Wednesday, November 6, 2024
No menu items!
HomeNatureElectrically driven long-range solid-state amorphization in ferroic In2Se3

Electrically driven long-range solid-state amorphization in ferroic In2Se3

  • Wong, H. S. P. et al. Phase change memory. Proc. IEEE 98, 2201–2227 (2010).

    Article 

    Google Scholar
     

  • Nam, S. W. et al. Electrical wind force-driven and dislocation-templated amorphization in phase-change nanowires. Science 336, 1561–1566 (2012).

    Article 
    ADS 
    CAS 
    PubMed 

    Google Scholar
     

  • Nukala, P., Lin, C. C., Composto, R. & Agarwal, R. Ultralow-power switching via defect engineering in germanium telluride phase-change memory devices. Nat. Commun. 7, 10482 (2016).

    Article 
    ADS 
    CAS 
    PubMed 
    PubMed Central 

    Google Scholar
     

  • Lee, S. H., Jung, Y. & Agarwal, R. Highly scalable non-volatile and ultra-low-power phase-change nanowire memory. Nat. Nanotechnol. 2, 626–630 (2007).

    Article 
    ADS 
    CAS 
    PubMed 

    Google Scholar
     

  • Jung, Y., Nam, S. W. & Agarwal, R. High-resolution transmission electron microscopy study of electrically-driven reversible phase change in Ge2Sb2Te5 nanowires. Nano Lett. 11, 1364–1368 (2011).

    Article 
    ADS 
    CAS 
    PubMed 

    Google Scholar
     

  • Fecht, H. J. Defect-induced melting and solid-state amorphization. Nature 356, 133–135 (1992).

    Article 
    ADS 
    CAS 

    Google Scholar
     

  • Zapperi, S., Cizeau, P., Durin, G. & Stanley, H. E. Dynamics of a ferromagnetic domain wall: avalanches, depinning transition, and the Barkhausen effect. Phys. Rev. B 58, 6353–6366 (1998).

    Article 
    ADS 
    CAS 

    Google Scholar
     

  • Casals, B., Nataf, G. F. & Salje, E. K. H. Avalanche criticality during ferroelectric/ ferroelastic switching. Nat. Commun. 12, 345 (2021).

    Article 
    CAS 
    PubMed 
    PubMed Central 

    Google Scholar
     

  • Biroli, G. Disordered solids: in search of the perfect glass. Nat. Phys. 10, 555–556 (2014).

    Article 
    CAS 

    Google Scholar
     

  • Berthier, L. & Biroli, G. Theoretical perspective on the glass transition and amorphous materials. Rev. Mod. Phys. 83, 587–645 (2011).

    Article 
    ADS 
    CAS 

    Google Scholar
     

  • Russo, J., Romano, F. & Tanaka, H. Glass forming ability in systems with competing orderings. Phys. Rev. 8, 021040 (2018).

    Article 
    CAS 

    Google Scholar
     

  • Klement, W., Willens, R. H. & Duwez, P. Non-crystalline structure in solidified gold–silicon alloys. Nature 187, 869–870 (1960).

    Article 
    ADS 
    CAS 

    Google Scholar
     

  • Zhang, L. et al. Amorphous martensite in β-Ti alloys. Nat. Commun. 9, 506 (2018).

    Article 
    ADS 
    PubMed 
    PubMed Central 

    Google Scholar
     

  • Rehn, L. E., Okamoto, P. R., Pearson, J., Bhadra, R. & Grimsditch, M. Solid-state amorphization of Zr3Al: evidence of an elastic instability and first-order phase transformation. Phys. Rev. Lett. 59, 2987–2990 (1987).

    Article 
    ADS 
    CAS 
    PubMed 

    Google Scholar
     

  • Bridges, F. et al. Local vibrations and negative thermal expansion in ZrW2O8. Science 280, 886–890 (1998).


    Google Scholar
     

  • He, Y. et al. In situ observation of shear-driven amorphization in silicon crystals. Nat. Nanotechnol. 11, 866–871 (2016).

