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Title: Theory and Modeling of Rare Events


1
Theory and Modeling of
Rare Events
  • Weinan E
  • Princeton University
  • Joint work with Weiqing Ren and
  • Eric Vanden-Eijnden (Courant Inst, New York
    University)
  • Supported by ONR

2
Problem Conformational change of biomolecules
in explicit solvent, at room temperature
?
3
Time history of torsion angles (in vacuum)
Conformational changes are rare events. This is a
multi-time-scale problem.
4
Rare events are of general interest
  • Conformational changes of biomolecules
  • Chemical reactions
  • Nucleation events
  • ? ? ? ? ? ?
  • Transition caused by very small thermal noise.

5
What do we want to know?
  • Transition pathways, bottlenecks,
  • Transition mechanism.
  • Transition rates

6
Plan for the talk
  • Theoretical foundation
  • Numerical modeling
  • Two different situations
  • Classical case Simple energy landscape
  • Complex systems Rough energy landscape

7
Two different situations
Complex
Simple
8
Consider the following (frictional) dynamics
Issues of dynamics Most results can be
extended to Langevin dynamics. Many issues
for Hamiltonian (NVE) dynamics remain open.
9
Simple system Transition state theory
(H. Eyring, E. Wigner, H. Kramers, 1930-40)
  • Identify transition state (saddle point)
  • Compute rates by harmonic approximation

Extended to higher dimensions
10
Transition State Theory Extensions
  • Dividing surfaces, replace saddle points
  • Variational TST optimal dividing surfaces
  • Transmission coefficients (re-crossing issue)

11
Pathways Minimum energy path (MEP)
  • When transition involves several saddle points
    and intermediate states, identify the relevant
    sequence of saddle points.

This is also the most probable path
(consequence of path integral formalism).
12
Langevin equation
13
Once we know MEP
  • Go back to TST with harmonic approximation
  • Use MEP as a local reaction coordinate,
  • to obtain a one-dimensional reduction
  • (compute potential of mean force, etc),
  • then use Kramers theory to obtain rates.

14
Complex systems Rough energy landscapes
  • Saddle points, MEP are not the right object.
  • No single most probable path. Many paths
    contribute.
  • Notion of transition state needs to be extended.

15
Two dimensional rough energy landscapeResults
of finite temperature string method
16
How do we describe transition over rough energy
landscapes?
Metastability related to existence of spectral
gap for L
Transition rates
17
Reaction coordinate q(x) cst. gives a
foliation of configuration space
Foliation family of non-intersecting surfaces
that fill up
space.
Importance of choosing the right reaction
coordinate (Bolhuis, Chandler, Dellago,
Geissler,
Transition path sampling (TPS)).
18
A distinguished reaction coordinate
The committor function q(x) (TPS)
  • level sets q(x) cst iso-committor surfaces

19
Analytical characterization
Simple mathematical characterization
Backward Kolmogorov equation
Where
This is a very high dimensional problem. Compare
with quantum many-body problem.
20
Characterization of iso-committor surfaces
Hitting point distribution for reactive
trajectories Hitting point distribution for
all trajectories Equilibrium distribution
restricted to the surfaces
21
Localization assumption
Equilibrium distribution on iso-committor
surface are peaked (localized).
Definition Transition tube -- connecting these
peaked distributions
This is the object of interest!
22
Alternative Variational formulation for
committor function q(x)
  • We are only interested in the iso-committor
    surfaces around the
  • transition tube.
  • Locally, we can approximate the iso-committor
    surfaces there by
  • hyper-planes.
  • The variational problem then simplifies
    dramatically.
  • (choosing special test functions)
  • Use these to reduce the many-body problem
  • to coupled
    one-body problem!

23
Finite-temperature string method (FTS)
  • 1. parametrizing the family of hyperplanes by
    strings
  • (center of mass) or by their normals

2. evolution of the string sampling
24
Dynamics of the string
Sampling on the hyper-planes e. g.
25
Calculation of the free energy
Value of the committor function
Connection with the variational problem
26
Transition state ensemble
27
Example Two dimensional rough energy landscape
28
Example Isomerization of alanine dipeptide
in vacuum, and in
explicit solvent
  • (in collaboration with Paul Maragakis, M.
    Karplus)
  • Simple system which exhibits generic features
    common to more complex biomolecules.
  • Conformation state described by torsion angles
    but mechanism of transition unknown before string
    method (transition state region? role of solvent?)

29
Actual conformation change
Two conformation states
microtime 1 fs
time per transition 1ps
time between transitions 1-10 ns
30
Transition path identified by string method
Two conformation states
mean string
31
Projection of the transition tube on the torsion
angle map
32
Projection of Transition state region
33
Free energy and committor function

34
Center of the transition tube (black
curve) Transition state region (red dots) Color
lines actual trajectories (stay confined in
tube)
35
Checking the result Computing the
committor distribution (operational
definition of committor)
Committer distribution (peaked at 1/2 for the
transition region)
36
Alanine dipeptide with explicit solvent
37
Alanine dipeptide with explicit solvent
38
Committor distribution for the transition state
region
39
Martensitic phase transformation
40
Two stable configurations
41
Dynamics suggested by mean string
42
Phase transformed by Twinn boundary propagation
43
Propagation of twin dislocation inside the twinn
boundary
44
Mean potential energy along the path
45
Special case T0, Zero-temperature
string method (ZTS)
Transition tube ? Minimum energy path
?
Connection with nudged elastic band
46
Example Mueller potential
47
Comparison with nudged elastic band
(Jonsson et al) LEPS potential
48
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49
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50
Summary 1. Conceptually
  • Saddle points (isolated transition states)
  • ? dividing surfaces
  • ? foliation
  • Minimum energy path (isolated transition path)
  • ? transition tube A distribution in the
    state
  • space connecting the reactant and
    product
  • states, and tells us where the reactive
  • trajectories are.

51
Committor functions and
iso-committor surfaces
  • Operational viewpoint (as in TPS)
  • launch trajectories and count them
  • Analytical viewpoint (as in FTS)
  • Backward Kolmogorov equation or
    variational
  • problem, in very high dimensional space
  • Localization assumption allows us to reduce the
    many-body problem to coupled one-body
    problem.

52
2. String method for computing transition
pathways and rates
  • Zero-T string method (ZTS) for simple systems
  • Finite-T string method (FTS) for complex
    systems, and when entropic effects are important.

A bridge between NEB and TPS
Adaptive blue moon sampling
53
3. Advertising
Tutorial, references, sample codes available at
www.math.princeton.edu/string
Mathematics and Chemistry A year-long special
program at IMA, Univ. of Minnesota,
2008-2009. Organizers Don Truhlar, Anne Chaka,
Weinan E, Bill Hase, Claude Le Bris and Tamar
Schlick.
54
Example
  • Rotation of aromatic ring of Tyr 35 in BPTI
  • (Bovine Pancreatic Trypsin Inhibitor)
  • computed by Paul Maragakis (Harvard)
  • Ring flipping time scale 0.1 1 s
  • (compare with time scale for atomic
    vibration
  • 1 fs 10-15 s)
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