Your search keyword '"Li, Yiyi"' showing total 19 results

1. Structure-driven intercalated architecture of septuple-atomic-layer $MA_2Z_4$ family with diverse properties from semiconductor to topological insulator to Ising superconductor

Author

Wang, Lei, Shi, Yongpeng, Liu, Mingfeng, Hong, Yi-Lun, Chen, Ming-Xing, Li, Ronghan, Gao, Qiang, Ren, Wencai, Cheng, Hui-Ming, Li, Yiyi, and Chen, Xing-Qiu

Subjects

Condensed Matter - Materials Science

Abstract

Motivated by the fact that septuple-atomic-layer MnBi$_2$Te$_4$ can be structurally viewed as the combination of double-atomic-layer MnTe intercalating into quintuple-atomic-layer Bi$_2$Te$_3$, we present a general approach of constructing twelve septuple-atomic-layer $\alpha_i$- and $\beta_i$-$MA_2Z_4$ monolayer family (\emph{i} = 1 to 6) by intercalating MoS$_2$-type $MZ$$_2$ monolayer into InSe-type A$_2$Z$_2$ monolayer. Besides reproducing the experimentally synthesized $\alpha_1$-MoSi$_2$N$_4$, $\alpha_1$-WSi$_2$N$_4$ and $\beta_5$-MnBi$_2$Te$_4$ monolayer materials, another 66 thermodynamically and dynamically stable $MA_2Z_4$ were predicted, which span a wide range of properties upon the number of valence electrons (VEC). $MA_2Z_4$ with the rules of 32 or 34 VEC are mostly semiconductors with direct or indirect band gap and, however, with 33 VEC are generally metal, half-metal ferromagnetism, or spin-gapless semiconductor upon whether or not an unpaired electron is spin polarized. Moreover, we propose $\alpha_2$-WSi$_2$P$_4$ for the spin-valley polarization, $\alpha_1$-TaSi$_2$N$_4$ for Ising superconductor and $\beta_2$-SrGa$_2$Se$_4$ for topological insulator., Comment: Maintext 9 pages; 5 figures; Supplementary Materials 8 figures and 4 tables

Published

2020

2. Underlying topological Dirac nodal line mechanism of anomalously large electron-phonon coupling strength on Be (0001) surface

Author

Li, Ronghan, Li, Jiangxu, Wang, Lei, Ma, Hui, Li, Dianzhong, Li, Yiyi, and Chen, Xing-Qiu

Subjects

Condensed Matter - Materials Science

Abstract

Beryllium was recently discovered to harbor a Dirac nodal line (DNL) in its bulk phase and the DNL-induced non-trivial drumhead-like surface states (DNSSs) on its (0001) surface, rationalizing several already-existing historic puzzles [Phys. Rev. Lett., \textbf{117}, 096401 (2016)]. However, to date the underlying mechanism, as to why its (0001) surface exhibits an anomalously large electron-phonon coupling effect ($\lambda_{e-ph}^s$ $\approx$ 1.0), remains unresolved. Here, by means of first-principles calculations we have evidenced that the coupling of the DNSSs with the phononic states mainly contributes to its novel surface \emph{e-ph} enhancement. Besides that the experimentally observed $\lambda_{e-ph}^s$ and the main Eliashberg coupling function (ECF) peaks have been reproduced well, we have decomposed the ECF, $\alpha^{2}$$F$(\emph{k},\textbf{\emph{q}};\emph{v}), and the \emph{e-ph} coupling strength $\lambda(\emph{k},\textbf{\emph{q}};\emph{v})$ as a function of each electron momentum (\emph{k}), each phonon momentum (\textbf{\emph{q}}) and each phonon mode ($v$), evidencing the robust connection between the DNSSs and both $\alpha^{2}$$F$(\emph{k},\textbf{\emph{q}};\emph{v}) and $\lambda(\emph{k},\textbf{\emph{q}};\emph{v})$. The results reveal the strong \emph{e-ph} coupling between the DNSSs and the phonon modes, which contributes over 80$\%$ of the $\lambda_{e-ph}^s$ coefficient on the Be (0001) surface. It highlights that the anomalously large \emph{e-ph} coefficient on the Be (0001) surface can be attributed to the presence of its DNL-induced DNSSs, clarifying the long-term debated mechanism., Comment: 6 pages, 3 figures

