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1. I-centered vs F-centered orthorhombic symmetry and negative thermal expansion of the charge density wave of EuAl2Ga2

Author

Agarwal, Harshit, Kotla, Surya Rohith, Noohinejad, Leila, Bag, Biplab, Eisele, Claudio, Ramakrishnan, Sitaram, Tolkiehn, Martin, Paulmann, Carsten, Thamizhavel, Arumugam, Ramakrishnan, Srinivasan, and van Smaalen, Sander

Subjects
Condensed Matter - Strongly Correlated Electrons, Condensed Matter - Materials Science
Abstract

Together with EuGa4 and EuAl4, EuAl2Ga2 belongs to the BaAl4 structure type with space group symmetry I4/mmm. EuAl2Ga2 develops an incommensurate charge density wave (CDW) at temperatures below TCDW = 51 K. On the basis of temperature dependent single-crystal X-ray diffraction (SXRD) data, the incommensurately modulated CDW crystal structure of EuAl2Ga2 is determined to possess orthorhombic superspace symmetry Immm(00g)s00. This symmetry is different from the orthorhombic Fmmm based symmetry of the CDW state of EuAl4. Nevertheless, both symmetries Immm(00g)s00 and Fmmm(00g)s00 lead to the same conclusion, that the CDW is supported by the layers of Al1 type atoms, while the Eu and Al2 or Ga atoms are not directly involved in CDW formation. The different symmetries of the CDW states of EuAl4 and EuAl2Ga2, as well as the observation of negative thermal expansion in the CDW state of EuAl2Ga2 might be explained by the effects of Ga substitution in the latter compound., Comment: 24 pages, 6 figures

Published
2024

2. Charge density wave without long-range structural modulation in canted antiferromagnetic kagome FeGe

Author

Shi, Chenfei, Deng, Hanbin, Kotla, Surya Rohith, Liu, Yi, Ramakrishnan, Sitaram, Eisele, Claudio, Agarwal, Harshit, Noohinejad, Leila, Liu, Ji-Yong, Yang, Tianyu, Liu, Guowei, Maity, Bishal Baran, Wang, Qi, Lin, Zhaodi, Kang, Baojuan, Yang, Wanting, Li, Yongchang, Yang, Zhihua, Li, Yuke, Qi, Yanpeng, Thamizhavel, Arumugam, Ren, Wei, Cao, Guang-Han, Yin, Jia-Xin, van Smaalen, Sander, Cao, Shixun, and Bao, Jin-Ke

Subjects
Condensed Matter - Strongly Correlated Electrons, Condensed Matter - Materials Science
Abstract

Strongly correlated electron systems with a kagome lattice can host abundant exotic quantum states such as superconductivity and spin/charge density waves (CDW) due to the complicated interactions between different degrees of freedoms in the framework of a unique two-dimensional geometrically frustrated lattice structure. Recently, successive orders of A-type antiferromagnetism (AFM), $2\times2\times2$ CDW and canted double-cone AFM have been manifested upon cooling in magnetic kagome FeGe. However, the mechanism of the CDW order and its interaction with magnetism are presently enigmatic at best. Here we investigate the evolution of CDW order with temperature across the spin canting transition in FeGe by single-crystal x-ray diffraction. Refinements of its modulated structure are presented using the superspace approach. Interestingly, the superlattice reflections originating from CDW-induced long-range structural modulation become extremely weak after the system enters the canted AFM while a $2\times2$ CDW in the $ab$ plane persists as a long-range order demonstrated by strong electronic modulation in the d$I$/d$V$ map of scanning tunneling spectroscopy. We discovered a novel CDW order without long-range structural modulation in FeGe probably because of the competition between CDW and canted AFM in determining the underlying crystal structure. In addition, occupational modulations of Ge1 atoms located in the kagome plane and displacive modulations of all the atoms were extracted from the refinements, confirming the existence of Ge atom dimerization along the $c$ axis as the major distortion and indicating a dynamic transformation between different CDW domains., Comment: 22 pages, 6 figures. Comments on the manuscript are welcome

Published
2024

3. Room temperature charge density wave in a tetragonal polymorph of Gd2Os3Si5 and study of its origin in the RE2T3X5 (RE = Rare earth, T = transition metal, X = Si, Ge) series

Author

Sharma, Vikash, Ramakrishnan, Sitaram, Jayakrishnan, S. S., Kotla, Surya Rohith, Maiti, Bishal, Eisele, Claudio, Agarwal, Harshit, Noohinejad, Leila, Tolkiehn, M., Bansal, Dipanshu, van Smaalen, Sander, and Thamizhavel, Arumugam

Subjects
Condensed Matter - Strongly Correlated Electrons, Condensed Matter - Materials Science
Abstract

