Your search keyword '"ORDER-DISORDER TRANSITION"' showing total 9 results

1. Influences of the Periodicity in Molecular Architecture on the Phase Diagrams and Microphase Transitions of the Janus Double-Brush Copolymer with a Loose Graft.

Author

Sun, Dachuan and Song, Yang

Subjects

*PHASE diagrams, *MEAN field theory, *SELF-consistent field theory, *GRAFT copolymers, *ORDER-disorder transitions, *COPOLYMERS

Abstract

The backbone of the Janus double-brush copolymer may break during long-term service, but whether this breakage affects the self-assembled phase state and microphase transitions of the material is still unknown. For the Janus double-brush copolymers with a periodicity in molecular architecture ranging from 1 to 10, the influences of the architectural periodicity on their phase diagrams and order–disorder transitions (ODT) were investigated by the self-consistent mean field theory (SCFT). In total, nine microphases with long-range order were found. By comparing the phase diagrams between copolymers of different periodicity, a decrease in periodicity or breakage along the copolymer backbone had nearly no influence on the phase diagrams unless the periodicity was too short to be smaller than 3. For copolymers with neutral backbones, a decrease in periodicity or breakage along the copolymer backbone reduced the critical segregation strengths of the whole copolymer at ODT. The equations for the critical segregation strengths at ODT, the architectural periodicity, and the volume fraction of the backbone were established for the Janus double-brush copolymers. The theoretical calculations were consistent with the previous theoretical, experimental, and simulation results. [ABSTRACT FROM AUTHOR]

Published

2022

2. Atomic Interactions and Order–Disorder Transition in FCC-Type FeCoNiAl 1− x Ti x High-Entropy Alloys.

Author

Wu, Ying, Li, Zhou, Feng, Hui, and He, Shuang

Subjects

*ORDER-disorder transitions, *ATOMIC interactions, *ALLOYS, *BINARY metallic systems, *ATOMIC radius, *EMBRITTLEMENT

Abstract

Single-phase high-entropy alloys with compositionally disordered elemental arrangements have excellent strength, but show a serious embrittlement effect with increasing strength. Precipitation-hardened high-entropy alloys, such as those strengthened by L12-type ordered intermetallics, possess a superior synergy of strength and ductility. In this work, we employ first-principles calculations and thermodynamic simulations to explore the atomic interactions and order–disorder transitions in FeCoNiAl1−xTix high-entropy alloys. Our calculated results indicate that the atomic interactions depend on the atomic size of the alloy components. The thermodynamic stability behaviors of L12 binary intermetallics are quite diverse, while their atomic arrangements are short-range in FeCoNiAl1−xTix high-entropy alloys. Moreover, the order–disorder transition temperatures decrease with increasing Ti content in FeCoNiAl1−xTix high-entropy alloys, the characteristics of order–disorder transition from first-principles calculations are in line with experimental observations and CALPHAD simulations. The results of this work provide a technique strategy for proper control of the order–disorder transitions that can be used for further optimizing the microstructure characteristics as well as the mechanical properties of FeCoNiAl1−xTixhigh-entropy alloys. [ABSTRACT FROM AUTHOR]

Published

2022

3. Optimizing Chain Topology of Bottle Brush Copolymer for Promoting the Disorder-to-Order Transition.

Author

Park, Jihoon, Shin, Hyun-Woo, Bang, Joona, and Huh, June

Subjects

*ORDER-disorder transitions, *STRUCTURAL isomers, *TOPOLOGY, *PARTICLE dynamics, *BOTTLES

Abstract

The order-disorder transitions (ODT) of core-shell bottle brush copolymer and its structural isomers were investigated by dissipative particle dynamics simulations and theoretically by random phase approximation. Introducing a chain topology parameter λ which parametrizes linking points between M diblock chains each with N monomers, the degree of incompatibility at ODT ( (χ N) ODT ; χ being the Flory–Huggins interaction parameter between constituent monomers) was predicted as a function of chain topology parameter (λ) and the number of linked diblock chains per bottle brush copolymer (M). It was found that there exists an optimal chain topology about λ at which (χ N) ODT gets a minimum while the domain spacing remains nearly unchanged. The prediction provides a theoretical guideline for designing an optimal copolymer architecture capable of forming sub-10 nm periodic structures even with non-high χ components. [ABSTRACT FROM AUTHOR]

Published

2022

4. Structural and Dynamical Order of a Disordered Protein: Molecular Insights into Conformational Switching of PAGE4 at the Systems Level