Published

2019

3. Phononic Weyl Nodal Straight Lines in High-Temperature Superconductor MgB$_2$

Author

Xie, Qing, Li, Jiangxu, Liu, Min, Wang, Lei, Li, Dianzhong, Li, Yiyi, and Chen, Xing-Qiu

Subjects

Condensed Matter - Materials Science

Abstract

Based on first-principles calculations, we predict that the superconducting MgB$_2$ with a AlB$_2$-type centrosymmetric lattice host the so-called phononic topological Weyl nodal lines (PTWNLs) on its bulk phonon spectrum. These PTWNLs can be viewed as countless Weyl points (WPs) closely aligned along the straight lines in the $-$H-K-H direction within the three-dimensional Brillouin zone (BZ). Their topological non-trivial natures are confirmed by the calculated Berry curvature distributions on the planes perpendicular to these lines. These lines are highly unique, because they exactly locate at the high-symmetry boundary of the BZ protected by the mirror symmetry and, simultaneously, straightly transverse the whole BZ, in different from known classifications including nodal rings, nodal chains or nets, and nodal loops. On the (10$\bar{1}$0) crystal surface, the PTWNLs-induced drumhead-like non-trivial surface states appear within the rectangular area confined by the projected lines of the PTWNLs with opposite chirality. Moreover, when the mirror symmetry is broken, the double-degenerate PTWNLs are further lifted to form a pair WPs with opposite chirality. Our results pave the ways for future experimental study on topological phonons on MgB$_2$ and highlights similar results in a series of isostructural AlB$_2$-type metallic diborides., Comment: 4 figures

Published

2018

4. Three-component bosons in TiS, ZrSe and HfTe

Author

Ullah, Sami, Li, Jiangxu, Li, Ronghan, Xie, Qing, Ma, Hui, Li, Dianzhong, Li, Yiyi, and Chen, Xing-Qiu

Subjects

Condensed Matter - Materials Science

Abstract

Topological semimetals with several types of three-dimensional (3D) fermion of electrons, such as Dirac fermions, Weyl fermions, Dirac nodal lines and triply degenerate nodal points have been theoretically predicted and then experimentally discovered in the electronic structures of a series of solid crystals. In analogy of various typical fermions, topological mechanical states with two type of bosons, Dirac and Weyl bosons, were also experimentally reported in some macroscopic systems of kHz frequency and with a type of doubly-Weyl phonons in atomic vibrational framework of THz frequency of solid crystal was also recently predicted. However, to date no triply degenerate nodal point of phonon beyond the conventional Dirac, Weyl and doubly-Weyl phonons has been reported. Here, through first-principles calculations, we have reported on the prediction that the WC-type TiS, ZrSe, and HfTe commonly host the unique triply degenerate nodal point of phonon in THz frequency due to the occurrence of the phonon band inversion between the doubly degenerate planar vibrational mode and the singlet vertical vibrational mode at the boundary A point of the bulk Brillouin zone. Quasiparticle excitations near this triply degenerate nodal point of phonons are three-component bosons, different from the known classifications. The underlying mechanism can be attributed to the leading role of the comparable atomic masses of constituent elements in compounds in competition with the interatomic interaction. Additionally, the electronic structures in their bulk crystals exhibit the coexisted triply degenerate nodal point and Weyl fermions. The novel coexistence of three-component bosons, three-component fermions and Weyl fermions in these materials thus suggest an enriched platform for studying the interplay between different types of fermions and bosons., Comment: 9 figures, 1 table, 10 pages