Charge density wave (CDW) systems are proposed to exhibit application potential for electronic and optoelectronic devices. Therefore, identifying new materials that exhibit a CDW state at room temperature is crucial for the development of CDW-based devices. Here, we present a non-layered tetragonal polymorph of Gd2Os3Si5, which exhibits a CDW state at room temperature. Gd2Os3Si5 crystallizes in the U2Mn3Si5-type tetragonal crystal structure with the space group P4/mnc. Single-crystal x-ray diffraction (SXRD) analysis shows that Gd2Os3Si5 possesses an incommensurately modulated structure with modulation wave vector q = (0.53, 0, 0), while the modulation reduces the symmetry to orthorhombic Cccm({\sigma}00)0s0. This differs in contrast to isostructural Sm2Ru3Ge5, where the modulated phase has been reported to possess the superspace symmetry Pm({\alpha} 0 {\gamma})0. However, reinvestigation of Sm2Ru3Ge5 suggests that its modulated crystal structure can alternatively be described by Cccm({\sigma}00)0s0, with modulations similar to Gd2Os3Si5. The magnetic susceptibility, \c{hi}(T), exhibits a maximum at low temperatures that indicates an antiferromagnetic transition at TN = 5.5 K. The \c{hi}(T) furthermore shows an anomaly at around 345 K, suggesting a CDW transition at TCDW = 345 K, that corroborates the result from high-temperature SXRD measurements. Interestingly, R2T3X5 compounds are known to crystallize either in the tetragonal Sc2Fe3Si5 type structure or in the orthorhombic U2Co3Si5 structure type. Not all of the compounds in the R2T3X5 series undergo CDW phase transitions. We find that R2T3X5 compounds will exhibit a CDW transition, if the condition : 0.526 < c/sqrt(ab) < 0.543 is satisfied. We suggest the wave vector-dependent electron-phonon coupling to be the dominant mechanism of CDW formation in the tetragonal polymorph of Gd2Os3Si5.

Published
2024
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4. Non-centrosymmetric, transverse structural modulation in SrAl4, and elucidation of its origin in the BaAl4 family of compounds

Author

Ramakrishnan, Sitaram, Kotla, Surya Rohith, Pi, Hanqi, Maity, Bishal Baran, Chen, Jia, Bao, Jin-Ke, Guo, Zhaopeng, Kado, Masaki, Agarwal, Harshit, Eisele, Claudio, Nohara, Minoru, Noohinejad, Leila, Weng, Hongming, Ramakrishnan, Srinivasan, Thamizhavel, Arumugam, and van Smaalen, Sander

Subjects
Condensed Matter - Strongly Correlated Electrons, Condensed Matter - Materials Science
Abstract

At ambient conditions SrAl4 adopts the BaAl4 structure type with space group I4/mmm. It undergoes a charge-density-wave (CDW) transition at TCDW = 243 K, followed by a structural transition at TS = 87 K. Temperature-dependent single-crystal X-ray diffraction (SXRD) leads to the observation of incommensurate superlattice reflections at q = \sigma c* with \sigma = 0.1116 at 200 K. The CDW has orthorhombic symmetry with the acentric superspace group F222(00sigma)00s, where F222 is a subgroup of Fmmm as well as of I4/mmm. Atomic displacements mainly represent a transverse wave, with displacements that are 90 deg out of phase between the two diagonal directions of the I-centered unit cell, resulting in a helical wave. Small longitudinal displacements are provided by the second harmonic modulation. The orthorhombic phase realized in SrAl4 is similar to that found in EuAl4. Electronic structure calculations and phonon calculations by density functional theory (DFT) have failed to reveal the mechanism of CDW formation. However, DFT reveals that Al atoms dominate the density of states near the Fermi level, thus, corroborating the SXRD measurements. SrAl4 remains incommensurately modulated at the structural transition, where the symmetry lowers from orthorhombic to b-unique monoclinic. We have identified a simple criterion, that correlates the presence of a phase transition with the interatomic distances. Only those compounds XAl4-xGax(X = Ba, Eu, Sr, Ca; 0 < x <4) undergo phase transitions, for which the ratio c/a falls within the narrow range 2.51 < c/a < 2.54.

Published
2023
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5. Annealing-induced long-range charge density wave order in magnetic kagome FeGe: fluctuations and disordered structure

Author

Shi, Chenfei, Liu, Yi, Maity, Bishal Baran, Wang, Qi, Kotla, Surya Rohith, Ramakrishnan, Sitaram, Eisele, Claudio, Agarwal, Harshit, Noohinejad, Leila, Tao, Qian, Kang, Baojuan, Lou, Zhefeng, Yang, Xiaohui, Qi, Yanpeng, Lin, Xiao, Xu, Zhu-An, Thamizhavel, A., Cao, Guang-Han, van Smaalen, Sander, Cao, Shixun, and Bao, Jin-Ke

Subjects
Condensed Matter - Strongly Correlated Electrons
Abstract

Charge density wave (CDW) in kagome materials with the geometric frustration is able to carry unconventional characteristics. Recently, a CDW has been observed below the antiferromagnetic order in kagome FeGe, in which magnetism and CDW are intertwined to form an emergent quantum ground state. However, the CDW is only short-ranged and the structural modulation originating from it has yet to be determined experimentally. Here we realize a long-range CDW order by post-annealing process, and resolve the structure model through single crystal x-ray diffraction. Occupational disorder of Ge resulting from short-range CDW correlations above $T_\mathrm{CDW}$ is identified from structure refinements. The partial dimerization of Ge along the $c$ axis is unveiled to be the dominant distortion for the CDW. Occupational disorder of Ge is also proved to exist in the CDW phase due to the random selection of partially dimerized Ge sites. Our work provides useful insights for understanding the unconventional nature of the CDW in FeGe., Comment: 4 figures and 1 table in the main text. Supplementary materials included. To be published in SCIENCE CHINA Physics, Mechanics & Astronomy (SCPMA)

