Introduction

The recent discovery of the Fe-based high temperature superconductors with superconducting transition temperatures as high as 55 K1,2 have attracted world-wide attention despite the magnetism of Fe. Among them, 11 compounds with Tc of 8 K possesses the simplest crystal structure3, containing a single layer of tetrahedrally coordinated Fe atoms to chalcogen atoms (Se/Te). This simplicity of structure and presence of less toxic Se as compared to As make 11 compounds more attractive to study the superconductivity mechanism in iron based superconductors as well as their possible technological applications.

Even more remarkably, the onset Tc of binary β-FeSe1−x was shown to be as high as 27 K4 with applied hydrostatic pressure, which suggests a possibility of increasing Tc via the chemical pressure route. Therefore, it is considered that chemical substitutions can be an alternative way to introduce pressure to change parameters and thereby affect superconductivity in the search for novel superconducting materials. Subsequently, several groups focused on different substitutions of ions with varied ionic radius upon either the Fe-site or the Se-site. Until now, the partial substitution of Se by Te and S has been found to significantly increase the Tc, e.g. with a maximum onset Tc of 15 K for FeSe0.5Te0.5 or FeS0.2Te0.85,6,7.

Meanwhile, the effect of various metals dopants, such as Al, Ti, V, Cr, Mn, Co, Ni, Cu, Ga, In, Ba and Sm on the FeSe1−x superconducting polycrystalline samples obtained by a solid state reaction was investigated in previous study8,9. Among them, Co, Ni, Cu, Al, Ga or Sm doped samples consist of mainly the tetragonal phase and these dopants occupied the Fe-sites and resulted in the changes in the lattice constants. On the other hand, the rest of the studied metal dopants did not incorporate into the host lattice of superconducting FeSe1−x and mainly formed inclusions with elements (Fe or Se) not incorporated into the matrix. However, in either case, the Tc in these doped FeSe1−x samples were generally suppressed, or even no longer emerged according to the resistivity as a function of temperature. Superconducting single crystal of pure FeTe1−xSex (x = 0.3–0.55) doped with Co, Ni, Cu, Mn, Zn, Mo, Cd, In, Pb, Hg, V, Ga, Mg, Al, Ti, Cr, Sr or Nd were also studied and the similar results were found in these doped single crystals10.

Based on these backgrounds, doping of various metals in the FeSe polycrystalline bulks or single crystal samples seems to be a noneffective way to raise Tc. Consequently, lots of research teams around world lost their interest in exploring the doping of various metals and mainly focused on the research of substitution of Se-site by Te and S in recent years. Nevertheless, in present work, Mg doped FeSe polycrystalline bulks were prepared by two-step solid-state reaction method, which exhibits enhanced Tc compared to undopoed FeSe sample. The corresponding enhancement mechanism is also discussed in detail, appearing to be quite different from that of the other metals doped FeSe polycrystalline bulks in previous studies.

Experimental details

Polycrystalline bulk samples FeSe0.9Mgx (x = 0, 0.2, 0.4 and 1) were prepared by two-step solid-state reaction method. The Fe powder (99.99% purity) and Se powder (99.5% purity) were firstly mixed in a molar ratio of FeSe0.9. The mixed powders were cold-pressed into pellets of 5 mm in diameter and 2 mm in thickness under a uniaxial pressure of 5 MPa. All the pressed pellets were placed in an alumina crucible inside a quartz tube furnace and then sintered at 650°C for 24 h under protection of ultra-high purity Ar gas. After slowly cooling down to room temperature, these sintered FeSe0.9 bulks were reground into powders. Then these powders was mixed homogeneously with Mg powders (99.99% purity) in a molar ratio of FeSe0.9Mgx (x = 0, 0.2, 0.4 and 1). The mixed powders were cold-pressed into pellets again. All the pressed pellets were placed in an alumina crucible inside a quartz tube furnace again and then sintered at 750°C for 0.5 h under protection of ultra-high purity Ar gas.

The phase composition of the sintered samples was determined by X-ray diffractometer (XRD) using Rigaku D/max2500 X-ray diffractometer with Cu Kα radiation. The morphologies were examined by field–emission scanning electron microscopes (SEM, S-4800, Hatachi). The sample resistance was measured using the standard four-probe method.

