Introduction
Zintl phases, a unique category of intermetallic compounds, were first introduced by E. Zintl in 1939, and have attracted considerable research attention.[1] Zintl compounds are characterized by their intricate chemical bonding and structural features. Their valence bonding modes can encompass ionic, metallic, and covalent interactions, reflecting their remarkable compositional and structural diversity.[2] Zintl compounds are primarily categorized into layered, chain, cage, etc. These classifications often include AB2X2, A5B2X6, AX3, and B4X3, with A representing alkali, alkaline-earth or rare-earth metals, B representing transition metals, and X representing metalloids.[3] With flexible structures, Zintl compounds possess a broad spectrum of physical properties, encompassing superconductivity, topological properties, magnetic order thermoelectricity, etc.[3i,4]
In recent years, the layered SnAs-based Zintl compounds have attracted much attention.[5] Layered Zintl compound NaSn2As2 crystallizes in trigonal Rm structure, where Na+ ions are separated by two honeycombs [SnAs]2− layers. The adjacent honeycomb layers interaction is via van der Waals (vdW) forces.[5f,i] At ambient pressure, NaSn2As2 shows bulk superconductivity with Tc of 1.3 K.[5f,i] It should be noted that NaSn2As2 is a nonelectron-balanced compound, containing Sn2+ ions with lone pairs of electrons.[5c,6] In contrast to NaSn2As2, the isostructural compound EuSn2As2 is electron-balanced one. EuSn2As2 contains magnetic Eu2+ ions, forming a peelable layered magnetic Zintl phase.[7] A transition from the paramagnetic (PM) to the antiferromagnetic (AFM) phase in EuSn2As2 occurs around TN–24 K.[7a,8] Below TN, EuSn2As2 is ferromagnetic in the a,b plane and antiferromagnetic between adjacent layers, forming an A-type AFM. A combination of first-principles calculations and angle-resolved photoemission spectroscopy (ARPES) experiments reveal that EuSn2As2 is a magnetic topological insulator (TI), characterized by the absence of an observable gap in the Dirac topological surface states (SSs). Besides, EuSn2As2 transforms from a strong TI with PM state to an axial insulator with AFM state below TN.[9] TN shows a linear increase with pressure below 10 GPa, attributed to the enhanced interlayer magnetic exchange coupling among Eu2+ ions.[10] Beyond ≈14 GPa, EuSn2As2 experiences a two-step high-pressure structural transformation, giving rise to a novel monoclinic configuration. The bent Sn─Sn bonds become planar and form honeycomb Sn sheets, coinciding with the emergence of superconductivity ≈4 K.[11]
SrSn2As2 is the sister compound of EuSn2As2, which remains relatively less explored. Theoretical calculations propose that SrSn2As2 is a potential candidate for the novel 3D Dirac semimetal.[12] The ARPES results presented a band reversal feature near the Γ point, indicating that SrSn2As2 may be a new topological insulator.[13] Given that EuSn2As2 is superconducting under high pressure, it is interesting to explore novel quantum phenomena in SrSn2As2 upon compression. Hence, we systematically investigate the structural and electronic properties of the SnAs-based Zintl compound SrSn2As2 under high pressure. Interestingly, we observe the pressure-induced superconductivity in SrSn2As2, with a nonmonotonic evolution of Tc. Our theoretical calculations reveal that SrSn2As2 undergoes a structural transformation from a rhombohedral to a monoclinic phase under high pressure, as evidenced by both X-ray diffraction (XRD) and Raman data. The electronic band structure of the high-pressure phase and the evolution of Tc are also discussed.