Published

2017

5. Topological nodal line states and a potential catalyst of hydrogen evolution in the TiSi family

Author

Li, Jiangxu, Ma, Hui, Feng, Shaobo, Ullah, Sami, Li, Ronghan, Dong, Junhua, Li, Dianzhong, Li, Yiyi, and Chen, Xing-Qiu

Subjects

Condensed Matter - Materials Science

Abstract

Topological nodal line (DNL) semimetals, formed by a closed loop of the inverted bands in the bulk, result in the nearly flat drumhead-like surface states with a high electronic density near the Fermi level. The high catalytic active sites associated with the high electronic densities, the good carrier mobility, and the proper thermodynamic stabilities with $\Delta G_{H^*}$$\approx$0 are currently the prerequisites to seek the alternative candidates to precious platinum for catalyzing electrochemical hydrogen (HER) production from water. Within this context, it is natural to consider whether or not the DNLs are a good candidate for the HER because its non-trivial surface states provide a robust platform to activate possibly chemical reactions. Here, through first-principles calculations we reported on a new DNL TiSi-type family with a closed Dirac nodal line consisting of the linear band crossings in the $k_y$ = 0 plane. The hydrogen adsorption on the (010) and (110) surfaces yields the $\Delta G_{H^*}$ to be almost zero. The topological charge carries have been revealed to participate in this HER. The results are highlighting that TiSi not only is a promising catalyst for the HER but also paves a new routine to design topological quantum catalyst utilizing the topological DNL-induced surface bands as active sites, rather than edge sites-, vacancy-, dopant-, strain-, or heterostructure-created active sites., Comment: 8 pages, 5 figures

Published

2017

6. Dirac node lines in pure alkali earth metals

Author

Li, Ronghan, Cheng, Xiyue, Ma, Hui, Wang, Shoulong, Li, Dianzhong, Zhang, Zhenyu, Li, Yiyi, and Chen, Xing-Qiu

Subjects

Condensed Matter - Materials Science

Abstract

Beryllium is a simple alkali earth metal, but has been the target of intensive studies for decades because of its unusual electron behaviors at surfaces. Puzzling aspects include (i) severe deviations from the description of the nearly free electron picture, (ii) anomalously large electron-phonon coupling effect, and (iii) giant Friedal oscillations. The underlying origins for such anomalous surface electron behaviors have been under active debate, but with no consensus. Here, by means of first-principle calculations, we discover that this pure metal system, surprisingly, harbors the Dirac node line (DNL) that in turn helps to rationalize many of the existing puzzles. The DNL is featured by a closed line consisting of linear band crossings and its induced topological surface band agrees well with previous photoemission spectroscopy observation on Be (0001) surface. We further reveal that each of the elemental alakali earth metals of Mg, Ca, and Sr also harbors the DNL, and speculate that the fascinating topological property of DNL might naturally exist in other elemental metals as well., Comment: 5 pages, 4 figures