Results and Discussion

Figure 1 shows the temperature dependence of electrical resistivity for the sintered FeSe0.9Mgx (x = 0, 0.2, 0.4 and 1) samples. The positive slope of ρ(T) indicates that these samples exhibit metallic behavior. It is also found that Mg-doped samples possess higher resistivity than that of undoped samples at normal state, which can be attributed to the electron scattering effect owing to Mg doping. From this point of view, the resistivity of doped samples at normal state ought to increase as the amount of Mg addition increases. But their actual resistivity performance is out of our expectation. In fact, the resistivity of doped samples at normal state gradually decreased as the amount of Mg addition increased from FeSe0.9Mg0.2 to FeSe0.9Mg. Especially, the resistivity of FeSe0.9Mg is even lower than undoped FeSe0.9 sample when the temperature is below 150 K. These unique results are totally different from the case of other metal doped FeSe samples reported in previous study8,9. Figure 1b presents the detailed temperature dependence of electrical resistivity for the sintered samples between 5 K and 30 K. It can be found that the onset of the transition temperature (Tconset) of undoped FeSe0.9 is about 9.8 K, consistent with previous report3. As for FeSe0.9Mg0.2 and FeSe0.9Mg sintered samples, their Tconset are comparable to the undoped sample. More precisely, their Tconset are even a bit higher than that of undoped sample. On the other hand, the Tconset of FeSe0.9Mg0.4 is significantly increased to 12.3 K, about 25% higher than that of undoped sample. This result is abnormal considering that most of metal dopants substituting on Fe site generally brought about the depression of Tc8,9,10.

Figure 1
figure 1

the temperature dependence of electrical resistivity for the FeSe0.9Mgx (x = 0, 0.2, 0.4 and 1) samples prepared by two-step sintering, with (a) the whole measured temperature range from 5 K to 300 K and (b) the enlarged range between 5 K and 30 K.

The abnormal results of Tc obtained hereby imply that the introduction of proper amount of Mg addition by two-step sintering method seems open possible windows for the enhancement of Tc in FeSe superconductors via metal doping. In order to clarify the enhancement mechanism in the Tc of the prepared sample, the phase composition and microstructure are investigated in detail.

Figure 2a shows the X-ray diffraction patterns of sintered FeSe0.9Mgx (x = 0, 0.2, 0.4 and 1) samples. One can see that superconducting phase, β-FeSe, is the main phase in all the sintered samples. Some common impurities, Fe7Se8 and Fe3O4, are also recognized in FeSe0.9 sample. As the amount of Mg dopant was added from FeSe0.9Mg0.2 to FeSe0.9Mg, the intensity of β-FeSe peaks decreased while the peaks corresponding to MgSe and Fe emerge and gradually become stronger. Observing Fig. 2a more carefully, one can also see that all the MgSe main peaks are very close to and even overlap with β-FeSe peaks in the patterns (for example, MgSe (200) peak and β-FeSe (002) peak, MgSe (220) peak and FeSe (112) peak, MgSe (111) peak and FeSe (101) peak). Besides, it is noticed that the positions of (001) and (101) peaks corresponding to β-FeSe phase almost keep unchanged with the amount of Mg addition increasing, as shown in Fig. 2b and Fig. 2c, suggesting that the lattice parameters (a and c) of β-FeSe almost remain unchanged. Based on the above XRD results, it can be concluded that Mg dopant mainly reacted with FeSe forming MgSe and Fe: Mg + FeSe = MgSe + Fe and seldom entered into crystal lattice of β-FeSe and substitute of Fe-site.

Figure 2
figure 2

the X-ray diffraction patterns of FeSe0.9Mgx (x = 0, 0.2, 0.4 and 1) samples prepared by two-step sintering, with (a) The whole measured view, (b) Magnified view of β-FeSe (001) peak and (c) Magnified view of β-FeSe (101) peak.

The SEM images of sintered FeSe0.9Mgx (x = 0, 0.2, 0.4 and 1) samples are given in Fig. 3. It can be seen that the sintered undoped FeSe sample is dense and consisted of small randomly aligned grains (about 500 nm in size, see Fig. 3a), which is the typical characteristic of FeSe bulks prepared by traditional solid-state sintering11,12. On the other hand, regular layered grains are observed in the sintered Mg-doped samples. As the amount of Mg addition increases, the percent of layered grains increased and finally the layered grains dominate in the microstructure of sintered FeSe0.9Mg0.4 and FeSe0.9Mg samples. Moreover, the size of layered grains also enlarges as Mg addition increases. Interestingly, observing Fig. 3c and Fig. 3d more carefully, one can see that the thickness of each layer in these layered grains is very small (only about 100 nm) and also very homogeneous. This unique microstructure was seldom observed in other-metal doped FeSe samples. Combined with the XRD results, Mg addition mainly reacts with FeSe forming MgSe. The formation of these layered grains is supposed to be closely related with this reaction. Since the produced MgSe shares the similar x-ray diffraction characteristics with β-FeSe, it can incorporate into superconducting β-FeSe matrix, finally forming these multi-layered grain structure in the sintered Mg-doped sample. This speculation can be further proved by the elemental maps of Se, Fe and Mg for the microstructure of Mg doped smple, as shown in Fig. 4. It can be seen from Fig. 4 that Fe distributes uniformly in the whole SEM image while Mg and Se are relatively concentrated at the region of layered grains, as marked by white squires in Fig. 4. This result suggests that the layered grains are mainly consisted of MgSe and FeSe.

