On the microstructure of the charge density wave observed in La1−xCaxMnO3

Loudon, J. C.; Cox, Susan; Mathur, N. D.; Midgley, Paul A.

doi:10.1080/14786430412331323555

Cited by 16 publications

(12 citation statements)

References 28 publications

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“…Owing to the large periodicity of the CDWs locking into the lattice at transition 3 (6b and 5:5c), it should be the transition most affected by disorder, explaining its disappearance in the polycrystal. This is consistent with observations of similar ordering in which the strain in a polycrystalline sample can prevent a lock-in in some grains [7]. Therefore the CDW transitions in both single crystal and polycrystalline -U can be modeled as DPTs, without erroneously invoking pinning modes of the CDWs.…”

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Comment on “Pinning Frequencies of the Collective Modes inα-Uranium”

et al. 2007

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We point out that a recent model for the heat capacity of -U that invokes charge-density-wave (CDW) collective modes is unphysical. We show instead that the features in the heat capacity of both single crystal and polycrystalline -U can be accounted for by a number of Peierls transitions that are subject to increased disorder in the polycrystalline sample.The fundamental flaw in the interpretation of Uranium heat capacity (C p ) reported in [1] concerns the relative temperature scales of the CDW collective mode (to which phenomena in C p are attributed) and the CDW transitions. For the collective mode to be a valid description of the lowest-energy excited state of the CDW, the temperature (T) should be such that pair breaking is completely negligible; e.g., for the CDW material TaSe 4 2 I the Peierls transition occurs at 263 K, whereas collective mode contributions to C p are observed for T & 1:7 K [2]. By contrast, the authors of Ref.[1] claim erroneously that collective mode contributions are responsible for phenomena at and around the CDW ordering T's, where the single-particle gap is closing, and subgap excitations will be smeared out.Reference [1] contains important technical errors. First, when the model of [1] is plotted over the whole T range of the C p anomalies [ Fig. 1(a), curves], rather than the restricted ranges used in [1] [ Fig. 1(a), bold lines], it is clear that the model bears no resemblance to the data. Second, Mihaila et al. incorrectly substitute D for in the model. It is explicitly stated in [2] that is the Debye T for phasons ( & 10 K), which is distinct from the Debye T for phonons ( D ' 256 K). These quantities have different origins, and differ by at least an order of magnitude. Third, Mihaila et al. use polycrystal data as a background, assuming that there is no contribution from CDWs. However, if the background C p is modeled, it can be seen that peaks associated with CDWs are present in both single crystal and polycrystal data [ Fig. 1(b)].The peaks in C p should instead be attributed to the second order CDW transitions. These can be modeled as disordered system Peierls transitions (DPTs) [3,4]. The increased disorder in the polycrystal relative to the single crystal leads to the transitions being broadened or destroyed. By removing the smooth background of C p [4], three transitions in the single crystal [ Fig. 1(c)] [5] were revealed. In the polycrystal an excess C p was evident in the T range of transitions 1 and 2 in the single crystal, with transition 3 absent [ Fig. 1(d)]. The DPT model fits the data well in both cases [Figs. 1(c) and 1(d)].Transition 1 is the onset of the three CDWs, all incommensurate. At transition 2, q x locks into 0:5a , and at transition 3, q y and q z lock into 1 6 b and 2 11 c , respectively [6]. Owing to the large periodicity of the CDWs locking into the lattice at transition 3 (6b and 5:5c), it should be the transition most affected by disorder, explaining its disappearance in the polycrystal. This is consistent with observations of similar ordering ...

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“…3͑c͔͒ measured using a Quantum Design superconducting quantum interference device. Below 150 K, ͑1͒ all but one value of is nonzero within error and the material is primarily antiferromagnetic, 9,17 and ͑2͒ q / a * Ϸ 0.46 varies little with temperature, but falls short of the expected 13 ͑1−x͒ = 0.48 perhaps due to pinning 21 ͓which would also produce the local variations in superlattice orientation seen in Figs. 2͑c͒ and 2͑e͔͒.…”

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Limited local electron-lattice coupling in manganites: An electron diffraction study

et al. 2008

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“…Electronically "soft" phases with weak electron-lattice coupling have been suggested 17 and a phenomenological Ginzburg-Landau theory was postulated 16 to describe these phases in a delocalised charge-density wave (CDW) picture. 22,23 At this point, it has to be stated that any CO pattern could be regarded as some kind of CDW. However, the term CDW is conventionally used only for systems which undergo a Peierls transition by cooling below the Peierls transition temperature T PE .…”

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Investigation of the electronic structure of the charge-ordered phase in epitaxial and polycrystallineLa1−xCaxMnO3
Schmidt
¹

2008
Phys. Rev. B
37
0
9
0
1
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In this work the charge transport properties of charge ordered (CO) La 1-x Ca x MnO 3 (LCMO) (x= 0.55, 0.67) epitaxial thin films and polycrystals are discussed following the recent controversy of localised electron states vs. weakly or delocalised charge-density wave (CDW) states in CO manganites. The transport properties were investigated by current vs. voltage, direct current resistivity vs. temperature, local activation energy vs. temperature, magnetoresistance and admittance spectroscopy measurements, which all indicated a localised electronic structure in the single CO phase. Delocalised charge anomalies observed previously may be restricted to phase separated materials.

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On the microstructure of the charge density wave observed in La₁₋_xCa_xMnO₃

Cited by 16 publications

References 28 publications

Comment on “Pinning Frequencies of the Collective Modes inα-Uranium”

Comment on “Pinning Frequencies of the Collective Modes inα-Uranium”

Limited local electron-lattice coupling in manganites: An electron diffraction study

Investigation of the electronic structure of the charge-ordered phase in epitaxial and polycrystallineLa1−xCaxMnO3
Schmidt
¹

2008
Phys. Rev. B
37
0
9
0
1
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On the microstructure of the charge density wave observed in La1−xCaxMnO3

Cited by 16 publications

References 28 publications

Comment on “Pinning Frequencies of the Collective Modes inα-Uranium”

Comment on “Pinning Frequencies of the Collective Modes inα-Uranium”

Limited local electron-lattice coupling in manganites: An electron diffraction study

Investigation of the electronic structure of the charge-ordered phase in epitaxial and polycrystallineLa1−xCaxMnO3Schmidt1 2008Phys. Rev. B370901View full textAdd to dashboardCite

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On the microstructure of the charge density wave observed in La₁₋_xCa_xMnO₃

Investigation of the electronic structure of the charge-ordered phase in epitaxial and polycrystallineLa1−xCaxMnO3
Schmidt
¹

2008
Phys. Rev. B
37
0
9
0
1
View full text Add to dashboard Cite