Published
2023
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6. Realization of Z$_2$ Topological Metal in Single-Crystalline Nickel Deficient NiV$_2$Se$_4$

Author

Ramakrishnan, Sitaram, Matteppanavar, Shidaling, Schonleber, Andreas, Patra, Bikash, Singh, Birender, Thamizhavel, Arumugam, Singh, Bahadur, Ramakrishnan, Srinivasan, and van Smaalen, Sander

Subjects
Condensed Matter - Strongly Correlated Electrons
Abstract

Temperature-dependent electronic and magnetic properties are reported for a Z2 topological metal single-crystalline nickel-deficient NiV$_2$Se$_4$. It is found to crystallize in the monoclinic Cr3S4 structure type with space group I2=m. From single-crystal x-ray diffraction, we find that there are vacancies on the Ni site, resulting in the composition Ni0:85V2Se4 in agreement with our electron-probe microanalysis. The electrical resistivity shows metallic behavior with a broad anomaly around 150{200 K that is also observed in the heat capacity data. This anomaly indicates a change of state of the material below 150 K. We believe that this anomaly could be due to spin fluctuations or charge-density-wave (CDW) fluctuations, where the lack of long-range order is caused by vacancies at the Ni site of Ni0:85V2Se4. Although we fail to observe any structural distortion in this crystal down to 1.5 K, its electronic and thermal properties are anomalous. The observation of non-linear temperature dependence of resistivity as well as an enhanced value of the Sommerfeld coefficient = 104.0(1) mJ/molK2 suggests strong electron-electron correlations in this material. The first-principles calculations performed for NiV$_2$Se$_4$, which are also applicable to Ni0:85V2Se4, classify this material as a topological metal with Z2 = (1; 110) and coexisting electron and hole pockets at the Fermi level. The phonon spectrum lacks any soft phonon mode, consistent with the absence of periodic lattice distortion in the present experiments., Comment: arXiv admin note: text overlap with arXiv:cond-mat/0610166 by other authors

Published
2023
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7. Coupling between colossal charge density wave ordering and magnetism in Ho2Ir3Si5

Author

Ramakrishnan, Sitaram, Bao, Jin-Ke, Eisele, Claudio, Patra, Bikash, Nohara, Minoru, Bag, Biplab, Noohinejad, Leila, Tolkiehn, Martin, Paulmann, Carsten, Schaller, Achim M., Rekis, Toms, Kotla, Surya Rohith, Schönleber, Andreas, Thamizhavel, Arumugam, Singh, Bahadur, Ramakrishnan, Srinivasan, and van Smaalen, Sander

Subjects
Condensed Matter - Strongly Correlated Electrons, Condensed Matter - Materials Science
Abstract

Ho2Ir3Si5 belongs to the family of three-dimensional (3D) R2Ir3Si5 (R = Lu, Er and Ho) compounds that exhibit a colossal first-order charge density wave (CDW) transition where there is a strong orthorhombic-to-triclinic distortion of the lattice accompanied by superlattice reflections. The analysis by single-crystal X-ray diffraction (SXRD) has revealed that the Ir-Ir zigzag chains along c are responsible for the CDW in all three compounds. The replacement of the rare earth element from non-magnetic Lu to magnetic Er or Ho lowers TCDW, where TCDWLu = 200 K, TCDWEr = 150 K and TCDWHo = 90 K. Out of the three compounds, Ho2Ir3Si5 is the only system where second-order superlattice reflections could be observed, indicative of an anharmonic shape of the modulation wave. The CDW transition is observed as anomalies in the temperature dependencies of the specific heat, electrical conductivity and magnetic susceptibility, which includes a large hysteresis of 90 to 130 K for all measured properties, thus corroborating the SXRD measurements. Similar to previously reported Er2Ir3Si5, there appears to be a coupling between CDW and magnetism such that the Ho3+ magnetic moments are influenced by the CDW transition, even in the paramagnetic state. Moreover, earlier investigations on polycrystalline material revealed antiferromagnetic (AFM) ordering at TN = 5.1 K, whereas AFM order is suppressed and only the CDW is present in our highly ordered single-crystal. First-principles calculations predict Ho2Ir3Si5 to be a metal with coexisting electron and hole pockets at the Fermi level. The Ho and Ir atoms have spherically symmetric metallic-type charge density distributions that are prone to CDW distortion. Phonon calculations affirm that the Ir atoms are primarily responsible for the CDW distortion, which is in agreement with the experiment.