Results and Discussion
Prior to high-pressure measurements, we first check the sample quality by single-crystal and powder XRD diffractions. The single crystal XRD pattern on the (00l) flat surface of the sample shows sharp diffraction peaks (Figure 1a). The inset of Figure 1b shows the chemical compositional analysis results using EDX, illustrating a Sr:Sn:As atomic ratio of 20.45:38.97:40.59, which is consistent with the nominal composition. In addition, we further performed the powder XRD for phase examinations. As shown in Figure 1b, all the Bragg peaks can be indexed into a rhombohedral structure with the space group Rm. The calculated lattice parameter are a = 4.2012(7) Å and c = 26.7155(4) Å, in agreement with the previous report.[5a] The consistency between powder and single crystal XRD measurements guarantees the correct phase. The ambient crystal structure of SrSn2As2 is shown in Figure 1c, which is identical to the configuration of EuSn2As2 and NaSn2As2.[5i,11a] Then, we performed transport measurements at ambient pressure. Figure 1d shows the resistivity of SrSn2As2 as a function of temperature, showing typical metallic behavior with residual resistivity ratio (RRR) = 2.31.
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Since NaSn2As2 showed superconductivity at ambient pressure and EuSn2As2 achieved superconductivity upon compression, it is natural to explore superconductivity in SrSn2As2 using high-pressure technology. Hence, we investigated the effect of high pressure on SrSn2As2 single crystals. Figure 2a shows the electrical resistivity ρ(T) of SrSn2As2 at various pressures. Increasing pressure induces a continuous suppression of the overall magnitude of ρ(T), which is typical behavior of metal under high pressure. As shown in Figure 2b, the resistivity of SrSn2As2 drops abruptly at ≈2.5 K at 10.3 GPa. The resistivity drop becomes more pronounced upon further compressing. Above 28.3 GPa, zero resistivity is observed at low temperatures, indicating a superconducting transition. The superconducting transition temperature Tc (90% drop of the normal state resistivity) reaches 4.63 K at P = 28.3 GPa. As plotted in Figure 2c, Tc decreases slowly beyond this pressure, and the superconductivity persists up to 53.5 GPa. The temperature dependence of transition width ΔTc (10–90% of the normal state resistivity at Tc) is in Figure 6 and Figure S1 (Supporting Information). The transition width ΔTc has a sharp decline from 2.07 to 0.44 K in the pressure range from 22.9 to 34.4 GPa. ΔTc reflects the superconducting stated disturbance originating from the thermodynamic fluctuations, the applied magnetic field, the presence of secondary crystalline phases, the applied pressure, etc.,[14] which needs further evidence to confirm its origin. The overall behavior of Tc reveals a nonmonotonic evolution under high pressure. Interestingly, Tc is also observed during decompression, and the superconducting transition persists until recovery to 14.9 GPa.
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To gain insight into the superconducting transition, we applied an external magnetic field to samples subjected to 28.3 and 48.1 GPa, respectively. Figure 2d,e demonstrate that the Tc is continuously suppressed with increasing magnetic field and the superconducting transition could not be observed above 1.8 K at ≈2.5 T. This confirms that the sharp drop of ρ(T) ≈4 K in SrSn2As2 originates from a superconducting transition. The upper critical field μ0Hc2 is determined from the 90% point on the resistivity transition curve, and the plot of temperature normalized Hc2(T) is shown in Figure 2f. By fitting the data using the Ginzburg–Landau (G-L) formula μ0Hc2 (T) = μ0 Hc2(T)(1 − t2)/(1 + t2), where t = T/Tc is the reduced temperature with zero-field superconducting Tc. The extrapolated upper critical fields μ0Hc2 (0) at 28.3 and 48.1 GPa are 2.05 and 2.41 T, which yields a Ginzburg-Landau coherence length ξGL(0) of 12.68 and 11.69 nm, respectively.