Published

2016

7. Combined Fast Reversible Liquid-like Elastic Deformation with Topological Phase Transition in Na$_3$Bi

Author

Cheng, Xiyue, Li, Ronghan, Li, Dianzhong, Li, Yiyi, and Chen, Xing-Qiu

Subjects

Condensed Matter - Materials Science

Abstract

By means of first-principles calculations, we identified the structural phase transition of Na$_3$Bi from hexagonal ground state to cubic $cF$16 phase above 0.8 GPa, in agreement with the experimental findings. Upon the releasing of pressure, \emph{cF}16 phase of Na$_3$Bi is mechanically stable at ambient condition. The calculations revealed that the $cF$16 phase is topological semimetal, in similarity to well-known HgTe and it even exhibits an unusually low $C^\prime$ modulus (only about 1.9 GPa) and a huge anisotropy, $A^u$ of as high as 11, the third highest value among all known cubic crystals in their elastic behaviors. These facts render \emph{cF}16-type Na$_3$Bi very soft with a liquid-like elastic deformation in the (110)$<$1$\overline{1}$0$>$ slip system. Importantly, as accompanied with this deformation, Na$_3$Bi shows a topological phase transition from a topological semimetal state at its strain-free cubic phase to a topological insulating state at its distorted phase. Because the $C^\prime$ elastic deformation almost costs no energy in a reversible and liquid-like soft manner, \emph{cF}16-type Na$_3$Bi would potentially provide a fast on/off switching way between topological insulator and topological semimetal, which would be beneficial to the quantum electronic devices for practical applications., Comment: 5 pages, 4 figures

Published

2015

8. Topological Metal of NaBi with Ultralow Lattice Thermal Conductivity and Electron-phonon Superconductivity

Author

Chen, Xing-Qiu, Li, Ronghan, Sun, Yan, Cheng, Xiyue, Li, Dianzhong, and Li, Yiyi

Subjects

Condensed Matter - Materials Science

Abstract

By means of first-principles and \emph{ab initio} tight-binding calculations, we found that the compound of NaBi is a three-dimensional non-trivial topological metal. Its topological feature can be confirmed by the presence of band inversion, the derived effective Z$_2$ invariant and the non-trivial surface states with the presence of Dirac cones. Interestingly, our calculations further demonstrated that NaBi exhibits the uniquely combined properties between the electron-phonon coupling superconductivity in nice agreement with recent experimental measurements and the obviously anisotropic but extremely low thermal conductivity. The spin-orbit coupling effects greatly affect those properties. NaBi may provide a rich platform to study the relationship among metal, topology, superconductivity and thermal conductivity., Comment: 5 pages, 4 figures

Published

2014

9. Effects of dilute substitutional solutes on carbon in $\alpha$-Fe: interactions and associated carbon diffusion from first-principles calculations

Author

Liu, Peitao, Xing, Weiwei, Cheng, Xiyue, Li, Dianzhong, Li, Yiyi, and Chen, Xing-Qiu

Subjects

Condensed Matter - Materials Science

Abstract

By means of first-principles calculations coupled with the kinetic Monte Carlo simulations, we have systematically investigated the effects of dilute substitutional solutes on the behaviors of carbon in $\alpha$-Fe. Our results uncover that: ($i$) Without the Fe vacancy the interactions between most solutes and carbon are repulsive due to the strain relief, whereas Mn has a weak attractive interaction with its nearest-neighbor carbon due to the local ferromagnetic coupling effect. ($ii$) The presence of the Fe vacancy results in attractive interactions of all the solutes with carbon. In particular, the Mn-vacancy pair shows an exceptionally large binding energy of -0.81 eV with carbon. ($iii$) The alloying addition significantly impacts the atomic-scale concentration distributions and chemical potential of carbon in the Fe matrix. Among them, Mn and Cr increase the carbon chemical potential whereas Al and Si reduce it. ($iv$) Within the dilute scale of the alloying solution, the solute concentration and temperature dependent carbon diffusivities demonstrate that Mn has a little impact on the carbon diffusion whereas Cr (Al or Si) remarkably retards the carbon diffusion. Our results provide certain implication for better understanding the experimental observations related with the carbon solubility limit, carbon micro-segregation and carbide precipitations in the ferritic steels., Comment: 13 pages, 14 figure, Phys. Rev. B, accepted

Published

2014

10. The three-dimensional topological Dirac semimetal Na$_3$Bi: the ground state phase

Author

Cheng, Xiyue, Li, Ronghan, Chen, Xing-Qiu, Li, Dianzhong, and Li, Yiyi

Subjects

Condensed Matter - Materials Science

Abstract

By means of first-principles calculations, we found that the early characterized three-dimensional topological bulk Dirac semimetal of the $P$6$_3$/$mmc$ Na$_3$Bi is dynamically unstable at the ground state due to the presence of the large imaginary phonon frequencies around the $K$ point. Alternatively, our calculations suggest a new ground state phase which crystalizes in the $P$$\overline3$$c$1 structure with a buckled graphite-like Na/Bi sheets, which is both energetically and dynamically more stable. Moreover, the calculations also uncovered that the $P$$\overline3$$c$1 phase at the ground state is also a topological 3D Dirac semimetal, being exactly the same as the electronic states of the metastable $P$6$_3$/$mmc$ phase., Comment: 5 pages, 4 figures