Published
2022
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8. Spin and charge density waves in the quasi-one-dimensional KMn6Bi5

Author

Bao, Jin-Ke, Cao, Huibo, Krogstad, Matthew J., Taddei, Keith M., Shi, Chenfei, Cao, Shixun, Lapidus, Saul H., van Smaalen, Sander, Chung, Duck Young, Kanatzidis, Mercouri G., Rosenkranz, Stephan, and Chmaissem, Omar

Subjects
Condensed Matter - Strongly Correlated Electrons, Condensed Matter - Materials Science, Condensed Matter - Superconductivity
Abstract

AMn6Bi5 materials (A = Na, K, Rb and Cs) consisting of unique Mn-cluster chains emerge as a new family of superconductors with the suppression of their antiferromagnetic (AFM) order under high pressures. Here, we report transverse incommensurate spin density waves (SDWs) for the Mn atoms with a propagating direction along the chain axes as a ground state for KMn6Bi5 by single crystal neutron diffraction. The SDWs have a refined amplitude of ~2.46 Bohr magnetons for the Mn atoms in the pentagons and ~0.29 Bohr magnetons with a large standard deviation for Mn atoms in the center between the pentagons. AFM dominate both the nearest-neighbor Mn-Mn interactions within the pentagon and next-nearest-neighbor Mn-Mn interactions out of the pentagon (along the propagating wave). The SDWs exhibit both local and itinerant characteristics probably formed by a cooperative interaction between local magnetic exchange and conduction electrons. A significant magnetoelastic effect during the AFM transition, especially along the chain direction, has been demonstrated by temperature-dependent x-ray powder diffraction. Single crystal x-ray diffraction below the AFM transition revealed satellite peaks originating from charge density waves along the chain direction with a q-vector twice as large as the SDW one, pointing to a strong real space coupling between them. Our work not only manifests a fascinating interplay among spin, charge, lattice and one dimensionality to trigger intertwined orders in KMn6Bi5 but also provides important piece of information for the magnetic structure of the parent compound to understand the mechanism of superconductivity in this new family.

Published
2022
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10. Orthorhombic charge density wave on the tetragonal lattice of EuAl4

Author

Ramakrishnan, Sitaram, Kotla, Surya Rohith, Rekis, Toms, Bao, Jin-Ke, Eisele, Claudio, Noohinejad, Leila, Tolkiehn, Martin, Paulmann, Carsten, Singh, Birender, Verma, Rahul, Bag, Biplab, Kulkarni, Ruta, Thamizhavel, Arumugam, Singh, Bahadur, Ramakrishnan, Srinivasan, and van Smaalen, Sander

Subjects
Condensed Matter - Strongly Correlated Electrons
Abstract

EuAl4 possesses the BaAl4 crystal structure type with tetragonal symmetry I4/mmm. It undergoes a charge-density-wave (CDW) transition at TCDW = 145 K and it features four consecutive antiferromagnetic phase transitions below 16 K. Here, we use single-crystal x-ray diffraction to determine incommensurately modulated crystal structure of EuAl4 in its CDW state. The CDW is shown to be incommensurate with modulation wave vector q = (0, 0, 0.1781(3)) at 70 K. The symmetry of the incommensurately modulated crystal structure is orthorhombic with superspace group Fmmm(00{\sigma})s00, where Fmmm is a subgroup of I4/mmm of index 2. Both the lattice and the atomic coordinates of the basic structure remain tetragonal. Symmetry breaking is entirely due to the modulation wave, where atoms Eu and Al1 have displacements exclusively along a, while the fourfold rotation would require equal displacement amplitudes along a and b. The calculated band structure of the basic structure and interatomic distances in the modulated crystal structure both indicate the aluminum atoms as location of the CDW. The temperature dependence of the specific heat reveals an anomaly at TCDW = 145 K of a magnitude similar to canonical CDW systems. The present discovery of orthorhombic symmetry for the CDW state of EuAl4 leads to the suggestion of monoclinic instead of orthorhombic symmetry for the third AFM state.

Published
2022
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11. Commensurate stacking phase transitions in an intercalated transition metal dichalcogenide

Author

Yang, Xiaohui, Bao, Jin-Ke, Lou, Zhefeng, Li, Peng, Jiang, Chenxi, Wang, Jialu, Sun, Tulai, Liu, Yabin, Guo, Wei, Ramakrishnan, Sitaram, Kotla, Surya Rohith, Tolkiehn, Martin, Paulmann, Carsten, Cao, Guang-Han, Nie, Yuefeng, Li, Wenbin, Liu, Yang, van Smaalen, Sander, Lin, Xiao, and Xu, Zhu-An

Subjects
Condensed Matter - Materials Science, Condensed Matter - Superconductivity
Abstract

Intercalation and stacking order modulation are two active ways in manipulating the interlayer interaction of transition metal dichalcogenides (TMDCs), which lead to a variety of emergent phases and allow for engineering material properties. Herein, the growth of Pb intercalated TMDCs--Pb(Ta$_{1+x}$Se$_2$)$_2$, the first 124-phase, is reported. Pb(Ta$_{1+x}$Se$_2$)$_2$ exhibits a unique two-step first-order structural phase transition at around 230 K. The transitions are solely associated with the stacking degree of freedom, evolving from a high temperature phase with ABC stacking and symmetry $R3m$ to an intermediate phase with AB stacking and $P3m1$, and finally to a low temperature phase with again symmetry $R3m$, but with ACB stacking. Each step involves a rigid slide of building blocks by a vector [1/3, 2/3, 0]. Intriguingly, gigantic lattice contractions occur at the transitions on warming. At low temperature, bulk superconductivity with $T_\textrm{c}\approx$ 1.8 K is observed. The underlying physics of the structural phase transitions are discussed from first-principle calculations. The symmetry analysis reveals topological nodal lines in the band structure. Our results demonstrate the possibility to realize higher order metal intercalated phases of TMDCs, advance our knowledge of polymorphic transitions and may inspire stacking order engineering in TMDCs and beyond.

