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Monte-Carlo simulations of the structure of complex liquids with various interaction potentials Alja ž Godec Advisers: prof. dr. Janko Jamnik and doc. dr. Franci Merzel National Institute of Chemistry
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Contents 1. Introduction 2. Statistical mechanics of complex liquids 3. Spherical multipole expansion of the electrostatic interaction energy 4. Monte-Carlo simulations of ensembles of anisotropic particles 5. How to present the results of MC simulations? 6. Conclusions and considerations for future work
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Introduction What are complex liquids? simple liquid anisotropic particles, COMPLEX POTENTIALS hard spheres, Lennard-Jones particles- SIMPLE ISOTROPIC POTENTIALS Importance of complex liquids? ≈ ρ vapour ρ bulk complex liquid ΔF= ΔU-TΔS ΔU = 0 ΔU > 0 Hydrophobic interactions
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Introduction ≈ ρ vapour ρ bulk S hard sphere in LJ fluid S Angular correlations completely ignored!!
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Statistical mechanics of complex liquids Assumption: separable Hamiltonian (intermolecular interactions have no effect on the quantum states) H=H class +H quant two sets of independent quantum states (i.e. eigenstates can be taken as a product) with energy E n =E n cl +E n qu The partition function factorises Q = Q cl Q qu and individual molecular energy Consequence of the above assumption: the contributions of quantum coordinates to physical properties are independent of density classical: centre of mass and the external rotational degrees of freedom quantum mechanical vibrational and internal rotational degrees of freedom
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Statistical mechanics of complex liquids Probability density for the classical states The classical Hamiltonian can be split into kinetic and potential energy H=K t +K r +U ( r N ω N ) IαIα In Monte-Carlo calculations we need only the configurational probability density, but we introduce a new distribution P ' ( r N p N ω N J N )
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Statistical mechanics of complex liquids new probability density it is convinient to introduce a new distribution P ( r N p N ω N J N ) We can write
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Statistical mechanics of complex liquids We can now directly factorize the p s and J s of different molecules are uncorrelated furthermore thus we can directly integrate Λ t =h/(2πmkT) 1/2 Λ r =(h/(8π 2 I x kT) 1/2 )× (h/(8π 2 I y kT) 1/2 )(h/(8π 2 I z kT) 1/2 ) Ω = 8 π 2 ( 4 π )
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Spherical multipole expansion of the electrostatic interaction energy electrostatic interaction a molceule= a distribution of charges (placed in the atomic centres); Atoms have finite sizes and also interact with polarization interactions electrostatic interaction between two molceules= interaction between two charge distributions spherical harmonic expansion of r 12 -1 =|r+r 2 -r 1 | -1 Pair potential energy: dispersion polarisation exchange repulsion (finite size of atom) z y x r · · q1q1 q2q2 r1r1 r2r2 potential of a charge distribution:
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Spherical multipole expansion of the electrostatic interaction energy m th component of the spherical multipole moment of order l : interaction between two charge distributions= ∑ ( interactions of components of multipole moments of charge distributions) z y x r Introduction of body-fixed coordinate frame: x’ z’ y’ z y x x’ z’ y’ x’ z’ y’ Ω
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z’’ y’’ x’’ x’ z’ Spherical multipole expansion of the electrostatic interaction energy z y x y’ r · · q1q1 q2q2 r1r1 r2r2 xyz: space-fixed x’y’z’ and x’’y’’z’’: body-fixed calculated only once What is gained? example: molecule consisting of four charges 17 terms /pair 5 (10) terms /pair Spherical multipole expansion TIP5P water model Relation between multipole moments in the space-fixed and body-fixed coordinate frames:
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Monte-Carlo simulations of ensembles of anisotropic particles What do we do in a MC calculation? P ( x )... probability density function Monte-Carlo: perform a number of trials τ : in each trial choose a random number ζ from P ( x ) in the interval (x 1,x 2 ) How to choose P in a way, which allows the function evaluation to be concentrated in the region of space that makes importatnt contributions to the integral? Construction of P ( x ) by Metropolis algorithm generates a Markov chain of states 1. outcome of each trial depends only upon the preceding trial 2. each trial belongs to a finite set of possible outcomes
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Monte-Carlo simulations of ensembles of anisotropic particles a state of the system m is characterized by positions and orientations of all molecules probability of moving from m to n = π mn N possible states π mn constitute a N×N matrix, π each row of π sums to 1 probability that the system is in a particular state is given by the probability vector ρ =( ρ 1, ρ 2, ρ 3,..., ρ m, ρ n,..., ρ N ) probability of the initial state = ρ(1) equilibrium distribution Microscopic reversibility (detailed balance): Metropolis:
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Monte-Carlo simulations of ensembles of anisotropic particles How to accept trial moves? Metropolis: - allways accept if U new ≤ U old - if U new > U old choose a random number ζ from the interval [0,1] 0 1 exp(-βΔU) U new -U old ΔU nm ζ 1ζ 1 ζ 2ζ 2 × × allways accept accept reject How to generate trial moves? translation rotation How many particles should be moved? sampling efficiency: ~kT reasonable acceptance 1. N particles, one at a time: CPU time ~ nN 2. N particles in one move: CPU time ~ nN sampling efficiency down by a factor 1/N
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Monte-Carlo simulations of ensembles of anisotropic particles How to represent results (especially angular correlations)? we introduce a generic distribution function: we further introduce a reduced generic distribution function: ideal gas: homogenous isotropic fluid:
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How to present the results of MC simulations? generally: pair correlation function: spherical harmonic expansion of the pair correlation function in a space fixed frame: δ ( ω )= δ ( φ ) δ (cos θ ) δ ( χ ) linear molecules: intermolecular frame ω = 0 φ : angular correlation function, g ( r h ω h ) :
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removing the m dependence: reconstruction EXAMPLE: dipoles in LJ spheres r φ θ2θ2 How to present the results of MC simulations?
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Conclusions and considerations for the future - we have briefly reviewed the statistical mechanics of complex liquids - in order to reduce the number of interaction terms that have to be evaluated in each simulation step a spherical multipole expansion of the electrostatic interaction energy was made - the basics of the Monte-Carlo method for simulation of ensembles of anisotropic particles were provided along with useful methods for representing the results of such simulations. - finally results of MC simulations of dipoles embedded in Lennard- Jones spheres were briefly presented. - employ such simulations to study biophysical processes, such as the hydrophobic effect - possibility of including polarization effects basis for developing a polarizable water model for biomolecular simulations
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