    Article 
    ADS 
    CAS 
    PubMed 

    Google Scholar
     

  • Shportko, K. et al. Resonant bonding in crystalline phase-change materials. Nat. Mater. 7, 653–658 (2008).

    Article 
    ADS 
    CAS 
    PubMed 

    Google Scholar
     

  • Nukala, P. et al. Inverting polar domains via electrical pulsing in metallic germanium telluride. Nat. Commun. 8, 15033 (2017).

    Article 
    ADS 
    CAS 
    PubMed 
    PubMed Central 

    Google Scholar
     

  • Edwards, A. H. et al. Electronic structure of intrinsic defects in crystalline germanium telluride. Phys. Rev. B 73, 045210 (2006).

    Article 
    ADS 

    Google Scholar
     

  • Lines, M. E. & Glass, A. M. Principles and Applications of Ferroelectrics and Related Materials (Oxford Univ. Press, 2001).

  • Ding, W. et al. Prediction of intrinsic two-dimensional ferroelectrics in In2Se3 and other III2-VI3 van der Waals materials. Nat. Commun. 8, 14956 (2017).

    Article 
    ADS 
    CAS 
    PubMed 
    PubMed Central 

    Google Scholar
     

  • Xiao, J. et al. Intrinsic two-dimensional ferroelectricity with dipole locking. Phys. Rev. Lett. 120, 227601 (2018).

    Article 
    ADS 
    CAS 
    PubMed 

    Google Scholar
     

  • Xu, C. et al. Two-dimensional antiferroelectricity in nanostripe-ordered In2Se3. Phys. Rev. Lett. 125, 47601 (2020).

    Article 
    ADS 
    CAS 

    Google Scholar
     

  • Xu, C. et al. Two-dimensional ferroelasticity in van der Waals β’-In2Se3. Nat. Commun. 12, 3665 (2021).

    Article 
    ADS 
    CAS 
    PubMed 
    PubMed Central 

    Google Scholar
     

  • Zhang, Z. et al. Atomic visualization and switching of ferroelectric order in β-In2Se3 films at the single layer limit. Adv. Mater. 34, 2106951 (2022).

    Article 
    CAS 

    Google Scholar
     

  • Wang, L. et al. In-plane ferrielectric order in van der Waals β′-In2Se3. ACS Nano 18, 809–818 (2024).

    Article 
    CAS 
    PubMed 

    Google Scholar
     

  • Peng, H., Schoen, D. T., Meister, S., Zhang, X. F. & Cui, Y. Synthesis and phase transformation of In2Se3 and CuInSe2 nanowires. J. Am. Chem. Soc. 129, 34–35 (2007).

    Article 
    CAS 
    PubMed 

    Google Scholar
     

  • Liu, L. et al. Atomically resolving polymorphs and crystal structures of In2Se3. Chem. Mater. 31, 10143–10149 (2019).

    Article 
    ADS 
    CAS 

    Google Scholar
     

  • Van Landuyt, J., Hatwell, H. & Amelinckx, S. The domain structure of β-In2S3 ‘single crystals’ due to the ordering of indium vacancies. Mater. Res. Bull. 3, 519–528 (1968).

    Article 

    Google Scholar
     

  • Van Landuyt, J. & Amelinckx, S. Antiphase boundaries and twins associated with ordering of indium vacancies in β-In2S3. Phys. Status Solidi B Basic Solid State Phys. 31, 589–600 (1969).

    Article 
    ADS 

    Google Scholar
     

  • Chen, P. J. & Montgomery, S. T. A macroscopic theory for the existence of the hysteresis and butterfly loops in ferroelectricity. Ferroelectrics 23, 199–207 (1980).

    Article 
    ADS 
    CAS 

    Google Scholar
     

  • Modi, G., Stach, E. A. & Agarwal, R. Low-power switching through disorder and carrier localization in bismuth-doped germanium telluride phase change memory nanowires. ACS Nano 14, 2162–2171 (2020).