Published
2021
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13. Mixed system $Cs_3Cu_3Cl_{8-x}Br_xOH$ with weakly connected Cu-triangles

Author

van Well, Natalija, Bolte, Michael, Eisele, Claudio, Keller, Lukas, Schefer, Jürg, and van Smaalen, Sander

Subjects
Condensed Matter - Materials Science, Condensed Matter - Strongly Correlated Electrons
Abstract

To study the relationship between the properties of low-dimensional spin systems with weakly coupled Cu-triangles and their crystal structure, single crystals of $Cs_3Cu_3Cl_8OH$ (1) and the new $Cs_3Cu_3Cl_{7.6}Br_{0.4}OH$ (2) were grown. Both compounds are isostructural and crystallize in a monoclinic structure with space group $P2_1/c$. The magnetic susceptibility of (1) shows a maximum at $2.23 K$ and of (2) at $2.70 K$, which are attributed to antiferromagnetic phase transitions. Furthermore, the magnetization along the $b$-axis at $1.9 K$ for both compounds shows a spin-flop transition into a new antiferromagnetic phase. This transition occurs at $0.61 T$ for (1) and at $2.0 T$ for (2). The antiferromagnetic order can be suppressed by a magnetic field $B_{C1}= 1.1 T$ for (1) and $B_{C2}= 1.2 T$ for (2). First single crystal neutron diffraction measured on (1) at different temperatures reveals the magnetic signal on the top of the nuclear reflection at (-1 0 0). Its magnetic ordering temperature was found to be at $T_{N1}= 2.12(3) K$., Comment: Accepted Paper

Published
2020
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14. Tetragonal mixed system $Cs_2CuCl_{4-x}Br_x$ complemented by the tetragonal phase realisation of $Cs_2CuCl_4$

Author

van Well, Natalija, Eisele, Claudio, Ramakrishnan, Sitaram, Shang, Tian, Medarde, Marisa, Cervellino, Antonio, Skoulatos, Markos, Georgii, Robert, and van Smaalen, Sander

Subjects
Condensed Matter - Materials Science, Condensed Matter - Strongly Correlated Electrons
Abstract

Realisation of the tetragonal phase of $Cs_2CuCl_4$ is possible using specific crystal growth conditions at a temperature below $281K$. This work deals with the comparison of the magnetic susceptibility and the magnetization of this new tetragonal compound with the magnetic behaviour of tetragonal $Cs_2CuCl_{2.9}Br_{1.1}$, $Cs_2CuCl_{2.5}Br_{1.5}$, $Cs_2CuCl_{2.2}Br_{1.8}$ and presents consistent results for such quasi $2-D$ antiferromagnets. Structural investigation at low temperature for $Cs_2CuCl_{2.2}Br_{1.8}$ shows no phase transition. The structure remains in the tetragonal symmetry $I4/mmm$. Furthermore, several magnetic reflections corresponding to the propagation vector $k = (0, 0, 0)$ are observed for this tetragonal compound through neutron diffraction experiments below the magnetic phase transition at $T_N = 11.3K$ confirming its antiferromagnetic nature., Comment: Preprint

Published
2020
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15. Magnetic phase diagram of the triangular antiferromagnetic $Cs_2CuCl_{4-x}Br_x$ mixed system

Author

van Well, Natalija, Zaharko, Oksana, Delley, Bernard, Skoulatos, Markos, Georgii, Robert, van Smaalen, Sander, and Rüegg, Christian

Subjects
Condensed Matter - Materials Science, Condensed Matter - Strongly Correlated Electrons
Abstract

The novel magnetic phase diagram of the $Cs_2CuCl_{4-x}Br_x$ mixed system is established by means of single crystal neutron diffraction in the lowest temperature region and zero magnetic field. Two long-range ordered magnetic phases exist in this mixed system depending on the Cl/Br concentration. In the rich Cl concentration range, the ordered magnetic state occurs below the ordering temperature $T_N = 0.51(1)K$ for $Cs_2CuCl_3Br_1$ and at $Cs_2CuCl_{2.6}Br_{1.4}$ below $T_N = 0.24(2)K$. Magnetic order with a temperature-independent position $(0, 0.573(1), 0)$ below the ordering temperature $T_N = 0.63(1)K$ appears in the rich Br concentration for $Cs_2CuCl_{0.6}Br_{3.4}$. Between the rich Cl and rich Br concentration ranges (two magnetic phases), there is a range of x without magnetic order down to $50mK$. A suggestion about the magnetic exchange paths in the $bc$-layer for different regimes is presented, which can be controlled depending on the preferred Br-occupation in the [CuX4] tetrahedra. The density functional theory (DFT) calculations of the exchange coupling constants J, J^' for some ordered compositions of the mixed system $Cs_2CuCl_{4-x}Br_x$ indicate that these are not frustrated.

