Layered Double Hydroxides: Proposal of a One-Layer Cation-Ordered Structure Model of Monoclinic Symmetry

Jayanthi, K.; Nagendran, Supreeth; Kamath, P. Vishnu

doi:10.1021/acs.inorgchem.5b01050

Cited by 15 publications

(25 citation statements)

References 26 publications

(100 reference statements)

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“…The key to the successful choice of a monoclinic cell is to find the appropriate value for the stacking angle β, in c-stacking. 20 In this we were greatly aided by DIFFaX simulations (Fig. 3).…”

Section: Resultsmentioning

confidence: 99%

Structure models for the hydrated and dehydrated nitrate-intercalated layered double hydroxide of Li and Al

2016

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Imbibition of LiNO into gibbsite results in the formation of a single phase layered double hydroxide of the composition LiAl(OH)(NO)·1.2HO. This phase undergoes reversible dehydration along with the compression of the basal spacing accompanied by the reorientation of the nitrate in the interlayer gallery. The hydrated phase is a solid solution of two lattices: (i) a hexagonal lattice defining the ordering of atoms within the metal hydroxide layer, and (ii) a lattice of orthorhombic symmetry defining the ordering of atoms within the interlayer. DFT calculations of the hydration behaviour show that there is no registry between the two sublattices. In the dehydrated phase, the nitrate ion is intercalated with its molecular plane parallel to the metal hydroxide layer and the crystal adopts a structure of hexagonal symmetry.

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Section: Resultsmentioning

confidence: 99%

Structure models for the hydrated and dehydrated nitrate-intercalated layered double hydroxide of Li and Al

2016

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“…We note that the structural model of the 1 M polytype proposed by us for quintinite-1 M was used by Jayanthi et al . (2015) for synthetic LDHs and applied for the Rietveld structure refinement of the synthetic analogue of zaccagnaite, [Zn 4 Al 2 (OH) 12 ][(CO 3 )(H 2 O) 3 ] (Marappa and Kamath, 2015).…”

Section: Introductionmentioning

confidence: 99%

“…Previously published structural models of quintinite appeared to be helpful for the characterization of hydrotalcite-supergroup members (Lozano et al ., 2012; Mills et al ., 2012 a ; Theiss et al ., 2015); synthetic layered double hydroxides (Zhang and Evans, 2012; Jayanthi and Kamath, 2013, 2016; Radha et al ., 2014; Jayanthi et al ., 2015; Marappa and Kamath, 2015); their crystal structure simulation and analysis (Radha and Kamath, 2012; Richardson, 2013; Ghamami et al ., 2016; Tsukanov and Psakhie, 2016).…”

Section: Introductionmentioning

confidence: 99%

Crystal chemistry of natural layered double hydroxides: 4. Crystal structures and evolution of structural complexity of quintinite polytypes from the Kovdor alkaline-ultrabasic massif, Kola peninsula, Russia

et al. 2018

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Two quintinite polytypes, 3R and 2T, which are new for the Kovdor alkaline-ultrabasic complex, have been structurally characterized. The crystal structure of quintinite-2T was solved by direct methods and refined to R1 = 0.048 on the basis of 330 unique reflections. The structure is trigonal, P$\bar 3$c1, a = 5.2720(6), c = 15.113(3) Å and V = 363.76(8) Å3. The crystal structure consists of [Mg2Al(OH)6]+ brucite-type layers with an ordered distribution of Mg2+ and Al3+ cations according to the $\sqrt 3 $ × $\sqrt 3 $ superstructure with the layers stacked according to a hexagonal type. The complete layer stacking sequence can be described as …=Ab1C = Cb1A=…. The crystal structure of quintinite-3R was solved by direct methods and refined to R1 = 0.022 on the basis of 140 unique reflections. It is trigonal, R$\bar 3$m, a = 3.063(1), c = 22.674(9) Å and V = 184.2(1) Å3. The crystal structure is based upon double hydroxide layers [M2+,3+(OH)2] with disordered distribution of Mg, Al and Fe and with the layers stacked according to a rhombohedral type. The stacking sequence of layers can be expressed as …=АB = BC = CA=… The study of morphologically different quintinite generations grown on one another detected the following natural sequence of polytype formation: 2H → 2T → 1M that can be attributed to a decrease of temperature during crystallization. According to the information-based approach to structural complexity, this sequence corresponds to the increasing structural information per atom (IG): 1.522 → 1.706 → 2.440 bits, respectively. As the IG value contributes negatively to the configurational entropy of crystalline solids, the evolution of polytypic modifications during crystallization corresponds to the decreasing configurational entropy. This is in agreement with the general principle that decreasing temperature corresponds to the appearance of more complex structures.