Author

Lin, Xingcheng, Lin, Xingcheng, Kulkarni, Prakash, Bocci, Federico, Schafer, Nicholas P., Roy, Susmita, Tsai, Min-Yeh, He, Yanan, Chen, Yihong, Rajagopalan, Krithika, Mooney, Steven M., Zeng, Yu, Weninger, Keith, Grishaev, Alex, Onuchic, José N., Levine, Herbert, Wolynes, Peter G., Salgia, Ravi, Rangarajan, Govindan, Uversky, Vladimir, Orban, John, Jolly, Mohit Kumar, Lin, Xingcheng, Lin, Xingcheng, Kulkarni, Prakash, Bocci, Federico, Schafer, Nicholas P., Roy, Susmita, Tsai, Min-Yeh, He, Yanan, Chen, Yihong, Rajagopalan, Krithika, Mooney, Steven M., Zeng, Yu, Weninger, Keith, Grishaev, Alex, Onuchic, José N., Levine, Herbert, Wolynes, Peter G., Salgia, Ravi, Rangarajan, Govindan, Uversky, Vladimir, Orban, John, and Jolly, Mohit Kumar

Abstract

Folded proteins show a high degree of structural order and undergo (fairly constrained) collective motions related to their functions. On the other hand, intrinsically disordered proteins (IDPs), while lacking a well-defined three-dimensional structure, do exhibit some structural and dynamical ordering, but are less constrained in their motions than folded proteins. The larger structural plasticity of IDPs emphasizes the importance of entropically driven motions. Many IDPs undergo function-related disorder-to-order transitions driven by their interaction with specific binding partners. As experimental techniques become more sensitive and become better integrated with computational simulations, we are beginning to see how the modest structural ordering and large amplitude collective motions of IDPs endow them with an ability to mediate multiple interactions with different partners in the cell. To illustrate these points, here, we use Prostate-associated gene 4 (PAGE4), an IDP implicated in prostate cancer (PCa) as an example. We first review our previous efforts using molecular dynamics simulations based on atomistic AWSEM to study the conformational dynamics of PAGE4 and how its motions change in its different physiologically relevant phosphorylated forms. Our simulations quantitatively reproduced experimental observations and revealed how structural and dynamical ordering are encoded in the sequence of PAGE4 and can be modulated by different extents of phosphorylation by the kinases HIPK1 and CLK2. This ordering is reflected in changing populations of certain secondary structural elements as well as in the regularity of its collective motions. These ordered features are directly correlated with the functional interactions of WT-PAGE4, HIPK1-PAGE4 and CLK2-PAGE4 with the AP-1 signaling axis. These interactions give rise to repeated transitions between (high HIPK1-PAGE4, low CLK2-PAGE4) and (low HIPK1-PAGE4, high CLK2-PAGE4) cell phenotypes, which possess differing s

Published

2019

5. Ordering Phase Transition with Symmetry-Breaking from Disorder over Non-Equivalent Sites: Calorimetric and Crystallographic Study of Crystalline d-Sorbose

Author

Kazuhiro Fukada, Yasuhisa Yamamura, Mafumi Hishida, Hiroki Kakuta, Hideki Saitoh, Sakiko Iwagaki, and Kazuya Saito

Subjects

Phase transition, structural phase transition, Materials science, General Chemical Engineering, Calorimetry, Crystal structure, 010402 general chemistry, 01 natural sciences, Heat capacity, order-disorder transition, Inorganic Chemistry, chemistry.chemical_compound, Phase (matter), 0103 physical sciences, lcsh:QD901-999, General Materials Science, Symmetry breaking, entropy of transition, 010304 chemical physics, symmetry-breaking, Condensed Matter Physics, Sorbose, 0104 chemical sciences, Crystallography, chemistry, lcsh:Crystallography, Glass transition, calorimetry

Abstract

Phase transitions in the crystalline state of chiral sorbose were examined using precise heat capacity calorimetry and X-ray crystallography. The calorimetry established heat capacity below room temperature. Besides the known transition (main transition) at 199.5 K, the calorimetry detected plural thermal anomalies assignable to new phase transitions (around 210 K) and a glass transition (at ca. 120 K). The X-ray diffraction at low temperatures established the crystal structure of the lowest temperature phase. The identification of the broken symmetry upon the main transition solves an apparent contradiction that the structural disorder reported previously does not contribute seemingly to the symmetrization.

Published

2020

6. Effect of the Order-Disorder Transition on the Electronic Structure and Physical Properties of Layered CuCrS 2.

Author

Korotaev, Evgeniy V., Syrokvashin, Mikhail M., Filatova, Irina Yu., and Sotnikov, Aleksandr V.