Published
2019
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16. Inverse pressure-induced Mott transition in TiPO$_4$

Author

Jönsson, H. Johan M., Ekholm, Marcus, Bykov, Maxim, Dubrovinsky, Leonid, van Smaalen, Sander, and Abrikosov, Igor A.

Subjects
Condensed Matter - Strongly Correlated Electrons
Abstract

TiPO$_4$ shows interesting structural and magnetic properties as temperature and pressure are varied, such as a spin-Peierls phase transition and the development of incommensurate modulations of the lattice. Recently, high pressure experiments for TiPO$_4$ reported two new structural phases appearing at high pressures, the so-called phases IV and V [M. Bykov et al., Angew. Chem. Int. Ed. 55, 15053]. The latter was shown to include the first example of 5-fold O-coordinated P-atoms in an inorganic phosphate compound. In this work we characterize the electronic structure and other physical properties of these new phases by means of ab-initio calculations, and investigate the structural transition. We find that the appearance of phases IV and V coincides with a collapse of the Mott insulating gap and quenching of magnetism in phase III as pressure is applied. Remarkably, our calculations show that in the high pressure phase V, these features reappear, leading to an antiferromagnetic Mott insulating phase, with robust local moments.

Published
2019
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17. The role of magnetic order in VOCl

Author

Ekholm, Marcus, Schönleber, Andreas, and van Smaalen, Sander

Subjects
Condensed Matter - Materials Science
Abstract

VOCl and other transition metal oxychlorides are candidate materials for next-generation rechargeable batteries. We have investigated the influence of the underlying magnetic order on the crystallographic and electronic structure by means of density functional theory. Our study shows that antiferromagnetic ordering explains the observed low-temperature monoclinic distortion of the lattice, which leads to a decreased distance between antiferromagnetically coupled V-V nearest neighbors. We also show that the existence of a local magnetic moment removes the previously suggested degeneracy of the occupied levels, in agreement with experiments. To describe the electronic structure, it turns out crucial to take the correct magnetic ordering into account, especially at elevated temperature.

Published
2019
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20. Annealing-induced long-range charge density wave order in magnetic kagome FeGe: Fluctuations and disordered structure.

Author

Shi, Chenfei, Liu, Yi, Maity, Bishal Baran, Wang, Qi, Kotla, Surya Rohith, Ramakrishnan, Sitaram, Eisele, Claudio, Agarwal, Harshit, Noohinejad, Leila, Tao, Qian, Kang, Baojuan, Lou, Zhefeng, Yang, Xiaohui, Qi, Yanpeng, Lin, Xiao, Xu, Zhu-An, Thamizhavel, Arumugam, Cao, Guang-Han, van Smaalen, Sander, and Cao, Shixun

Abstract

Charge density wave (CDW) in kagome materials with the geometric frustration is able to carry unconventional characteristics. Recently, a CDW has been observed below the antiferromagnetic order in kagome FeGe, in which magnetism and CDW are intertwined to form an emergent quantum ground state. However, the CDW is only short-ranged and the structural modulation originating from it has yet to be determined experimentally. Here we realize a long-range CDW order by post-annealing process, and resolve the structure model through single crystal X-ray diffraction. Occupational disorder of Ge resulting from short-range CDW correlations above TCDW is identified from structure refinements. The partial dimerization of Ge along the c axis is unveiled to be the dominant distortion for the CDW. Occupational disorder of Ge is also proved to exist in the CDW phase due to the random selection of partially dimerized Ge sites. Our work provides useful insights for understanding the unconventional nature of the CDW in FeGe. [ABSTRACT FROM AUTHOR]

Published
2024
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22. Order–Disorder Structure in Ni3Sb4CO6F6: Synthesis, Characterization, and Its Applications toward Photocatalytic Dye Degradation and Antibacterial Activities

Author

Paul, Sayantani, Das, Sangita, Sepay, Nayim, Basak, Nilendu, Sen, Bibaswan, Islam, Ekramul, Van Smaalen, Sander, and Ali, Sk Imran