Published

2014

11. A Unified Mechanism for Hydrogen Trapping at Metal Vacancies

Author

Xing, Weiwei, Chen, Xing-Qiu, Lu, Gang, Li, Dianzhong, and Li, Yiyi

Subjects

Condensed Matter - Materials Science

Abstract

Interaction between hydrogen (H) and metals is central to many materials problems of scientific and technological importance. Chief among them is the development of H storage and H-resistant materials. H segregation or trapping at lattice defects, including vacancies, dislocations, grain boundaries, etc, plays a crucial role in determining the properties of these materials. Here, through first-principles simulations, we propose a unified mechanism involving charge transfer induced strain destabilization to understand H segregation behavior at vacancies. We discover that H prefers to occupy interstitials with high pre-existing charge densities and the availability of such interstitials sets the limit on H trapping capacity at a vacancy. Once the maximum H capacity is reached, the dominant charge donors switch from the nearest-neighbor (NN) to the next-nearest-neighbor (NNN) metal atoms. Accompanying with this long-range charge transfer, a significant reorganization energy would occur, leading to instability of the H-vacancy complex. The physical picture unveiled here appears universal across the BCC series and is believed to be relevant to other metals/defects as well. The insight gained from this study is expected to have important implications for the design of H storage and H-resistant materials., Comment: 5 pages, 3 figures

Published

2013

12. Interstitial-Boron Solution Strengthened WB$_{3+x}$

Author

Cheng, Xiyue, Zhang, Wei, Chen, Xing-Qiu, Niu, Haiyang, Liu, Peitao, Du, Kui, Liu, Gang, Li, Dianzhong, Cheng, Hui-Ming, Ye, Hengqiang, and Li, Yiyi

Subjects

Condensed Matter - Materials Science, Condensed Matter - Mesoscale and Nanoscale Physics

Abstract

By means of variable-composition evolutionary algorithm coupled with density functional theory and in combination with aberration-corrected high-resolution transmission electron microscopy experiments, we have studied and characterized the composition, structure and hardness properties of WB$_{3+x}$ ($x$ $<$ 0.5). We provide robust evidence for the occurrence of stoichiometric WB$_3$ and non-stoichiometric WB$_{3+x}$ both crystallizing in the metastable $hP$16 ($P6_3/mmc$) structure. No signs for the formation of the highly debated WB$_4$ (both $hP$20 and $hP$10) phases were found. Our results rationalize the seemingly contradictory high-pressure experimental findings and suggest that the interstitial boron atom is located in the tungsten layer and vertically interconnect with four boron atoms, thus forming a typical three-center boron net with the upper and lower boron layers in a three-dimensional covalent network, which thereby strengthen the hardness., Comment: 5 pages, 5 figures

Published

2013

13. Rock-salt SnS and SnSe: Native Topological Crystalline Insulators

Author

Sun, Yan, Zhong, Zhicheng, Shirakawa, Tomonori, Franchini, Cesare, Li, Dianzhong, Li, Yiyi, Yunoki, Seiji, and Chen, Xing-Qiu