The transition width ΔTc drastically changed at ≈30 GPa, and the slopes of dHc2/dT are notably different: −0.53 and −0.69 T/K for 28.3 and 48.1 GPa, respectively. Our results suggest that the nature of the superconducting state beyond 30 GPa may differ from that of the initial superconducting one. In order to identify the structural stability of SrSn2As2 under high pressure, we have performed high-pressure in situ synchrotron XRD and Raman spectroscopy measurements. The XRD patterns of SrSn2As2 collected at different pressures are shown in Figure 3a. As the pressure increases, all diffraction peaks move to higher angles due to lattice contraction, and no structural phase transition is observed at pressures up to 29.8 GPa. Above 33.0 GPa, additional diffraction peaks appear, indicating a structural phase transition. Figure 3b presents the Raman spectra of SrSn2As2 under various pressures up to 55.5 GPa. With increasing pressure, the interaction force between adjacent layers increases and all four phonon modes exhibit blue shift, which is analogous to EuSn2As2.[11b] The Raman signals of the mode become significant, while mode decreases monotonically. An abrupt disappearance of Raman peaks for pressure beyond 33.6 GPa indicates the structural phase transition to a high-pressure phase. The evolution of the Raman spectra is consistent with our synchrotron XRD patterns and provides further evidence for pressure-induced structural phase transition.
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It should be emphasized that by only relying on the experimental data, the structural solution of high-pressure phases is not possible, because the XRD peaks are rather weak and broad. Hence, we performed the structure predictions at 30 and 50 GPa, respectively. In each search, structures were evaluated within 25 generations with 30 structures per generation, and the ambient stable structure Rm was treated as a seed structure. We found one stable monoclinic structure with space group C2/m under high pressure, as shown in the inset of Figure 4a. The buckled Sn─Sn bonds become planar and form honeycomb-like Sn sheets, meanwhile, the SnAs layers further connect to each other via the As─As bonds across the Sr layers to form zigzag As chains between the Sn sheets. This 3D monoclinic structure comprising honeycomb-like Sn sheets and zigzag As chains resembles the situation in EuSn2As2 identified under high pressure.[11a] As the enthalpy difference relative to Rm structure in Figure 4a, the enthalpy of C2/m structure is below that of Rm above 22 GPa, suggesting that C2/m structure is more energetically stable under high pressure. Then we calculated the phonon spectrum of C2/m structure under high pressure, as plotted in Figure 4b,c. There are no imaginary frequencies in the phonon dispersion for C2/m phase above 25 GPa, illustrating its dynamical stability. In summary, our theoretical and experimental results suggest that there is a structural phase transition from Rm phase to C2/m phase under high pressure.
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Next, we calculated the electronic structures of C2/m structure under high pressure. As depicted in Figure 5a,c, the valence bands and conduction bands cross the Fermi energy in the band structures of C2/m phase, exhibiting typical metal characteristics. We can observe steep conduction bands crossing the Fermi energy, which is beneficial for superconductivity. The corresponding partial density of states (PDOS) is shown in Figure 5b,d. The Sn atoms make the main contribution at the Fermi energy, and the total density of states (DOS) at Fermi energy N(Ef) decreases from 5.2 states/formula at 25 GPa to 4.1 states/formula at 50 GPa, which agrees with the slow decreasing of Tc from 28.3 to 53.5 GPa.
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To confirm the emergence of a superconducting state under high pressure, we repeated the measurements with new samples for a second run and proved that all the results were reproducible (Figure S2, Supporting Information). Based on the aforementioned results, we can establish a Tc-P phase diagram for SrSn2As2 as shown in Figure 6. Superconductivity was observed at ≈10.3 GPa with a maximum Tc of 4.63 K at 28.3 GPa for SrSn2As2. The high-pressure in situ synchrotron XRD and Raman spectroscopy reveal evidence of structural transition ≈28.3 GPa, which is in line with the theoretical predictions that the ambient Rm phase transforms to the high-pressure C2/m phase. Combining the transition width ΔTc and theoretical calculations, the Tc-P phase diagram reveals two distinct superconducting regions: SC-I Rm phase and SC-II C2/m phase. In the SC-I region, Tc increases with pressure with a broad superconducting transition width. In the SC-I region between 25 and 60 GPa, Tc is monotonically suppressed with external pressure. The suppression of Tc in SrSn2As2 under pressure can be attributed to a decline in the electronic density of states at the Fermi level.
