Metallization of colloidal crystals

Colloidal crystals formed by size-asymmetric binary particles co-assemble into a wide variety of colloidal compounds with lattices akin to ionic crystals. Recently, a transition from a compound phase with a sublattice of small particles to a metal-like phase in which the small particles are delocalized has been predicted computationally and observed experimentally. In this colloidal metallic phase, the small particles roam the crystal maintaining the integrity of the lattice of large particles, as electrons do in metals. A similar transition also occurs in superionic crystals, termed sublattice melting. Here, we use energetic principles and a generalized molecular dynamics model of a binary system of functionalized nanoparticles to analyze the transition to sublattice delocalization in different co-assembled crystal phases as a function of T, number of grafted chains on the small particles, and number ratio between the small and large particles $n_s$:$n_l$. We find that $n_s$:$n_l$ is the primary determinant of crystal type due to energetic interactions and interstitial site filling, while the number of grafted chains per small particle determines the stability of these crystals. We observe first-order sublattice delocalization transitions as T increases, in which the host lattice transforms from low- to high-symmetry crystal structures, including A20 to BCT to BCC, Ad to BCT to BCC, and BCC to BCC/FCC to FCC transitions and lattices. Analogous sublattice transitions driven primarily by lattice vibrations have been seen in some atomic materials exhibiting an insulator-metal transition also referred to as metallization. We also find minima in the lattice vibrations and diffusion coefficient of small particles as a function of $n_s$:$n_l$, indicating enhanced stability of certain crystal structures for $n_s$:$n_l$ values that form compounds.

[1]  A. Travesset,et al.  Perovskite-type superlattices from lead halide perovskite nanocubes , 2021, Nature.

[2]  J. Teng,et al.  From colloidal particles to photonic crystals: advances in self-assembly and their emerging applications. , 2021, Chemical Society reviews.

[3]  C. Mirkin,et al.  Electron-Equivalent Valency through Molecularly Well-Defined Multivalent DNA. , 2021, Journal of the American Chemical Society.

[4]  M. Olvera de la Cruz,et al.  Delocalization Transition in Colloidal Crystals , 2020, 2011.01347.

[5]  G. Yi,et al.  Colloidal diamond , 2020, Nature.

[6]  P. Perdikaris,et al.  Hydrodynamic and frictional modulation of deformations in switchable colloidal crystallites , 2020, Proceedings of the National Academy of Sciences.

[7]  C. Gehrmann,et al.  Anharmonic host-lattice dynamics enable fast ion conduction in superionic AgI , 2019, 1911.07492.

[8]  M. Olvera de la Cruz,et al.  Sublattice melting in binary superionic colloidal crystals. , 2019, Physical review. E.

[9]  Tristan Bereau,et al.  Hoobas: A highly object-oriented builder for molecular dynamics , 2019, Computational Materials Science.

[10]  C. Mirkin,et al.  Particle analogs of electrons in colloidal crystals , 2019, Science.

[11]  Sharon C. Glotzer,et al.  freud: A Software Suite for High Throughput Analysis of Particle Simulation Data , 2019, Comput. Phys. Commun..

[12]  F. Smallenburg,et al.  Diffusion and interactions of interstitials in hard-sphere interstitial solid solutions. , 2017, The Journal of chemical physics.

[13]  A. Travesset Nanoparticle Superlattices as Quasi-Frank-Kasper Phases. , 2017, Physical review letters.

[14]  Robert M. Hanson,et al.  The AFLOW Library of Crystallographic Prototypes: Part 2 , 2018, Computational Materials Science.

[15]  D. Weitz,et al.  Direct Observation of Entropic Stabilization of bcc Crystals Near Melting. , 2017, Physical review letters.

[16]  R. Higler,et al.  Anomalous dynamics of interstitial dopants in soft crystals , 2016, Proceedings of the National Academy of Sciences.

[17]  S. Schmidt,et al.  Robust structural identification via polyhedral template matching , 2016, 1603.05143.

[18]  S. Ong,et al.  Design principles for solid-state lithium superionic conductors. , 2015, Nature materials.

