H Völker scite author profile

Localization of charge carriers in crystalline solids has been the subject of numerous investigations over more than half a century. Materials that show a metal-insulator transition without a structural change are therefore of interest. Mechanisms leading to metal-insulator transition include electron correlation (Mott transition) or disorder (Anderson localization), but a clear distinction is difficult. Here we report on a metal-insulator transition on increasing annealing temperature for a group of crystalline phase-change materials, where the metal-insulator transition is due to strong disorder usually associated only with amorphous solids. With pronounced disorder but weak electron correlation, these phase-change materials form an unparalleled quantum state of matter. Their universal electronic behaviour seems to be at the origin of the remarkable reproducibility of the resistance switching that is crucial to their applications in non-volatile-memory devices. Controlling the degree of disorder in crystalline phase-change materials might enable multilevel resistance states in upcoming storage devices.

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Low‐Temperature Transport in Crystalline Ge₁Sb₂Te₄

Völker

Jost

Wuttig

2015

Adv Funct Materials

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Disorder and its reduction upon annealing play a crucial role in understanding the electrical transport in the crystalline phase‐change material Ge1Sb2Te4. Previous studies focus either on the impact of disorder at moderate temperatures or on the low‐temperature properties of crystalline films with a low degree of disorder. The present investigation describes and discusses the impact of pronounced disorder on charge transport at low temperatures. The present data reveal the existence of a metal‐to‐insulator transition (MIT), where upon increasing order the zero‐temperature limit of conductivity changes from zero (insulator) to nonzero values (metal). The position of the MIT is determined with respect to the control parameter, i.e., the disorder, which is modified through the annealing conditions. Disorder is shown to localize carriers for an exceptionally large density of states. In the most disordered films, variable range hopping is observed, enabling the determination of the localization length. At the lowest temperatures studied, deviations from Mott variable range hopping are observed, which can be explained by a transition to Efros–Shklovskii hopping due to the presence of a soft Coulomb gap.

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Impact of vacancy ordering on thermal transport in crystalline phase-change materials

et al. 2014

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Controlling thermal transport in solids is of paramount importance for many applications. Often thermal management is crucial for a device's performance, as it affects both reliability and power consumption. A number of intricate concepts have been developed to address this challenge, such as diamond-like coatings to enhance the thermal conductivity or low symmetry complex super-structures to reduce it. Here, a different approach is pursued, where we explore the potential of solids with a high yet controllable degree of disorder. Recently, it has been demonstrated that an unconventionally high degree of structural disorder characterizes a number of crystalline phase-change materials (PCMs). This disorder strongly impacts electronic transport and even leads to disorder induced localization (Anderson localization). This raises the question how thermal transport is affected by such conditions. Here thermal transport in highly disordered crystalline Ge-Sb-Te (GST) based PCMs is investigated. Glass-like thermal properties are observed for several crystalline PCMs, which are attributed to strong scattering by disordered point defects. A systematic study of different compounds along the pseudo-binary line between GeTe and Sb2Te3 reveals that disordered vacancies act as point defects responsible for pronounced phonon scattering. Annealing causes a gradual ordering of the vacancies and leads to a more 'crystal-like' thermal conductivity. While both vibrational and electronic degrees of freedom are affected by disorder, the consequences differ for different stoichiometries. This opens up a pathway to tune electrical and thermal transport by controlling the degree of disorder. Materials with tailored transport properties may not only help to improve power efficiency and scaling in upcoming phase-change memories but are also of fundamental interest in the field of thermoelectric materials.

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Weak antilocalization and disorder-enhanced electron interactions in annealed films of the phase-change compound GeSb2Te4

et al. 2012

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Phase change materials can be reversibly switched between amorphous and crystalline states and often show strong contrast in the optical and electrical properties of these two phases. They are now in widespread use for optical data storage, and their fast switching and a pronounced change of resistivity upon crystallization are also very attractive for nonvolatile electronic data storage. Nevertheless there are still several open questions regarding the electronic states and charge transport in these compounds. In this work we study electrical transport in thin metallic films of the disordered, crystalline phase change material Ge1Sb2Te4. We observe weak antilocalization and disorder enhanced Coulomb interaction effects at low temperatures, and separate the contributions of these two phenomena to the temperature dependence of the resistivity, Hall effect, and magnetoresistance. Strong spin-orbit scattering causes positive magnetoresistance at all temperatures, and a careful analysis of the low-field magnetoresistance allows us to extract the temperature dependent electron dephasing rate and study other scattering phenomena. We find electron dephasing due to inelastic electron-phonon scattering at higher temperatures, electron-electron scattering dephasing at intermediate temperatures, and a crossover to weak temperature dependence below 1 K. arXiv:1208.1104v2 [cond-mat.mes-hall]

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Disorder‐Induced Localization in Crystalline Pseudo‐Binary GeTe–Sb₂Te₃ Alloys between Ge₃Sb₂Te₆ and GeTe

Jost

Völker

Poitz

et al. 2015

Adv Funct Materials

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Disorder has a tremendous impact on charge transport in crystalline compounds on the pseudo-binary line between Sb 2 Te 3 and GeTe. Directly after crystallization, the pronounced disorder on the cation sublattice renders crystalline Ge 1 Sb 2 Te 4 -a composition with a carrier density of the order of 10 20 cm-an Anderson insulator. Annealing, however, induces the reduction of disorder and eventually triggers an insulator-to-metal transition. This study presents data on the electrical properties, the optical conductivity, and structural properties of the pseudo-binary compositions between Ge 3 Sb 2 Te 6 and GeTe. In contrast to the preceding investigations, which rely on the annealing temperature for tuning the electrical properties, this study elucidates the impact of stoichiometry and demonstrates that the stoichiometry may be employed as an alternative control parameter for the metal-to-insulator transition. The combination of annealing temperature and stoichiometry, therefore, provides a rich playground for tailoring disorder and, as a consequence, the transport of charge.

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H Völker

Disorder-induced localization in crystalline phase-change materials

Low‐Temperature Transport in Crystalline Ge₁Sb₂Te₄

Impact of vacancy ordering on thermal transport in crystalline phase-change materials

Weak antilocalization and disorder-enhanced electron interactions in annealed films of the phase-change compound GeSb2Te4

Disorder‐Induced Localization in Crystalline Pseudo‐Binary GeTe–Sb₂Te₃ Alloys between Ge₃Sb₂Te₆ and GeTe

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H Völker

Disorder-induced localization in crystalline phase-change materials

Low‐Temperature Transport in Crystalline Ge1Sb2Te4

Impact of vacancy ordering on thermal transport in crystalline phase-change materials

Weak antilocalization and disorder-enhanced electron interactions in annealed films of the phase-change compound GeSb2Te4

Disorder‐Induced Localization in Crystalline Pseudo‐Binary GeTe–Sb2Te3 Alloys between Ge3Sb2Te6 and GeTe

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Product

Resources

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Low‐Temperature Transport in Crystalline Ge₁Sb₂Te₄

Disorder‐Induced Localization in Crystalline Pseudo‐Binary GeTe–Sb₂Te₃ Alloys between Ge₃Sb₂Te₆ and GeTe