How do Monte Carlo and molecular dynamics differ?

Monte Carlo samples configurations stochastically without real time or dynamics, while molecular dynamics generates a time-ordered trajectory; both can yield equilibrium averages, but only dynamics gives time-dependent properties.

Why is computing free energy difficult?

Free energy depends on the full volume of accessible phase space rather than the lowest-energy configuration, so it requires careful, well-converged sampling and specialized estimators.

Monte Carlo and Free-Energy Methods

Monte Carlo methods sample configurations stochastically, and free-energy techniques built upon them compute the thermodynamic quantities that govern binding, solubility, and equilibrium.

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Definition

Stochastic configurational sampling methods and the free-energy estimators derived from them, used to compute thermodynamic free-energy differences in molecular systems.

Scope

Covers Metropolis Monte Carlo sampling, importance sampling and detailed balance, and the principal free-energy techniques: free-energy perturbation, thermodynamic integration, umbrella sampling, and enhanced-sampling approaches that overcome high barriers. Emphasizes the computation of relative and absolute free energies of practical interest.

Core questions

How does Metropolis sampling generate configurations with the correct Boltzmann weights?
Why is free energy harder to compute than energy, and how do perturbation and integration methods address this?
How does umbrella sampling recover free-energy profiles across barriers?
What strategies enhance sampling of rare events?

Key theories

Metropolis sampling: Accepts or rejects trial moves with a probability satisfying detailed balance so that the generated configurations follow the Boltzmann distribution, enabling unbiased thermodynamic averaging.
Free-energy perturbation: Expresses the free-energy difference between two states as an ensemble average of an exponential energy difference, the foundation of alchemical free-energy calculations.

Clinical relevance

Free-energy methods underpin quantitative prediction of binding affinities, solvation free energies, and partition coefficients, making them central to computational drug discovery and physical property estimation.

History

The 1953 Metropolis algorithm introduced importance-sampling Monte Carlo; Zwanzig's 1954 perturbation formula and later thermodynamic-integration and umbrella-sampling schemes built the modern free-energy toolkit now standard in molecular simulation.

Key figures

Nicholas Metropolis
Marshall Rosenbluth
Robert Zwanzig
Daan Frenkel

Seminal works

metropolis1953
zwanzig1954

Frequently asked questions

How do Monte Carlo and molecular dynamics differ?: Monte Carlo samples configurations stochastically without real time or dynamics, while molecular dynamics generates a time-ordered trajectory; both can yield equilibrium averages, but only dynamics gives time-dependent properties.
Why is computing free energy difficult?: Free energy depends on the full volume of accessible phase space rather than the lowest-energy configuration, so it requires careful, well-converged sampling and specialized estimators.