Subjects

Condensed Matter - Materials Science

Abstract

Unlike time-reversal topological insulators, surface metallic states with Dirac cone dispersion in the recently discovered topological crystalline insulators (TCIs) are protected by crystal symmetry. To date, TCI behaviors have been observed in SnTe and the related alloys Pb$_{1-x}$Sn$_{x}$Se/Te, which incorporate heavy elements with large spin-orbit coupling (SOC). Here, by combining first-principles and {\it ab initio} tight-binding calculations, we report the formation of a TCI in the relatively lighter rock-salt SnS and SnSe. This TCI is characterized by an even number of Dirac cones at the high-symmetry (001), (110) and (111) surfaces, which are protected by the reflection symmetry with respect to the ($\bar{1}$10) mirror plane. We find that both SnS and SnSe have an intrinsically inverted band structure and the SOC is necessary only to open the bulk band gap. The bulk band gap evolution upon volume expansion reveals a topological transition from an ambient pressure TCI to a topologically trivial insulator. Our results indicate that the SOC alone is not sufficient to drive the topological transition., Comment: 5 pages, 5 figures

Published

2013

14. How Channel Segregates Originates: The Flow of Accumulated Impurity Clusters in Solidifying Steels

Author

Li, Dianzhong, Chen, Xing-Qiu, Fu, Paixian, Ma, Xiaoping, Liu, Hongwei, Chen, Yun, Luan, Yikun, and Li, Yiyi

Subjects

Condensed Matter - Materials Science

Abstract

The phenomenon, channel segregates (CS) as a result of gravity-driven flow due to density contrast occurred in the solid-liquid mushy zones1during solidification, often causes the severe destruction of homogeneity and even some fatal damages. Investigation on its mechanism sheds light on the understanding and controlling of the formation of solidifying metals,earth's core, igneous rock and sea ice. Until now, it still remains controversial what composes the density contrasts and, to what extent, how it affects channel segregates. Here, we show that in experimental 500kg and 100 ton commercial cast steel ingots CS originates from oxide Al2O3/MnS impurity clusters (OICs) initially nucleated from the oxide (Al2O3) particles, which induce an extra flow due to sharp density contrast between clusters and melt. The results uncover that, as OICs enrich and grow, their driven flow becomes stronger than the traditionally recognized inter-dendritic thermo-solutal convection, dominating the subsequent opening of the channels. This study extends the classical macrosegregation theory, highlights a significant technological breakthrough to control CS, and could quickly yield practical benefits to the worldwide manufacture of over 50 million tons of ingots, super-thick slab and heavy castings annually, as well as has general implications for the elaboration of other related natural phenomena., Comment: 18 pages, 5 figures

Published

2013

15. Structure, bonding, and hardness of CrB$_4$: a superhard material?

Author

Niu, Haiyang, Wang, Jiaqi, Chen, Xing-Qiu, Li, Dianzhong, Li, Yiyi, Lazar, Petr, Podloucky, Raimund, and Kolmogorov, Aleksey N.

Subjects

Condensed Matter - Materials Science

Abstract

By electron and X-ray diffraction we establish that the CrB$_4$ compound discovered over 40 years ago crystallizes in the $oP10$ (\emph{Pnnm}) structure, in disagreement with previous experiments but in agreement with a recent first-principles prediction. The 3D boron network in the new structure is a distorted version of the rigid carbon $sp^3$ network proposed recently for the high-pressure C$_4$ allotrope. According to our density functional theory calculations and the analysis of the bonding, CrB$_4$ is a potentially superhard material. In fact, the calculated weakest shear and tensile stresses exceed 50 GPa and its Vickers hardness is estimated to be 48 GPa., Comment: 5 pages, 4 figures

Published

2012

16. Families of superhard crystalline carbon allotropes induced via cold-compressed graphite and nanotubes

Author

Niu, Haiyang, Chen, Xing-Qiu, Wang, Shibing, Li, Dianzhong, Mao, Wendy L., and Li, Yiyi