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“…The [Cr(OH) 6 ] polyhedron has D 2 h symmetry in the [Cu–Cr] LDH, and C 3 v symmetry in the [Zn–Cr] LDH. In the observed structures, the [M(OH) 6 ] polyhedra have C 3 symmetry when M = Cu 2+ , and D 3 symmetry when M = Zn 2+ . In the computed structures, the coordination symmetry of the [Cu(OH) 6 ] polyhedron varies from C s to C 2 and that of the [Zn(OH) 6 ] polyhedron is D 3 and C 2 .…”

Section: Resultsmentioning

confidence: 88%

“…6 ] polyhedra have C 3 symmetry when M = Cu 2+ , [22] and D 3 symmetry when M = Zn 2+ . [23] In the computed structures, the coordination symmetry of the [Cu(OH) 6 ] polyhedron varies from C s to C 2 and that of the [Zn(OH) 6 ] polyhedron is D 3 and C 2 . The lowering of the coordination symmetry of the divalent ions from the ideal D 3d is especially puzzling in crystals of high symmetry, and it forms the subject matter of this paper.…”

Section: Computation Of the Structure By Energy Minimizationmentioning

confidence: 99%

Electronic‐Structure Calculations of Cation‐Ordered II‐III Layered Double Hydroxides: Origin of the Distortion of the Metal‐Coordination Symmetry

2017

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Cation ordering brings down the crystal symmetry and introduces distortion into the coordination polyhedra around the divalent cations. In particular, edge sharing of the differently sized [M(OH)6] polyhedra causes a non‐uniform distension of the array of hydroxy ions. The question arises as to whether this distortion has its origin in the Jahn–Teller distortion of metal coordination or a 2D “Peierls”‐type distortion of the array of hydroxy ions. To address this question, DFT calculations were performed on the sulfate‐intercalated [Cu–Cr], [Zn–Cr], and [Zn–Al] layered double hydroxides (LDHs). An analysis of the density of states shows that the distortion of the Cu2+ coordination polyhedron is due to the Jahn–Teller effect, whereas the Zn2+ coordination polyhedron in [Zn–Al] LDH likely suffers a “Peierls”‐type distortion. In the [Zn–Cr] LDH, electronic‐structure calculations do not predict any distortion in the metal coordination, which is in agreement with experimental results that show only a slight departure from ideal symmetry.

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Layered Double Hydroxides: Proposal of a One-Layer Cation-Ordered Structure Model of Monoclinic Symmetry

Cited by 15 publications

References 26 publications

Structure models for the hydrated and dehydrated nitrate-intercalated layered double hydroxide of Li and Al

Structure models for the hydrated and dehydrated nitrate-intercalated layered double hydroxide of Li and Al

Crystal chemistry of natural layered double hydroxides: 4. Crystal structures and evolution of structural complexity of quintinite polytypes from the Kovdor alkaline-ultrabasic massif, Kola peninsula, Russia

Electronic‐Structure Calculations of Cation‐Ordered II‐III Layered Double Hydroxides: Origin of the Distortion of the Metal‐Coordination Symmetry

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