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1. Small-world disordered lattices: spectral gaps and diffusive transport

   https://doi.org/10.1088/1367-2630/ac7db5  

   Rosa, Matheus I. N. ; Ruzzene, Massimo ( July 2022 , New Journal of Physics)

   We investigate the dynamic behavior of lattices with disorder introduced through non-local network connections. Inspired by the Watts–Strogatz small-world model, we employ a single parameter to determine the probability of local connections being re-wired, and to induce transitions between regular and disordered lattices. These connections are added as non-local springs to underlying periodic one-dimensional (1D) and two-dimensional (2D) square, triangular and hexagonal lattices. Eigenmode computations illustrate the emergence of spectral gaps in various representative lattices for increasing degrees of disorder. These gaps manifest themselves as frequency ranges where the modal density goes to zero, or that are populated only by localized modes. In both cases, we observe low transmission levels of vibrations across the lattice. Overall, we find that these gaps are more pronounced for lattice topologies with lower connectivity, such as the 1D lattice or the 2D hexagonal lattice. We then illustrate that the disordered lattices undergo transitions from ballistic to super-diffusive or diffusive transport for increasing levels of disorder. These properties, illustrated through numerical simulations, unveil the potential for disorder in the form of non-local connections to enable additional functionalities for metamaterials. These include the occurrence of disorder-induced spectral gaps, which is relevant to frequency filtering devices, as well as the possibility to induce diffusive-type transport which does not occur in regular periodic materials, and that may find applications in dynamic stress mitigation.

    

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2. Order to disorder in quasiperiodic composites

   https://doi.org/10.1038/s42005-022-00898-z  

   Morison, David ; Murphy, N. Benjamin ; Cherkaev, Elena ; Golden, Kenneth M. ( December 2022 , Communications Physics)

   Abstract From quasicrystalline alloys to twisted bilayer graphene, the study of material properties arising from quasiperiodic structure has driven advances in theory and applied science. Here we introduce a class of two-phase composites, structured by deterministic Moiré patterns, and we find that these composites display exotic behavior in their bulk electrical, magnetic, diffusive, thermal, and optical properties. With a slight change in the twist angle, the microstructure goes from periodic to quasiperiodic, and the transport properties switch from those of ordered to randomly disordered materials. This transition is apparent when we distill the relationship between classical transport coefficients and microgeometry into the spectral properties of an operator analogous to the Hamiltonian in quantum physics. We observe this order to disorder transition in terms of band gaps, field localization, and mobility edges analogous to Anderson transitions — even though there are no wave scattering or interference effects at play here. 

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3. Thickness-dependent phase transition kinetics in lithium-intercalated MoS 2

   https://doi.org/10.1088/2053-1583/ac4e9b  

   Pondick, Joshua V ; Yazdani, Sajad ; Kumar, Aakash ; Hynek, David J ; Hart, James L ; Wang, Mengjing ; Qiu, Diana Y ; Cha, Judy J ( February 2022 , 2D Materials)

   Abstract The phase transitions of two-dimensional (2D) materials are key to the operation of many devices with applications including energy storage and low power electronics. Nanoscale confinement in the form of reduced thickness can modulate the phase transitions of 2D materials both in their thermodynamics and kinetics. Here, using in situ Raman spectroscopy we demonstrate that reducing the thickness of MoS 2 below five layers slows the kinetics of the phase transition from 2H- to 1T′-MoS 2 induced by the electrochemical intercalation of lithium. We observe that the growth rate of 1T′ domains is suppressed in thin MoS 2 supported by SiO 2 , and attribute this growth suppression to increased interfacial effects as the thickness is reduced below 5 nm. The suppressed kinetics can be reversed by placing MoS 2 on a 2D hexagonal boron nitride ( h BN) support, which readily facilitates the release of strain induced by the phase transition. Additionally, we show that the irreversible conversion of intercalated 1T′-MoS 2 into Li 2 S and Mo is also thickness-dependent and the stability of 1T′-MoS 2 is significantly increased below five layers, requiring a much higher applied electrochemical potential to break down 1T′-MoS 2 into Li 2 S and Mo nanoclusters. 

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4. Hysteresis in the thermally induced phase transition of cellulose ethers

   https://doi.org/10.1039/d2sm00564f  

   Bizmark, Navid ; Caggiano, Nicholas J. ; Liu, Jason X. ; Arnold, Craig B. ; Prud’homme, Robert K. ; Datta, Sujit S. ; Priestley, Rodney D. ( August 2022 , Soft Matter)

   Functionalized cellulosics have shown promise as naturally derived thermoresponsive gelling agents. However, the dynamics of thermally induced phase transitions of these polymers at the lower critical solution temperature (LCST) are not fully understood. Here, with experiments and theoretical considerations, we address how molecular architecture dictates the mechanisms and dynamics of phase transitions for cellulose ethers. Above the LCST, we show that hydroxypropyl substituents favor the spontaneous formation of liquid droplets, whereas methyl substituents induce fibril formation through diffusive growth. In celluloses which contain both methyl and hydroxypropyl substituents, fibrillation initiates after liquid droplet formation, suppressing the fibril growth to a sub-diffusive rate. Unlike for liquid droplets, the dissolution of fibrils back into the solvated state occurs with significant thermal hysteresis. We tune this hysteresis by altering the content of substituted hydroxypropyl moieties. This work provides a systematic study to decouple competing mechanisms during the phase transition of multi-functionalized macromolecules. 

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5. Electric-double-layer-gated transistors based on two-dimensional crystals: recent approaches and advances

   https://doi.org/10.1088/2515-7639/ab8270  

   Xu, Ke ; Fullerton-Shirey, Susan K. ( May 2020 , Journal of Physics: Materials)

   Electric-double-layer (EDL) gated transistors use ions in an electrolyte to induce charge in the channel of the transistor by field-effect. Because a sub-nanometer gap capacitor is created at the electrolyte/channel interface, large capacitance densities (∼µF cm⁻²) corresponding to high sheet carrier densities (10¹⁴cm⁻²) can be induced, exceeding conventional gate dielectrics by about one order of magnitude. Because it is an interfacial technique, EDL gating is especially effective on two-dimensional (2D) crystals, which—at the monolayer limit—are basically interfaces themselves. Both solid polymer electrolytes and ionic liquids are routinely used as ion-conducting gate dielectrics, and they have provided access to regimes of transport in 2D materials that would be inaccessible otherwise. The technique, now widely used, has enabled the 2D crystal community to study superconductivity, spin- and valleytronics, investigate electrical and structural phase transitions, and create abruptp-njunctions to generate tunneling, among others. In addition to using EDL gating as a tool to investigate properties of the 2D crystals, more recent efforts have emerged to engineer the electrolyte to add new functionality and device features, such as synaptic plasticity, bistability and non-volatility. Example of potential applications include neuromorphic computing and non-volatile memory. This review focuses on using ions forelectrostaticcontrol of 2D crystal transistors both to uncover basic properties of 2D crystals, and also to add new device functionalities.

    

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