I. INTRODUCTION
In the past decades, borate crystals have garnered significant attention due to their diverse applications in nonlinear optical materials, fluorescent materials, and laser crystals (Xu et al., Reference Xu, Liu, Deng, Wu, Wu, Wu, Lin, Lin, Chen and Wang1995; Wang and Chen, Reference Wang and Chen2010). Boron, with its sp2 and sp3 hybridized chemical bonds, can form either BO3 triangles (Wu et al., Reference Wu, Chen, Xu and Sun2006) or BO4 tetrahedra by binding to oxygen atoms (He et al., Reference He, Chen, Okudera and Simon2005). The polymerization of these BO3 and BO4 units gives rise to a wide range of anion groups, resulting in the formation of over 1000 borate compounds with remarkable structural flexibility (Yang et al., Reference Yang, Fan, Li, Sun, Wei, Cheng and Zhao2012). Initially proposed by Ross and Edwards (Reference Ross and Edwards1967), the prevailing understanding in borate chemistry was that BO3 and BO4 groups could only exist in isolation or be linked by common corners, as dictated by Pauling's 3rd and 4th rules (Pauling, Reference Pauling1929). However, Huppertz's group firstly demonstrated that edge-sharing of BO4 polyhedra can be stabilized under extremely high pressure (8–11 GPa) (Huppertz and von der Eltz, Reference Huppertz and von der Eltz2002). The later discovery of KZnB3O6 suggested that edge-sharing BO4 polyhedra can even be thermodynamically stable under ambient pressure (Jin et al., Reference Jin, Cai, Wang, He, Wang and Chen2010; Wu et al., Reference Wu, Yao, Zhang, Fu and Wu2010). At high temperatures, KZnB3O6 exhibits an unusual unidirectional thermal expansion, which plays a role in preserving edge-sharing BO4 from disassociation (Lou et al., Reference Lou, Li, Li, Jin and Chen2015a, Reference Lou, Li, Li, Zhang, Jin and Chen2015b). In the last decade, numerous new borates have been discovered, with an increasing number of them featuring the unusual presence of edge-sharing [BO4] tetrahedra (Mutailipu et al., Reference Mutailipu, Poeppelmeier and Pan2020). Besides, recent research has demonstrated the limited application of the Pauling's rules (George et al., Reference George, Waroquiers, Di Stefano, Petretto, Rignanese and Hautier2020), thus it is not surprising to find more edge-sharing [BO4] tetrahedra. However, while theoretical calculations have been extensively employed to study these edge-sharing BO4 regions (Yang et al., Reference Yang, Fan, Li, Sun, Wei, Cheng and Zhao2012), the experimental investigation on its chemical bonding and charge density distribution remains scarce.
In KZnB3O6, boron binds to oxygen atoms in the form of a BO3 triangle and a BO4 tetrahedron (Jin et al., Reference Jin, Cai, Wang, He, Wang and Chen2010). Polymerization of these B–O blocks leads to the formation of anion groups B6O12, which consist of two BO4 tetrahedra and four BO3 triangles. The BO4 tetrahedra are edge-shared with each other and further corner-shared by BO3 triangles at their outer vertices. It is worth noting that the O–O distance in the edge-sharing zone is exceptionally short, i.e., less than 2.15 Å. For comparison, Figure 1 shows the distribution of O–O atom distances in 1060 borate compounds collected from the Material Project Database (Jain et al., Reference Jain, Ong, Hautier, Chen, Richards, Dacek and Cholia2013), which are predominantly much longer than 2.25 Å. The short O–O distance raises the question of whether there is weak chemical bonding within this edge-sharing region.
Currently, two widely used methods for obtaining experimental charge density from X-ray diffraction data are the multipole refinement method (MM) and the maximum-entropy method (MEM). The MM utilizes multipolar expansions of atomic electron density and offers high-resolution static electron density information (Netzel, Reference Netzel2008). However, the predefined refinable parameters in MM may introduce model-dependent features. In contrast, the MEM reconstructs the electron density distribution (EDD) by maximizing the entropy of the system (Takata et al., Reference Takata, Nishibori and Sakata2001). Therefore, MEM does not rely on specific models or functional forms for EDD. This flexibility is particularly valuable when studying materials that exhibit nontraditional bonding, as is the case with the edge-sharing BO4 unit.
