukuma et al., 2012).

2. Structural commentary

In the Cr₅B₃ structure, the Cr atoms at the Cr2 and Cr1 sites are surrounded by a Cr₈B₆ rhombic dodeca­hedron and a Cr₁₁B₅ 16-vertex Frank–Kasper cluster, respectively, and those at the B1 and B2 sites are surrounded by a Cr₁₀ bicapped square anti­prism and Cr₈B tricapped trigonal prism, respectively (Fig. 1).

Figure 1 (left) Crystal structures of Cr5B3. The purple and green displacement ellipsoids correspond to Cr and B atoms, respectively. Displacement ellipsoids are drawn at the 99% probability level. (right) Coordination polyhedra for each site, Cr11B5 16-vertex Frank–Kasper cluster around Cr1 on 16l site (z = 0.15), Cr8B6 rhombic dodeca­hedron around Cr2 on 4c site (z = 0), Cr10 bicapped square anti­prism around B1 on 4a site (z = 1/4), and Cr8B tricapped trigonal prism around B2 on 8h sites (z = 0).

The B2—B2 inter­atomic distances on the z = 0 and 1/2 plane is 1.8168 (16) Å, which is significantly longer than the average B—B covalent bond distances of 1.77 Å in rhombohedral boron (Donohue, 1974). This B2 pair (B dimer) serves as a bridging unit between two adjacent Cr–B tricapped trigonal prisms, with each boron atom occupying the center of a respective polyhedron. The Cr—B inter­atomic distances are in the range of 2.1803 (3)–2.2826 (1) Å (Table 1), which are close to the sum of the Goldschmidt radii (r_Cr = 1.36 Å and r_B = 0.97 Å; Brandes & Brook, 1992). The intra­plane Cr2⋯Cr2 and intra­plane Cr2⋯Cr1 distances are 3.8698 (1) and 2.5072 (1) Å, respectively. The inter­plane Cr2⋯Cr1 distance is significantly smaller than the sum of the radii of the Cr atoms, and the anisotropic atomic displacement parameters (ADPs) for Cr2 exhibit a larger anisotropy than those of Cr1 (Table 2). The U₃₃ of Cr2 is approximately 1.75 times larger than U₁₁ (= U₂₂), indicating that the displacement ellipsoid of Cr2 is elongated along the c-axis direction. These Cr⋯Cr distances and ADPs of Cr2 indicate a strong correlation between the Cr2 and Cr1 atoms.

The bonding configurations of boron in metal boride compounds (MxBy) are classified with the metal-to-boron ratio (M:B), and their structural characteristics have been systematically investigated (Rogl & Nowotny, 1978). In metal-rich compositions M/B > 1.5, boron typically exists as isolated B or a B–B dimer, occupying localized positions within the metal network. As the metal-to-boron ratio decreases, the bonding motifs transform progressively into mono-periodic chains (e.g., Cr₂AlB₂-type), di-periodic boron layers (e.g., CrB₂-type), and eventually into three-dimensional frameworks constructed from B₆ octa­hedra or B₁₂ icosa­hedra (e.g. UB₄-type). This structural diversity plays a crucial role in determining the electronic structure and physical properties of borides. In particular, Cr₅B₃, with a M:B of 5:3 (1.67), is categorized as a metal-rich boride and the boron configurations B1 and B2 sites correspond to ‘isolated B' and ‘B–B dimer', respectively. The slabs of Cr₈ square anti­prisms [Cr⋯Cr inter­atomic distances of 2.42178 (14) and 2.86881 (3) Å] together with the B1 site and Cr square lattice [Cr⋯Cr inter­atomic distance of 2.50718 (5) Å] with B2 dimers [B2⋯B2 inter­atomic distance of 1.8168 (16) Å] alternately stack along the c-axis as shown in Fig. 2. The slabs of Cr₈ square anti­prisms together with the B1 site connect via edge-sharing. Unlike boron-rich borides, the boron unit, Cr₅B₃, are locally confined, reflecting a characteristic inter­metallic bonding framework in which boron can act predominantly as an electron donor.

Figure 2 (left) Cr square lattices with B dimers at z = 0 and z = 1/2, and (right) slabs of Cr8B square anti­prisms around the B1 site between z = 0.15 and z = 0.35.

