(Crystal) Nucleation: The language

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Why crystallization requires supercooling (Crystal) Nucleation: The language 2r 1. Transferring N particles from liquid to crystal yields energy. Crystal nucleus Δµ: thermodynamic driving force N is proportional to the VOLUME of the crystal (i.e. to r 3 ) Why crystallization requires supercooling 1. But it costs energy to make a surface area S. ΔG tot * ~ r 2 ΔG ~ -r 3 Crystal nucleus 2r γ: surface tension 0 r r c S is proportional to the SURFACE of the crystal (i.e. to r 2 ) 1

Crystallization of NaCl from melt Computing absolute nucleation rates NaCl 10 27 m -3 s -1 10 24 m -3 s -1 All experimental points (1) 10 21 m -3 s -1 10 18 m -3 s -1 Other example: hard sphere colloids. 10 15 m -3 s -1 Computed nucleation rate of Tosi-Fumi NaCl 800K 900K 1000K 2

Crystal nucleation of hard-sphere colloids NUCLEATION BARRIER SIMULATION RESULTS Equilibrium phase behavior: Pusey and van Megen Nature 320 340 (1986) 1 Nucleus / (month cm 3 ) Nucleation RATES Discrepancy: >20 orders of magnitude. Experiments Simulations Log 10 (I) Nucleation Rate depends strongly on strength and range of repulsion (lower γ) 8 10 12 14 16 18 20 22 0.8 Longer ranged repulsion HS κ=10 κ=5 κ=3.33333 24 0.1 0.2 0.3 0.4 0.5 0.6 µ γ [kt/σ 2 ] 0.7 0.6 0.5 0.4 Hard core + Yukawa ( screened Coulomb ) interaction Hard-Sphere κ=10 (FCC) κ=10 (BCC) κ=5 (FCC) κ=5 (BCC) κ=3.33333 (FCC) 0.3 0.1 0.2 0.3 0.4 0.5 0.6 µ [kt] 3

Effect of a flat wall on nucleation CNT: But of course - crystal nucleation is HETEROGENEOUS with: Homogeneous nucleation barrier: ΔG = 1334 kt The effect of surface free energy: ΔG Observation: γ Solid-Liquid Heterogeneous nucleation barrier: ΔG = 17 kt Flat wall speeds up nucleation by a factor 10 570 That is why homogeneous nucleation is the exception is about one order of magnitude smaller than γ Solid-Vapour 4

03/08/2012 Therefore: this this Consequence: is easier than T F + F S Protein crystallization conditions `two-step nucleation is plausible Seeded nucleation? Tc F+F Protein concentration 5

Seeded Crystallization RANDOM (!) SUBSTRATES CAN ACT AS UNIVERSAL NUCLEATION SEEDS (Experiments: Naomi Chayen, Imperial College) If the crystal fits well on the template, it is easy to nucleate however: Figure 1: Electron micrograph of micro-porous silicon (left) shows that the sample contains a network of pores with sizes between 5 and 10 nanometers. The figure on the right hand shows a number of protein crystals (phycobili protein) that have formed on the micro-porous silicon. (N.E. Chayen et al., Ref.. [1]) Explanation (Richard Sear) For every Cinderella there is a shoe that fits Theory: Richard Sear D. Frenkel, NATURE, 443, 641, 2006 6

But this is not the whole story. h I II T Fluid T c F + S Solid Hard particles with SHORT- RANGED attraction ΔG 0 < 0 > 0 II ΔG ρ Liquid may form a wetting layer Metastable fluid-fluid h I In this regime, the dense liquid may wet walls Study crystal nucleation in a regime where the bulk liquid is not even metastable Wetting layer in large pore 7

03/08/2012 In this regime, the dense liquid may wet walls Capillary condensation in small pore Crystal nucleation in filled pore Disordered substrate yields perfect crystal that nucleates in wetting layer. J. A. van Meel, R. P. Sear and DF, Phys. Rev. Lett. 105, 205501 (2010) Which illustrates that: Beyond Newtonian dynamics: this this 1. Langevin dynamics 2. Brownian dynamics 3. Stokesian dynamics 4. Dissipative particle dynamics is easier than 5. Stochastic rotation/multi-particle collision dynamics 6. Lattice Boltzmann 7. Etc. etc. 8

Saving time. These algorithms are often used to simulate molecular motion in a viscous medium, without solving the equations of motion for the solvent particles. Friction force First, consider motion with friction alone: Conservative force There is a relation between the correlation function of the random force and the friction coefficient: After a short while, all particles will stop moving, due to the friction.. random force Better: The derivation is straightforward, but beyond the scope of this lecture. The KEY point is that the friction force and the random force ARE RELATED. 9

Generalizsed Langevin Equation Laplace transform Limiting case of Langevin dynamics: No inertial effects (m=0) Becomes: Brownian Dynamics Fluctuation- Dissipation (But still the friction force and the random force are related) What is missing in Langevin dynamics and Brownian dynamics? Is this serious? 1. Momentum conservation 2. Hydrodynamics Not always: it depends on the time scales. Momentum diffuses away in a time L 2 /ν. After that time, a Brownian picture is OK. (1 implies 2). However: hydrodynamics makes that the friction constant depends on the positions of all particles (and so do the random forces ). 10

Momentum conserving, coarse-grained schemes: Recursive sampling Dissipative particle dynamics Stochastic Rotation Dynamics/Multi-particle collision dynamics Lattice-Boltzmann simulations These schemes represent the solvent explicitly (i.e. as particles), but in a highly simplified way. Outline: 1. Recursive enumeration a) Polymer statistics (simulation) b).. 2. Molecular Motors (experiments!) (well, actually, simulated experiments) Lattice polymers: 11

12

This method is exact for non-self-avoiding, noninteracting lattice polymers. It can be used to speed up MC sampling of (self)interacting polymers B. Bozorgui and DF, Phys. Rev. E 75, 036708 (2007)) NOTE: `MFOLD also uses recursive sampling to predict RNA secondary structures. Recursive analysis of Molecular Motors Kinesin motor steps along micro-tubules with a step size of 8nm 13

Example: noisy synthetic data Experimentally, the step size is measured by fitting the (noisy) data. Example: noisy synthetic data Best practice: fit steps to data : true trace J.W.J. Kerssemakers et al., Nature 442,709 (2006) 14

How well does it perform? 1. It can be used if the noise is less than 60% of the step size. 2. It yields a distribution of step sizes (even if the underlying process has only one step size) Observation: We want to know the step size and the step frequency but We do not care which trace is the correct trace. Bayesian approach: compute the partition function Q of nonreversing polymer in a rough potential energy landscape As shown before: we can enumerate Q exactly (and cheaply). From Q we can compute a free energy true trace Other directed walks 15

Compute the excess free energy with respect to reference data What have we learned? 1. What is Soft Matter? 16

Time to stop! 17

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