In this study, we utilized synchrotron powder X-ray diffraction (PXRD) to determine the charge density distribution of KZnB3O6. The crystal structure was refined against the PXRD data using the Rietveld method (Rietveld, Reference Rietveld1967). Subsequently, the MEM-based pattern fitting (MPF) method was employed to construct the experimental electron density (Izumi, Reference Izumi2004). It is known that the MEM has the potential to lose structural information due to the overlap of reflections in powder diffraction. Therefore, both room-temperature single crystal X-ray diffraction (SXRD) data (298 K) and high-quality cryogenic SXRD data (81 K) were utilized to construct the charge density using the MEM method. By incorporating these multiple datasets, we aim to capture a comprehensive and accurate representation of the charge density distribution in KZnB3O6.
II. EXPERIMENTAL METHODS
The single crystal and powder samples of KZnB3O6 were prepared for diffraction experiments. For SXRD, a Bruker D8 Venture Photo II diffractometer was used to collect the data at 298 K, and a Rigaku XtaLAB Synergy diffractometer was used to collect the data at 81 K. The single crystal structure solution was performed using Olex2 (Dolomanov et al., Reference Dolomanov, Bourhis, Gildea, Howard and Puschmann2009) and SHELXL (Sheldrick, Reference Sheldrick2008). The dynamic electron density construction was performed using Dysnomia (Momma et al., Reference Momma, Ikeda, Belik and Izumi2013). Visualization of crystal structures and charge density maps was achieved using VESTA (Momma and Izumi, Reference Momma and Izumi2008). To validate the experimental EDD obtained from the two datasets, we conducted ab-initio calculations employing the generalized gradient approximation (GGA) method in the DMol3 package (Delley, Reference Delley2000).
The PXRD data were collected using the high-resolution powder diffractometer at BL15XU. Synchrotron X-rays from an undulator were monochromatized with a liquid nitrogen-cooled Si (311) double-crystal monochromator, and higher harmonics were reduced using a total reflection mirror system. X-rays with an energy of 29.1947 keV (Sn K edge) were employed. The Debye–Scherrer geometry was utilized, with powder samples loaded into capillaries with a diameter of 0.1 mm. The sample-to-detector distance was 955 mm, ensuring a high angular resolution of 0.003° in 2-theta. Rietveld refinement and the MPF method were conducted using the computer programs RIETAN-FP (Izumi and Momma, Reference Izumi and Momma2007) and Dysnomia (Momma et al., Reference Momma, Ikeda, Belik and Izumi2013).
III. RESULTS AND DISCUSSION
A. Crystal structure refinements
The crystal structure and EDD of KZnB3O6 were obtained based on two SXRD data sets collected at 298 and 81 K, respectively. The latter dataset collected at a lower temperature is of higher quality, exhibiting a high d-spacing resolution (d min = 0.50) and a much higher signal-to-noise ratio (I/σ(I) = 78) compared to the 298 K data with d min = 0.65, I/σ(I) = 27.1. The crystal structure of KZnB3O6 was refined using the full-matrix method based on F 2, utilizing the SHELXTL package, and all atoms were refined anisotropically. The refinement process yielded reliability(R) indices of R 1 = 2.35%, wR 2 = 6.35%, R int = 2.04% for the 298 K data, corresponding to completeness of 97.9%, redundancy of 1.22, number of unique reflections of 2112. For the 81 K data, the reliability indices can be further lowered to R 1 = 1.23%, wR 2 = 3.25%, R int = 1.06%, with completeness of 100%, redundancy of 4.20, and number of unique reflections of 4414. The X-ray absorption of both was handled using multi-scan method. More details of SXRD data can be seen in the CIF files deposited as supporting information. Subsequently, the MEM calculations were performed using the Dysnomia package, employing the Limited-memory Broyden–Fletcher–Goldfarb–Shannon (L-BFGS) algorithm to reconstruct the EDD with a grid size of 68 × 70 × 70 pixels in the unit cell.