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Conclusion
In summary, we have synthesized SrSn2As2 single crystal and explored the structure and electronic transport properties under high pressure. Our results demonstrate a pressure-induced superconductivity in SrSn2As2. The pressure-dependent Tc exhibits a nonmonotonic evolution with a maximum value of 4.63 K at 28.3 GPa. Our theoretical calculations, together with high-pressure in situ X-ray diffraction, and Raman spectroscopy measurements, indicate that SrSn2As2 transforms from the ambient rhombohedral Rm phase to the monoclinic C2/m phase above 25 GPa. Our research provides valuable insights into the understanding of the superconductivity in the layered SnAs-based family.
Experimental Section
The single crystals of SrSn2As2 were grown by the self-flux method. In order to obtain high-quality single crystals, pretreatment of starting materials (Sn, Alfa Aesar, 99.999% and As, Alfa Aesar, 99.99%) was performed to remove possible oxide layers on their surface by hydrogen reduction method and sublimation recrystallization method. High-purity starting materials of Sr, Sn, and As were loaded into an Al2O3 crucible with the atomic ratio of Sr: Sn: As = 1: 2: 2.2, and sealed into a quartz tube in a vacuum of 8 × 10−4 Pa. The raw materials were reacted and homogenized at 1173 K for several hours, followed by cooling down to 773 K at a rate of 3 K h−1. The crystalline phase of SrSn2As2 was checked by X-ray diffraction (XRD, Cu Kα, λ = 1.54184 Å). The chemical composition of SrSn2As2 is given by energy-dispersive X-ray spectra (EDX). Electrical transport properties were performed on a physical property measurement system (PPMS, Quantum Design).
Electrical transport measurements under high pressure were performed in a nonmagnetic diamond anvil cell (DAC).[15] A cubic BN/epoxy mixture layer was inserted between the BeCu gasket and electrical leads. Four platinum sheet electrodes were touched to the sample for resistance measurements with the van der Pauw method.[15b,16] Pressure was determined by the ruby luminescence method.[17] High-pressure in situ Raman spectroscopy investigation was performed using a Raman spectrometer (Renishaw in Via, UK) with a laser excitation wavelength of 532 nm and a low-wavenumber filter. Asymmetric DAC with anvil culet sizes of 300 μm was used, with silicon oil as pressure transmitting medium (PTM). High-pressure in situ XRD measurements were performed at beamline BL15U of Shanghai Synchrotron Radiation Facility (X-ray wavelength λ = 0.6199 Å). A symmetric DAC with anvil culet sizes of 200 μm and a Re gasket were used. Silicon oil was used as the PTM. The 2D diffraction images were analyzed using the FIT2D software.[18] Rietveld refinements of crystal structure under various pressures were performed using the GSAS and the graphical user interface EXPGUI.[19]
We used the machine learning graph theory accelerated crystal structure search method (Magus) to explore the structures of SrSn2As2 under 30 and 50 GPa.[20] We performed the geometry optimization using the Vienna Ab initio Simulation Package (VASP) based on the density functional theory.[21] The exchange-correlation function was treated by the generalized gradient approximation of Perdew, Burkey, and Ernzerhof.[22] The calculations used a projector-augmented wave (PAW) approach to describe the core electrons and their effects on valence orbitals.[23] The plane-wave kinetic-energy cutoff was set to 600 eV, and the Brillouin zone was sampled by the Monkhorst-Pack scheme of 2π × 0.03 Å−1. The convergence tolerance was 10−6 eV for total energy and 0.003 eV Å−1 for all forces. The electronic structure calculations used a denser k-mesh grid of 2π × 0.02 Å−1. The phonon spectrum was calculated by the PHONOPY program package using the finite displacement method with the supercell 2 × 2 × 2.[24]
Acknowledgements
W.C., J.W., and Y.L. contributed equally to this work. This work was supported bythe National Natural Science Foundation of China (Grant No. 52272265), the National Key R&D Program of China (Grant Nos. 2018YFA0704300, 2023YFA1607400), and Shanghai Science and Technology Plan (Grant No. 21DZ2260400). Z.W.W. thanks the support from the National Key R&D Program of China (Grant Nos. 2020YFA0308800 and 2022YFA1403400), the Natural Science Foundation of China (Grant No. 92065109), the Beijing Natural Science Foundation (Grant Nos. Z210006 and Z190006). The authors thank the Analytical Instrumentation Center (# SPST-AIC10112914), SPST, ShanghaiTech University, and the Analysis and Testing Center at Beijing Institute of Technology for assistance in facility support. The authors thank the staff from BL15U1 at Shanghai Synchrotron Radiation Facility for assistance during data collection.