Figure 3
figure 3

the typical SEM images of (a) FeSe0.9, (b) FeSe0.9Mg0.2, (c) FeSe0.9Mg0.4 and (d) FeSe0.9Mg samples prepared by two-step sintering.

Figure 4
figure 4

the elemental maps of Fe, Mg and Se For the microstructure of Mg doped FeSe0.9 sample prepared by two-step sintering.

The region of some layer grains was marked by white squares.

Combined with all the above results of superconducting properties, phase composition and microstructure, As Mg addition has little effect on the crystal lattice parameters of β-FeSe, but leads to the formation of unique layered grain structure consisted of MgSe and FeSe, it can be suggested that the enhancement of Tc in the FeSe0.9Mg0.4 sample should be attributed to the multi-layered grain structure. Interestingly, Nabeshima et al have just reported that FeSe epitaxial thin film deposited on CaF2 (100) substrate exhibits significantly enhanced Tc13. In fact, the multi-layered grain structure in sintered FeSe0.9Mg0.4 samples here is consisted of lots of homogenous and thin MgSe and FeSe layers (as described above, the thickness of each layer is about 100 nm, see Fig. 3c), just like as the FeSe thin films on the MgSe substrates. MgSe is very similar with CaF2 in the crystal structure and crystal constants (Cubic, a = 5.463 and 5.462 for MgSe and CaF2, respectively). From this view, our result is coincidently consistent with their research. They attribute the enhancement of Tc to the change of crystal lattice parameters a/c ratio. However, the lattice parameters of FeSe bulks almost keep unchanged by Mg doping in our work. There must be other mechanism underlying the enhancement of Tc here.

Besides Nabeshima et al's work, FeSe and FeSexTe1−x thin films with much higher Tc than those of bulk superconductors have also been achieved by other groups recently, especially the thin films on the substrate with quite similar lattice constants with them14,15,16. In these films, it was found that the Tc of these films is significantly enhanced, whereas their lattice parameters changed very little, or even remained unchanged. The effect of the change in lattice parameters is too weak to account for the improvement of Tc. It was suggested that the interface effect plays an important role in increasing Tc of these thin films14,16. In fact, interface effect has always been an interesting topic in the superconducting field. A lot of previous studies reported some unique superconducting phenomena at the various interfaces17,18,19.

In the case of FeSe0.9Mg0.4 sample prepared in present work, there are a lot of nano-structural interface between FeSe and MgSe formed in the multi-layered grain structure of Mg-doped sample. As we all know, MgSe is wide band gap semiconductor with bandgap energy of about 4.0 ev. One can imagine that the interfaces between MgSe and FeSe forming in present work have an important effect on the superconducting properties of FeSe. These interfaces might enhance electron-phonon coupling, as reported in the interface of atomically uniform films of Ag on Fe substrate17. Another possibility is formation of two-dimensional electron gas at these interfaces, which may cause the higher Tc, as demonstrated in Ref. [18]. Further research need to be carried out to elucidate the mechanism underlying the enhancement of Tc observed here.

Based on the interface effect discussed above, it also explains well why the Tc performance in FeSe0.9Mg0.4 sample is best among these three Mg doped samples. As for FeSe0.9Mg0.2 sample, Mg addition is not enough and the interface between MgSe and FeSe in the layered grains is insufficient to affect the overall Tc of sintered sample. When it comes to the FeSe0.9Mg, excess MgSe is formed and the superconducting β-FeSe is decreased too much, which also decrease the interfaces between MgSe and FeSe and thus affects Tc performance.

Conclusions

Mg doped FeSe polycrystalline bulks were obtained by two-step solid-state reaction method, which exhibits increased Tc compared to undoped FeSe sample. it was found that Mg addition has little effect on the crystal lattice parameters of superconducting β-FeSe, whereas leads to the formation of nano-layered grain structure consisted of MgSe and β-FeSe. Lots of nano-structural interfaces between FeSe and MgSe formed in this homogenous layered grain structure have significant effect on the superconducting properties and are responsible for the enhancement of Tc. Although Tc in the Mg doped FeSe bulks in present work needs to be further enhanced via optimizing both the amount of dopants and the synthesis technique to form better layered structure, our work not only demonstrates a powerful way for raising Tc in bulk superconductors, but also provides a well-defined platform for systematic studies of the mechanism of unconventional superconductivity through considering interface effect. Besides, FeSe thin film on MgSe substrate is also worth being studied in terms of interfacial superconductivity.