Subjects

*ORDER-disorder transitions, *ELECTRONIC structure, *METAL-insulator transitions, *ELECTRICAL resistivity, *BAND gaps

Abstract

The work reports a comprehensive study of the Seebeck coefficient, electrical resistivity and heat capacity of CuCrS2 in a wide temperature range of 100–740 K. It was shown that the value of the Seebeck coefficient is significantly affected by the sample treatment procedure. The order-to-disorder (ODT) phase transition was found to cause a metal-insulator transition (MIT). It was established that the ODT diminishes the Seebeck coefficient at high temperatures (T > 700 K). The DFT calculations of the CuCrS2 electronic structure showed that the localization of copper atoms in octahedral sites makes the band gap vanish due to the MIT. The decrease of CuCrS2 electrical resistivity in the ODT temperature region corresponds to the MIT. [ABSTRACT FROM AUTHOR]

Published

2021

7. Ordering Phase Transition with Symmetry-Breaking from Disorder over Non-Equivalent Sites: Calorimetric and Crystallographic Study of Crystalline d-Sorbose.

Author

Iwagaki, Sakiko, Kakuta, Hiroki, Yamamura, Yasuhisa, Saitoh, Hideki, Hishida, Mafumi, Fukada, Kazuhiro, and Saito, Kazuya

Subjects

PHASE transitions, GLASS transitions, HEAT capacity, SYMMETRY breaking, X-ray crystallography

Abstract

Phase transitions in the crystalline state of chiral sorbose were examined using precise heat capacity calorimetry and X-ray crystallography. The calorimetry established heat capacity below room temperature. Besides the known transition (main transition) at 199.5 K, the calorimetry detected plural thermal anomalies assignable to new phase transitions (around 210 K) and a glass transition (at ca. 120 K). The X-ray diffraction at low temperatures established the crystal structure of the lowest temperature phase. The identification of the broken symmetry upon the main transition solves an apparent contradiction that the structural disorder reported previously does not contribute seemingly to the symmetrization. [ABSTRACT FROM AUTHOR]

Published

2020

8. Effect of the Order-Disorder Transition on the Seebeck Coefficient of Nanostructured Thermoelectric Cu2ZnSnS4.

Author

Isotta, Eleonora, Fanciulli, Carlo, Pugno, Nicola M., and Scardi, Paolo

Subjects

*ORDER-disorder transitions, *CRYSTAL symmetry, *THERMAL analysis, *SEEBECK coefficient, *THERMOELECTRIC materials, *CRYSTAL structure

Abstract

Bulk samples of kesterite (Cu2ZnSnS4, CZTS) were produced by cold-pressing and sintering of CZTS powders obtained via reactive ball-milling. An increase in the Seebeck coefficient of more than 100 μV/K, almost doubling the expected value, is noticed around a temperature of 260 °C. As pointed out by thermal analyses, this is due to a second order transition of kesterite from an ordered I-4 to a disordered I-42m crystal structure. Conversely to what happens for solar cell materials, where the transition is considered to be detrimental for the performance, it appears to be beneficial for the thermoelectric Seebeck coefficient, suggesting that higher crystal symmetry and cation-disorder due to the transition lead to thermopower enhancement. [ABSTRACT FROM AUTHOR]

Published

2019

9. Low-Temperature Ordering in the Cluster Compound (Bi8)Tl[AlCl4]3.

Author

Knies, Maximilian, Kaiser, Martin, Lê Anh, Mai, Efimova, Anastasia, Doert, Thomas, and Ruck, Michael

Subjects

*SINGLE crystals, *PEROVSKITE, *SPACE groups, *ORDER-disorder transitions, *IONIC liquids, *X-ray diffraction

Abstract

The reaction of Bi, BiCl3, and TlCl in the ionic liquid [BMIm]Cl·4AlCl3 (BMIm = 1-n-butyl-3-methylimidazolium) at 180 °C yielded air-sensitive black crystals of (Bi8)Tl[AlCl4]3. X-ray diffraction on single crystals at room temperature revealed a structure containing [ Tl (AlCl 4) 3 ] ∞ 1 2 − strands separated by isolated Bi82+ square antiprisms. The thallium(I) ion is coordinated by twelve Cl− ions of six [AlCl4]− groups, resulting in a chain of face-sharing [TlCl12]11− icosahedra. The Bi82+ polycation is disordered, simulating a threefold axis through its center and overall hexagonal symmetry (space group P63/m). Slowly cooling the crystals to 170 K resulted in increased order in the Bi8 cluster orientations. An ordered structure model in a supercell with a' = 2a, b' = 2b, c' = 3c and the space group P65 was refined. The structure resembles a hexagonal perovskite, with complex groups in place of simple ions. [ABSTRACT FROM AUTHOR]

Published

2019