[19]  Kevin G Yager,et al.  Superlattices assembled through shape-induced directional binding , 2015, Nature Communications.

[20]  John D. Budai,et al.  Metallization of vanadium dioxide driven by large phonon entropy , 2014, Nature.

[21]  Chad A. Mirkin,et al.  DNA-mediated nanoparticle crystallization into Wulff polyhedra , 2013, Nature.

[22]  Bartosz A. Grzybowski,et al.  Colloidal assembly directed by virtual magnetic moulds , 2013, Nature.

[23]  Sharon C. Glotzer,et al.  HOOMD-blue: A Python package for high-performance molecular dynamics and hard particle Monte Carlo simulations , 2013 .

[24]  G. Yi,et al.  Recent progress on patchy colloids and their self-assembly , 2013, Journal of physics. Condensed matter : an Institute of Physics journal.

[25]  Anubhav Jain,et al.  Python Materials Genomics (pymatgen): A robust, open-source python library for materials analysis , 2012 .

[26]  M. Dijkstra,et al.  Self-assembly of a colloidal interstitial solid with tunable sublattice doping. , 2011, Physical review letters.

[27]  Oliver Beckstein,et al.  MDAnalysis: A toolkit for the analysis of molecular dynamics simulations , 2011, J. Comput. Chem..

[28]  T. Ishida Molecular dynamics study of the dynamical behavior in ionic liquids through interionic interactions , 2011 .

[29]  Gaël Varoquaux,et al.  Mayavi: 3D Visualization of Scientific Data , 2010, Computing in Science & Engineering.

[30]  Dmitri V Talapin,et al.  Energetic and entropic contributions to self-assembly of binary nanocrystal superlattices: temperature as the structure-directing factor. , 2010, Journal of the American Chemical Society.

[31]  Laura Filion,et al.  Prediction of binary hard-sphere crystal structures. , 2009, Physical review. E, Statistical, nonlinear, and soft matter physics.

[32]  S. Sacanna,et al.  Lock and key colloids , 2009, Nature.

[33]  Joshua A. Anderson,et al.  General purpose molecular dynamics simulations fully implemented on graphics processing units , 2008, J. Comput. Phys..

[34]  Christopher B. Murray,et al.  Structural diversity in binary nanoparticle superlattices , 2006, Nature.

[35]  C. Patrick Royall,et al.  Ionic colloidal crystals of oppositely charged particles , 2005, Nature.

[36]  S. Hull,et al.  Superionics: crystal structures and conduction processes , 2004 .

[37]  U. Pinsook Molecular dynamics study of vibrational entropy in bcc and hcp zirconium , 2002 .

[38]  A. Verdaguer,et al.  Computer simulation study of the velocity cross correlations between neighboring atoms in simple liquid binary mixtures , 2001 .

[39]  A. Verdaguer,et al.  MOLECULAR DYNAMICS STUDY OF THE VELOCITY CROSS-CORRELATIONS IN LIQUIDS , 1998 .

[40]  Arjun G. Yodh,et al.  Self-assembly of colloidal crystals , 1998 .

[41]  D. Frenkel,et al.  Entropy-driven formation of a superlattice in a hard-sphere binary mixture , 1993, Nature.

[42]  W. Schommers Structure and dynamics of superionic conductors , 1980 .

[43]  J. McTague,et al.  Should All Crystals Be bcc? Landau Theory of Solidification and Crystal Nucleation , 1978 .

[44]  W. Schommers Correlations in the Motion of Particles inα-AgI: A Molecular-Dynamics Study , 1977 .

[45]  J. M. Dickey,et al.  Computer Simulation of the Lattice Dynamics of Solids , 1969 .

[46]  Oliver Beckstein,et al.  MDAnalysis: A Python Package for the Rapid Analysis of Molecular Dynamics Simulations , 2016, SciPy.

[47]  A. Stukowski Modelling and Simulation in Materials Science and Engineering Visualization and analysis of atomistic simulation data with OVITO – the Open Visualization Tool , 2009 .

[48]  H. Hees,et al.  Statistical Physics , 2004 .

[49]  M. Salamon Physics of superionic conductors , 1979 .