The structure from PXRD data was further refined in the 2θ range from 3.0 to 30.0° using the Rietveld method implemented in RIETAN-FP. A composite background function based on Legendre polynomials with twelve adjustable parameters was fitted to the background intensities. The pseudo-Voigt function was employed to fit the peak profiles. Attempting to refine the atoms anisotropically led to unstable results for some B atoms and O atoms. Consequently, isotropic atomic displacement parameters were assigned to all atoms. The refinement resulted in reliability (R) indices of R p = 3.457%, R wp = 5.235%, S = 6.0700, R B = 6.666%, R F = 3.163%. The results of the Rietveld refinement on the powder diffraction pattern are displayed in Figure 2(d). Finally, the MPF method was applied to obtain the three-dimensional EDD, with a grid size of 68 × 70 × 70 pixels in the unit cell. After two REMEDY cycles, the reliability indices decreased to R B = 2.847% and R F = 1.493%, respectively.
The crystal structure of KZnB3O6, depicted in Figure 2, reveals a unit cell consisting of 22 atoms. The compound maintains its inversion symmetry (space group P-1) between temperatures of 81 K and 298 K. As illustrated in the inset of Figure 2(d), this compound exhibits two edge-sharing BO4 units, comprising two corner-shared B3O3 rings connected by a B2O2 ring. The refined cell parameters obtained through various methods are summarized in Table I. The unit cell volume increases from 269.646 to 272.68 Å3 between 81 and 298 K. The structural parameters for single crystal KZnB3O6 at 298 and 81 K are listed in Table II and Table III, respectively. Table IV provides the structural parameters for the powder data at 100 K.
B. Charge density distributions
Figures 2(a) and 2(b) display the experimental charge density ρ(r) obtained from SXRD at 298 and 81 K, respectively. Additionally, Figure 2(c) showcases the experimental ρ(r) derived from the PXRD data. In all cases, the equidensity isosurfaces of the 3D ρ(r) demonstrate satisfactory agreement with the corresponding atom arrangements. It is important to note that the experimental ρ(r) represents a dynamic function that incorporates thermal effects. As depicted in Figure 2(a), the influence of thermal motion on the charge density is evident, with significant anisotropic thermal motion at 298 K causing expansion of the electron density isosurface along the stronger vibrational direction. Conversely, at 81 K, the electron density isosurface appears more isotropic due to reduced thermal effects, as shown in Figure 2(b). Meanwhile, in the PXRD case, while the crystal structures and ρ(r) maps generally align, it is worth noting that the resulting thermal motion factors and ρ(r) isosurfaces are larger than those obtained from the SXRD datasets. This observation suggests that the powder diffraction data provide the least precise ρ(r) in the present study.
The most intriguing feature of KZnB3O6 lies in its edge-sharing B–O section, specifically the B6O12 block composed of two BO4 tetrahedra and four BO3 triangles. The BO4 tetrahedra share edges with each other and are further connected to BO3 triangles at their outer vertices (see the insert in Figure 2(d)). In Figure 3, we present two-dimensional slices of the charge density distribution in the B3O3 ring and B2O2 ring, obtained from the synchrotron PXRD data at 100 K, as well as the SXRD data at 298 and 81 K.
From Figures 3(a)–3(c), all illustrate the experimental ρ(r) of the corner-shared B–O hexatomic ring, which is a common structural motif in borate crystals. The center of the six atoms is clearly visible in the ρ(r) map, which is projected onto the (−1.43433, 1, 1.03254) plane intersecting the B3O3 ring. To enhance the visualization of charge density in the bonding region, the ρ(r) range is limited to values lower than 1.5 e/Å3. Additionally, we observe an obvious electron segregation within the B3O3 ring in the bonding region, indicative of the involvement of p atomic orbitals in the formation of covalent bonds. Notably, in the bonding region of the B–O hexatomic ring, the charge density obtained from the PXRD data becomes discontinuous at the lower level of 0.8 e/Å3, confirming it is not as precise as the results from the SXRD data.