    Article 
    CAS 
    PubMed 

    Google Scholar
     

  • Modi, G. et al. Controlled self-assembly of nanoscale superstructures in phase-change Ge–Sb–Te nanowires. Nano Lett. 24, 5799–5807 (2024).

    Article 
    ADS 
    CAS 
    PubMed 

    Google Scholar
     

  • Yan, Z. H., Klassen, T., Michaelsen, C., Oehring, M. & Bormann, R. Inverse melting in the Ti-Cr system. Phys. Rev. B 47, 8520–8527 (1993).

    Article 
    ADS 
    CAS 

    Google Scholar
     

  • Li, W., Qian, X. & Li, J. Phase transitions in 2D materials. Nat. Rev. Mater. 6, 829–846 (2021).

    Article 
    ADS 
    CAS 

    Google Scholar
     

  • Matzen, S. et al. Super switching and control of in-plane ferroelectric nanodomains in strained thin films. Nat. Commun. 5, 4415 (2014).

    Article 
    ADS 
    CAS 
    PubMed 

    Google Scholar
     

  • Gao, P. et al. Revealing the role of defects in ferroelectric switching with atomic resolution. Nat. Commun. 2, 591 (2011).

    Article 
    ADS 
    PubMed 

    Google Scholar
     

  • Fu, H. & Cohen, R. E. Polarization rotation mechanism for ultrahigh electromechanical response. Nature 403, 281–283 (2000).

    Article 
    ADS 
    CAS 
    PubMed 

    Google Scholar
     

  • Salje, E. K. H., Wang, X., Ding, X. & Scott, J. F. Ultrafast switching in avalanche-driven ferroelectrics by supersonic kink movements. Adv. Funct. Mater. 27, 1700367 (2017).

    Article 

    Google Scholar
     

  • Sui, F. et al. Atomic-level polarization reversal in sliding ferroelectric semiconductors. Nat. Commun. 15, 3799 (2024).

    Article 
    ADS 
    CAS 
    PubMed 
    PubMed Central 

    Google Scholar
     

  • Nord, M., Vullum, P. E., MacLaren, I., Tybell, T. & Holmestad, R. Atomap: a new software tool for the automated analysis of atomic resolution images using two-dimensional Gaussian fitting. Adv. Struct. Chem. Imaging 3, 9 (2017).

  • Takamoto, S. et al. Towards universal neural network potential for material discovery applicable to arbitrary combination of 45 elements. Nat. Commun. 131, 2991 (2022).

    Article 
    ADS 

    Google Scholar
     

  • Takamoto, S., Okanohara, D., Li, Q. J. & Li, J. Towards universal neural network interatomic potential. J. Mater. 9, 447–454 (2023).


    Google Scholar
     

  • Kresse, G. & Joubert, D. From ultrasoft pseudopotentials to the projector augmented-wave method. Phys. Rev. B 59, 1758 (1999).

    Article 
    ADS 
    CAS 

    Google Scholar
     

  • Perdew, J. P., Burke, K. & Ernzerhof, M. Generalized gradient approximation made simple. Phys. Rev. Lett. 77, 3865 (1996).

    Article 
    ADS 
    CAS 
    PubMed 

    Google Scholar
     

  • Kresse, G. & Hafner, J. Ab initio molecular dynamics for liquid metals. Phys. Rev. B 47, 558 (1993).

    Article 
    ADS 
    CAS 

    Google Scholar
     

  • Kresse, G. & Furthmüller, J. Efficient iterative schemes for ab initio total-energy calculations using a plane-wave basis set. Phys. Rev. B 54, 11169 (1996).

    Article 
    ADS 
    CAS 

    Google Scholar
     

  • Henkelman, G., Uberuaga, B. P. & Jónsson, H. A climbing image nudged elastic band method for finding saddle points and minimum energy paths. J. Chem. Phys. 113, 9901–9904 (2000).

    Article 
    ADS 
    CAS 

    Google Scholar
     

  • RELATED ARTICLES

    Most Popular

    Recent Comments