Conflict of Interest
The authors declare no conflict of interest.
Data Availability Statement
The data that support the findings of this study are available from the corresponding author upon reasonable request.
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Abstract
Layered SnAs‐based Zintl compounds exhibit a distinctive electronic structure, igniting extensive research efforts in areas of superconductivity, topological insulators, and quantum magnetism. In this paper, the crystal structures and electronic properties of the Zintl compound SrSn2As2 upon compression are systematically investigated. Pressure‐induced superconductivity is observed in SrSn2As2 with a nonmonotonic evolution of superconducting transition temperature Tc. Theoretical calculations together with high‐pressure synchrotron X‐ray diffraction and Raman spectroscopy have identified that SrSn2As2 undergoes a structural transformation from a rhombohedral Rm phase to the monoclinic C2/m phase. Beyond 28.3 GPa, Tc is suppressed due to a reduction of the density of state (DOS) at the Fermi level. The discovery of pressure‐induced superconductivity, accompanied by structural transitions in SrSn2As2, greatly expands the physical properties of layered SnAs‐based compounds and provides new ground states upon compression.
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; Wu, Juefei 1 ; Li, Yongkai 2 ; Pei, Cuiying 1 ; Wang, Qi 3 ; Zhao, Yi 1 ; Li, Changhua 1 ; Zhu, Shihao 1 ; Zhang, Mingxin 1 ; Zhang, Lili 4 ; Chen, Yulin 5 ; Wang, Zhiwei 2 ; Qi, Yanpeng 6
1 School of Physical Science and Technology, ShanghaiTech University, Shanghai, China
2 Centre for Quantum Physics, Key Laboratory of Advanced Optoelectronic Quantum Architecture and Measurement (MOE), School of Physics, Beijing Institute of Technology, Beijing, China, Beijing Key Lab of Nanophotonics and Ultrafine Optoelectronic Systems, Beijing Institute of Technology, Beijing, China, Material Science Center, Yangtze Delta Region Academy of Beijing Institute of Technology, Jiaxing, China
3 School of Physical Science and Technology, ShanghaiTech University, Shanghai, China, ShanghaiTech Laboratory for Topological Physics, ShanghaiTech University, Shanghai, China
4 Shanghai Synchrotron Radiation Facility, Shanghai Advanced Research Institute, Chinese Academy of Sciences, Shanghai, China
5 School of Physical Science and Technology, ShanghaiTech University, Shanghai, China, ShanghaiTech Laboratory for Topological Physics, ShanghaiTech University, Shanghai, China, Department of Physics, Clarendon Laboratory, University of Oxford, Oxford, UK
6 School of Physical Science and Technology, ShanghaiTech University, Shanghai, China, ShanghaiTech Laboratory for Topological Physics, ShanghaiTech University, Shanghai, China, Shanghai Key Laboratory of High‐resolution Electron Microscopy, ShanghaiTech University, Shanghai, China