To investigate the nature of bond interactions in the edge-sharing region, we present the ρ(r) map in the (1.13693, 2.90022, −1) plane intersecting the B2O2 ring (from Figures 3(d)–3(f)). In this plane, the two heavier atoms with higher ρ(r) values correspond to the O element, while the smaller two atoms represent B. Similar to the observations in the B–O hexatomic ring, we observe distinct electron segregation within the B2O2 ring in the B–O bonding region, indicating the involvement of p atomic orbitals in the formation of covalent bonds. Interestingly, both the room temperature SXRD data and the cryogenic synchrotron PXRD data reveal a fascinating phenomenon: the edge-shared B2O2 ring exhibits a significant accumulation of charge density between the O atoms. This unconventional O–O bonding is unexpected, as O–O covalent bonds are primarily observed in organic compounds. Such O–O covalence bonds are less common in inorganic systems, typically limited to certain metal peroxides and superoxides.
However, based on the high-quality SXRD data, it was demonstrated that the unusually accumulated electrons in the O–O bonding region are absent. The SXRD data at 81 K, with its high resolution (d min = 0.50) and high signal-to-noise ratio (I/σ(I) = 78), provide more reliable charge density information. As shown in Figure 3(e), electron accumulation is observed solely in the B–O bond region within the edge-sharing B2O2 ring, suggesting that chemical bonding is still predominantly governed by B–O sp3 bonding. This finding is consistent with the results of theoretical calculations performed using the experimental cell parameter of 81 K SXRD data, as illustrated in Figures 4(a) and 4(b). The one-dimensional electron density profiles along the O1–O1 bond in the B2O2 ring obtained by three experiments are compared with ab-initio calculations in Figure 4(c), demonstrating that electron density from the 81 K SXRD data is of the most accurate, while the PXRD provides the worst accuracy. Furthermore, to study the topology of charge density, the critical point in the middle of the B2O2 ring was calculated with the aid of the EDMA program (van Smaalen et al., Reference Smaalen, Palatinus and Schneider2003). A critical point of (3, +1) is found in both 81 and 298 K SXRD, which means the center of a ring structure without chemical bonding. However, the 100 K PXRD gives a critical point of (3, −1), showing the feature of a chemical bond. Considering all these factors above, the electron density obtained by the 81 K SXRD is the most plausible. Hence, it is evident that high-quality SXRD data collected at low temperatures is crucial in obtaining reliable experimental ρ(r) values for KZnB3O6 using MEM.
IV. CONCLUSIONS
In conclusion, our study successfully constructed the experimental charge density of KZnB3O6 using the maximum-entropy method, incorporating both synchrotron powder diffraction and laboratory single crystal diffraction data. In the current case, the room temperature single crystal diffraction data and the cryogenic synchrotron powder diffraction data only lead to inaccurate charge density distributions. By utilizing cryogenic single crystal diffraction data with a higher signal-to-noise ratio and resolution limit, we obtained an accurate experimental EDD of KZnB3O6. The later EDD demonstrated excellent agreement with the results obtained from theoretical calculations. Our results highlight the significance of collecting high-quality diffraction data to obtain reliable experimental electron density information. The findings also contribute to a better understanding of the bonding interactions and electron distribution in borate crystals.
V. DEPOSITED DATA
The single crystal and powder data were deposited with ICDD. The data can be requested by contacting pdj@icdd.com. The single crystal data at 298 K, 81 K, and the powder data at 100 K are also deposited as Crystallographic Information Files.
ACKNOWLEDGEMENTS
The single crystal X-ray diffraction at 81 K of this work was carried out at the Synergetic Extreme Condition User Facility (SECUF). We thank Tao Sun for his assistance in this measurement. This work is financially supported by the National Key Research and Development Program of China (Grant No. 2018YFE0202600), the National Natural Science Foundation of China (Grant No. 52272268), the Key Research Program of Frontier Sciences, CAS (Grant No. QYZDJ-SSWSLH013), the Informatization Plan of Chinese Academy of Sciences (Grant No. CAS-WX2021SF-0102), and the Youth Innovation Promotion Association of CAS (Grant No. 2019005).