Subjects

Condensed Matter - Materials Science

Abstract

We report a general scheme to systematically construct two classes of structural families of superhard sp3 carbon allotropes of cold compressed graphite through the topological analysis of odd 5+7 or even 4+8 membered carbon rings stemmed from the stacking of zigzag and armchair chains. Our results show that the previously proposed M, bct-C4, W and Z allotropes belong to our currently proposed families and that depending on the topological arrangement of the native carbon rings numerous other members are found that can help us understand the structural phase transformation of cold-compressed graphite and carbon nanotubes (CNTs). In particular, we predict the existence of two simple allotropes, R- and P-carbon, which match well the experimental X-ray diffraction patterns of cold-compressed graphite and CNTs, respectively, display a transparent wide-gap insulator ground state and possess a large Vickers hardness comparable to diamond., Comment: 5 pages, 4 figures, accepted by Phys. Rev. Lett

Published

2012

17. Hardness of T-carbon: Density functional theory calculations

Author

Chen, Xing-Qiu, Niu, Haiyang, Franchini, Cesare, Li, Dianzhong, and Li, Yiyi

Subjects

Condensed Matter - Materials Science

Abstract

We revisit and interpret the mechanical properties of the recently proposed allotrope of carbon, T-carbon [Sheng \emph{et al.}, Phys. Rev. Lett., \textbf{106}, 155703 (2011)], using density functional theory in combination with different empirical hardness models. In contrast with the early estimation based on the Gao's model, which attributes to T-carbon an high Vickers hardness of 61 GPa comparable to that of superhard cubic boron nitride (\emph{c}-BN), we find that T-carbon is not a superhard material, since its Vickers hardenss does not exceed 10 GPa. Besides providing clear evidence for the absence of superhardenss in T-carbon, we discuss the physical reasons behind the failure of Gao's and \v{S}im$\rm\mathring{u}$nek and Vack\'a\v{r}'s (SV) models in predicting the hardness of T-carbon, residing on their improper treatment of the highly anisotropic distribution of quasi-\emph{sp}$^3$-like C-C hybrids. A possible remedy to the Gao and SV models based on the concept of superatom is suggest, which indeed yields a Vickers hardness of about 8 GPa., Comment: 5 pages and 3 figures, accepted by Phys. Rev. B as a Rapid Communication

Published

2011

18. Strain driven onset of non-trivial topological insulating states in Zintl Sr$_2X$ compounds ($X$=Pb, Sn)

Author

Sun, Yan, Chen, Xing-Qiu, Li, Dianzhong, Franchini, Cesare, Yunoki, Seiji, Li, Yiyi, and Fang, Zhong

Subjects

Condensed Matter - Materials Science

Abstract

We explore the topological behavior of the binary Zintl phase of the alkaline earth metals based compounds Sr$_2$Pb and Sr$_2$Sn using both standard and hybrid density functional theory. It is found that Sr$_2$Pb lies on the verge of a topological instability which can be suitably tuned through the application of a small uniaxial expansion strain ($>$ 3%). The resulting non-trivial topologically insulating state display well-defined metallic states in the Sr$_{2}$Pb(010) surface, whose evolution is studied as a function of the film thickness., Comment: 5 pages, 4 figures

Published

2011

19. Intrinsic Correlation between Hardness and Elasticity in Polycrystalline Materials and Bulk Metallic Glasses

Author

Chen, Xing-Qiu, Niu, Haiyang, Li, Dianzhong, and Li, Yiyi

Subjects

Condensed Matter - Materials Science

Abstract

Though extensively studied, hardness, defined as the resistance of a material to deformation, still remains a challenging issue for a formal theoretical description due to its inherent mechanical complexity. The widely applied Teter's empirical correlation between hardness and shear modulus has been considered to be not always valid for a large variety of materials. Here, inspired by the classical work on Pugh's modulus ratio, we develop a theoretical model which establishes a robust correlation between hardness and elasticity for a wide class of materials, including bulk metallic glasses, with results in very good agreement with experiment. The simplified form of our model also provides an unambiguous theoretical evidence for Teter's empirical correlation., Comment: 10 pages, 4 figures and 3 tables

Published

2011