Fig. 3 depicts the crystal structures of the binary metal borides Cr₅B₃ (a, b) and TmB₄ (c, d) viewed along the c-axis (a, c) and b-axis (b, d). The purple, green and blue spheres indicate the Cr, B, and Tm atoms, respectively. The gray squares in (a, c, e, f, g) are the respective unit cells. Cr lattices [Cr⋯Cr inter­atomic distance of 2.6513 (1) and 2.8688 (1) Å] at z = 0.15 (Fig. 3e) and z = 0.35 (Fig. 3f) in the slabs of Cr₈ square anti­prisms around B1 site of Cr₅B₃ (in the right panel of Fig. 2) are illustrated. The distribution of Cr are clearly demonstrated by square and triangle tilting. This tilting geometrical feature, composed of squares and triangles, is found in the TmB₄ phase (Tm–Tm inter­atomic distances of 3.635 and 3.729 Å; Fisk et al., 1972) (Fig. 3g) belonging to the UB₄-type structure (tetra­gonal, P4/mbm). Both the Cr₅B₃ and TmB₄ structures feature two-dimensional magnetic layers resembling the Shastry–Sutherland lattice (SSL), characterized by orthogonal dimers and inter­dimer inter­actions. However, while the SSL network in TmB₄ is isolated within the structure, the SSL in Cr₅B₃ are embedded in a three-dimensional framework, making the magnetic frustration more complex and less idealized. This tiling structure is known as the SSL (Shastry & Sutherland, 1981). A schematic of the SSL is shown in Fig. 3h. The first-nearest-neighbor (1NN) and second-nearest-neighbor (2NN) pairs are denoted by the gray and black lines, respectively. Frustrated magnetic behavior with magnetic order is expected in Cr₅B₃-type analogous inter­metallic compounds consisting of SSL.

Figure 3 Crystal structures of binary metal borides: Cr5B3 (a, b) and TmB4 (c, d) viewed along the c-axis (a, c) and b-axis (b, d) directions. Red, green and blue spheres indicate Cr, B and Tm atoms. Gray squares in (a, c, e, f, g) are respective unit cells. Cr lattices at z = 0.15 (e) and z = 0.35 (f) in Cr5B3. (g) Tm lattice at z = 0 in TmB4. (h) Schematic of the SSL. The 1NN and the 2NN pairs are denoted by the solid and dashed lines, respectively.

3. Synthesis and crystallization

Cr₅B₃ exhibits incongruent melting behavior during a peritectic reaction at 2247 K (Massalski et al., 2016). Cr₅B₃ was obtained as a by-product of the synthesis of YCrB₄ crystals. The starting materials were Y (99.9%), Cr (99.95%), and B (99.5%). The samples were weighed at an atomic ratio Y:Cr:B = 1:7:4. The mixtures were then melted in an Ar arc melting furnace (ACM-01, Diavac). The resulting button-like product was then turned over and remelted thrice to improve its chemical homogeneity. Single crystals for the X-ray diffraction measurements were obtained from the fractured surface of this button-like product.

4. Refinement

The refinement process was conducted for the space-group type I4/mcm as described by Bertaut & Blum 1953. A correction for isotropic extinction was applied during the least-squares refinement. The final refinements were performed by applying the anisotropic ADPs to each atom. These final refinement results are listed in Table 3. The refinement was successful, with the R factor converging without any problems and no noticeable residuals.

Table 3 Experimental details Crystal data Chemical formula Cr5B3 Mr 292.43 Crystal system, space group Tetragonal, I4/mcm Temperature (K) 294 a, c (Å) 5.47276 (5), 10.07939 (16) V (Å3) 301.89 (1) Z 4 Radiation type Mo Kα μ (mm−1) 17.06 Crystal size (mm) 0.06 × 0.04 × 0.03   Data collection Diffractometer XtaLAB Synergy, Dualflex, HyPix Absorption correction Gaussian (CrysAlis PRO; Rigaku OD, 2019) Tmin, Tmax 0.520, 0.737 No. of measured, independent and observed [I > 2σ(I)] reflections 14650, 726, 687 Rint 0.032 (sin θ/λ)max (Å−1) 1.273   Refinement R[F2 > 2σ(F2)], wR(F2), S 0.011, 0.024, 1.10 No. of reflections 726 No. of parameters 16 Δρmax, Δρmin (e Å−3) 0.61, −0.79 Computer programs: CrysAlis PRO (Rigaku OD, 2019), SHELXT (Sheldrick, 2015a), SHELXL2016/6 (Sheldrick, 2015b) and VESTA (Momma & Izumi, 2011).