Abstract

Design of Ni3Sb4CO6F6, a metal carbon oxyfluoride [M–L–C–O–F] comprising a p-block cation, was carried out by incorporating a carbon atom inside the Sb4tetrahedral void of Ni3Sb4O6F6. Single crystals of Ni3Sb4O6F6and Ni3Sb4CO6F6were grown by employing a hydrothermal synthesis technique. Single-crystal X-ray diffraction (SCXRD) studies show that the crystal structure of Ni3Sb4CO6F6can be explained by both an ordered and a disordered structure model with cubic symmetry (SG: I4̅3m). Disorder generates the four split carbon sites due to symmetrically identical positions at (−x, −x, x) with the occupancy of one quarter of each carbon site of their total occupancy. On the other hand, disorder can be avoided by fixing the carbon site at (0, 0, 0), a special position with 100% occupancy at one site. Conversely, lowering of symmetry to tetragonal symmetry (SG: I4̅) provides comparatively low GOF and Rvalues, which could also be a kind of structural modeling for Ni3Sb4CO6F6considering the large data-to-parameter ratio. Insertion of carbon introduces an indirect band gap energy (Eg), i.e., 1.75 eV, in Ni3Sb4CO6F6compared to the direct band gap energy of its parent compound, Ni3Sb4O6F6(Eg= 3.25 eV), which was also confirmed from the theoretical study. Both Ni3Sb4O6F6and Ni3Sb4CO6F6were explored as efficient photocatalysts toward Methylene Blue dye degradation and excellent antibacterial agents against both Gram-positive and Gram-negative bacteria for the first time. The rate of dye degradation was greater for Ni3Sb4CO6F6, as evident from the kinetic study. The addition of 6% H2O2further increases the rate of dye degradation in both cases. The photocatalysts were recycled up to seven consecutive cycles with 60 and 80% minimum degradation efficiencies for Ni3Sb4O6F6and Ni3Sb4CO6F6, respectively. Radical scavenger test was also performed to investigate the responsible reactive oxygen species (ROS) in this photocatalytic dye degradation reaction. The antibacterial study was carried out with eight distinct bacterial strains, namely, Staphylococcussp., Salmonellasp., Pseudomonassp., Escherichia coli, Klebsiellasp., Bacillussp., Enterobactersp., and Proteussp.The bacterial disinfection properties of each compound were monitored by examining the ability to suppress bacteria in liquid LB medium. The compounds were also characterized through energy-dispersive X-ray (EDS), Fourier transform infrared spectroscopy (FTIR), powder X-ray diffraction (PXRD), field emission scanning electron microscopy (FE-SEM), and zeta potential study.

Published
2024
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24. Symmetry disquisition on the TiOX phase diagram

Author

Fausti, Daniele, Lummen, Tom T. A., Angelescu, Cosmina, Macovez, Roberto, Luzon, Javier, Broer, Ria, Rudolf, Petra, van Loosdrecht, Paul H. M., Tristan, Natalia, Buchner, Bernd, van Smaalen, Sander, Moller, Angela, Meyer, Gerd, and Taetz, Timo

Subjects
Condensed Matter - Strongly Correlated Electrons, Condensed Matter - Materials Science
Abstract

The sequence of phase transitions and the symmetry of in particular the low temperature incommensurate and spin-Peierls phases of the quasi one-dimensional inorganic spin-Peierls system TiOX (TiOBr and TiOCl) have been studied using inelastic light scattering experiments. The anomalous first-order character of the transition to the spin-Peierls phase is found to be a consequence of the different symmetries of the incommensurate and spin-Peierls (P$2_{1}/m$) phases. The pressure dependence of the lowest transition temperature strongly suggests that magnetic interchain interactions play an important role in the formation of the spin-Peierls and the incommensurate phases. Finally, a comparison of Raman data on VOCl to the TiOX spectra shows that the high energy scattering observed previously has a phononic origin.

Published
2007
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25. Incommensurate interactions and non-conventional spin-Peierls transition in TiOBr

Author

van Smaalen, Sander, Palatinus, Lukas, and Schonleber, Andreas

Subjects
Condensed Matter - Other Condensed Matter
Abstract

Temperature-dependent x-ray diffraction of the low-dimensional spin 1/2 quantum magnet TiOBr shows that the phase transition at T_{c2} = 47.1 (4) K corresponds to the development of an incommensurate superstructure. Below T_{c1} = 26.8 \pm 0.3 K the incommensurate modulation locks in into a two-fold superstructure similar to the low-temperature spin-Peierls state of TiOCl. Frustration between intra- and interchain interations within the spin-Peierls scenario, and competition between two-dimensional magnetic order and one-dimensional spin-Peierls order are discussed as possible sources of the incommensurability., Comment: 5 pages including 3 figures and 1 table

Published
2005
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27. Orthorhombic versus monoclinic symmetry of the charge-ordered state of NaV2O5

Author

van Smaalen, Sander, Daniels, Peter, Palatinus, Lukas, and Kremer, Reinhard K.

Subjects
Condensed Matter - Materials Science
Abstract

High-resolution X-ray diffraction data show that the low-temperature superstructure of alpha-NaV2O5 has an F-centered orthorhombic 2a x 2b x 4c superlattice. A structure model is proposed, that is characterized by layers with zigzag charge order on all ladders and stacking disorder, such that the averaged structure has space group Fmm2. This model is in accordance with both X-ray scattering and NMR data. Variations in the stacking order and disorder offer an explanation for the recently observed devils staircase of the superlattice period along c., Comment: REVTEX, 4 pages including 2 figures, shortened, submitted to PRL

Published
2001
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34. Coupling between Charge Density Wave Ordering and Magnetism in Ho2Ir3Si5

Author

Ramakrishnan, Sitaram, primary, Bao, Jinke, additional, Eisele, Claudio, additional, Patra, Bikash, additional, Nohara, Minoru, additional, Bag, Biplab, additional, Noohinejad, Leila, additional, Tolkiehn, Martin, additional, Paulmann, Carsten, additional, Schaller, Achim M., additional, Rekis, Toms, additional, Kotla, Surya Rohith, additional, Schönleber, Andreas, additional, Thamizhavel, Arumugam, additional, Singh, Bahadur, additional, Ramakrishnan, Srinivasan, additional, and van Smaalen, Sander, additional

Published
2023
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37. Spin and charge density waves in quasi-one-dimensional KMn6Bi5

Author

Bao, Jin-Ke, primary, Cao, Huibo, additional, Krogstad, Matthew J., additional, Taddei, Keith M., additional, Shi, Chenfei, additional, Cao, Shixun, additional, Lapidus, Saul H., additional, van Smaalen, Sander, additional, Chung, Duck Young, additional, Kanatzidis, Mercouri G., additional, Rosenkranz, Stephan, additional, and Chmaissem, Omar, additional

Published
2022
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39. Single-crystal-to-single-crystal phase transitions of commensurately modulated sodium saccharinate 1.875-hydrate

Author

Rekis, Toms, Schaller, Achim M., Kotla, Surya Rohith, Schönleber, Andreas, Noohinejad, Leila, Tolkiehn, Martin, Paulmann, Carsten, and Van Smaalen, Sander

Subjects
Crystallography, QD901-999, aperiodic structures, ddc:530, molecular crystals, Research Papers, phase transitions
Abstract

IUCrJ 8(1), 139 - 147 (2021). doi:10.1107/S2052252520015912, This work reports reversible, single-crystal-to-single-crystal phase transitions of commensurately modulated sodium saccharinate 1.875-hydrate [Na(sac)(15/8)H$_2$O]. The phases were studied in the temperature range 298 to 20 K. They exhibit complex disordered states. An unusual reentrant disorder has been discovered upon cooling through a phase transition at 120 K. The disordered region involves three sodium cations, four water molecules and one saccharinate anion. At room temperature, the structure is an eightfold superstructure that can be described by the superspace group C$_2$/c(0σ$_2$0)s0 with q = (0, 3/4, 0). It demonstrates maximum disorder with the disordered chemical entities having slightly different but close to 0.50:0.50 disorder component ratios. Upon cooling, the crystal tends to an ordered state, smoothly reaching a unified disorder component ratio of around 0.90:0.10 for each of the entities. Between 130 and 120 K a phase transition occurs involving a sudden increase of the disorder towards the disorder component ratio 0.65:0.35. Meanwhile, the space group and general organization of the structure are retained. Between 60 and 40 K there is another phase transition leading to a twinned triclinic phase. After heating the crystal back to room temperature its structure is the same as before cooling, indicating a complete reversibility of the phase transitions., Published by Chester

Published
2021
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44. Orthorhombic charge density wave on the tetragonal lattice of EuAl4

Author

Ramakrishnan, Sitaram, primary, Kotla, Surya Rohith, additional, Rekis, Toms, additional, Bao, Jin-Ke, additional, Eisele, Claudio, additional, Noohinejad, Leila, additional, Tolkiehn, Martin, additional, Paulmann, Carsten, additional, Singh, Birender, additional, Verma, Rahul, additional, Bag, Biplab, additional, Kulkarni, Ruta, additional, Thamizhavel, Arumugam, additional, Singh, Bahadur, additional, Ramakrishnan, Srinivasan, additional, and van Smaalen, Sander, additional

Published
2022
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47. Observation of multilayer quantum Hall effect in the charge density wave material CaCu$_4$As$_2$

Author

Sasmal, Souvik, Saini, Vikas, Ramakrishnan, Sitaram, Dwari, Gourav, Maity, Bishal Baran, Bao, Jin-Ke, Mondal, Rajib, Tripathi, Vikram, van Smaalen, Sander, Singh, Bahadur, and Thamizhavel, A.

Subjects
Condensed Matter::Superconductivity, Condensed Matter::Strongly Correlated Electrons, ddc:530
Abstract

Physical review research 4(1), L012011 (2022). doi:10.1103/PhysRevResearch.4.L012011, Low-dimensional layered materials manifest an inherent tendency towards the formation of symmetry reduced charge density wave (CDW) states with exotic properties. Here, we elucidate the anisotropic transport properties of CaCu$_4$As$_2$, which crystallizes in a rhombohedral lattice. Temperature-dependent single-crystal x-ray diffraction in conjunction with thermodynamic and transport measurements reveal that CaCu$_4$As$_2$ undergoes a structural or CDW transition below 51 K. For $I���[1\bar{2}10]$, angular-dependent Shubnikov���de Haas oscillations reveal a two-dimensional nature of the charge carriers contributing to the bulk transport in accord with our calculated Fermi surface. In the inverse Hall resistance versus 1/B plot, quantized Hall plateaus are observed. CaCu$_4$As$_2$ thus provides a new platform to understand the coexistence of both the CDW and quantum Hall effect in materials., Published by APS, College Park, MD

Published
2022
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