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Title: Srinivasan S. Iyengar

1
Atom-centered Density Matrix Propagation (ADMP)
Theory and Applications

Srinivasan S. Iyengar
Department of Chemistry and Department of
Physics,
Indiana University

2
Outline

Brief discussion of ab initio molecular dynamics
Atom-centered Density Matrix Propagation (ADMP)
Nut-n-bolts issues
Some Results
Novel findings for protonated water clusters
QM/MM generalizations ion channels
Gas phase reaction dynamics

3
Molecular dynamics on a single potential surface

Parameterized force fields (e.g. AMBER, CHARMM)
Energy, forces parameters obtained from
experiment
Molecular motion Newtons laws
Works for large systems
But hard to parameterize bond-breaking/formation
(chemical reactions)
Issues with polarization/charge
transfer/dynamical effects
Born-Oppenheimer (BO) Dynamics
Solve electronic Schrödinger eqn (DFT/HF/post-HF)
for each nuclear structure
Nuclei propagated using gradients of energy
(forces)
Works for bond-breaking but computationally
expensive
Large reactive, polarizable systems Something
like BO, but preferably less expensive.

4
Extended Lagrangian dynamics

Circumvent Computational Bottleneck of BO
Avoid repeated SCF electronic structure, not
converged, but propagated
Simultaneous propagation of electronic
structure and nuclei adjustment of time-scales
Car-Parrinello (CP) method
Orbitals expanded in plane waves
Occupied orbital coefficients propagated
O(N3) computational scaling (traditionally)
O(N) with more recent Wannier representations (?)
Atom-centered Density Matrix Propagation (ADMP)
Atom-centered Gaussian basis functions
Electronic Density Matrix propagated
Asymptotic linear-scaling with system size
Allows the use of accurate hybrid density
functionals
suitable for clusters

5
Atom-centered Density Matrix Propagation (ADMP)

Construct a classical phase-space
R,V,M,P,W,m
The Lagrangian ( Kinetic minus Potential energy)

P represented using atom-centered gaussian
basis sets

6
Euler-Lagrange equations of motion for ADMP

Equations of motion for density matrix and nuclei

Classical dynamics in R,V,M,P,W,m phase
space
Next few slide Forces, propagation equations,
formal error analysis

7
Nuclear Forces What Really makes it work
8
Density Matrix Forces

Use McWeeny Purified DM (3P2-2P3) in energy
expression to obtain

9
m effects an adjustment of time-scales

Bounds for m From a Hamiltonian formalism
m also related to deviations from the BO surface

10
Physical interpretation of m Bounds

Magnitude of m represents deviation from BO
surface
m acts as an adiabatic control parameter

11
Bounds on the magnitude of m
Controlling m Deviations from BO surface and
adiabaticity
12
Comparison with BO dynamics

Born-Oppenheimer dynamics
Converged electronic states.
Approx. 8-12 SCF cycles / nuclear config.
dE/dR not same in both methods

ADMP
Electronic state propagated classically no
convergence reqd.
1 SCF cycle for Fock matrix -gt dE/dP
Current 3-4 times faster.

References
Iyengar et al. Israel J. Chem. 7, 191, (2002).
Schlegel et al. JCP 114, 8694 (2002). Iyengar
and Frisch JCP 121, 5061 (2004).
13
Propagation of P time-reversible propagation

Velocity Verlet propagation of P

Classical dynamics in R,V,P,W phase space
Li and Li1 obtained iteratively
Conditions Pi1 2 Pi1 and WiPi PiWi Wi
(next two slides)

14
Idempotency (N-Representibility of DM)

Given Pi2 Pi, need Li to find idempotent Pi1
Solve iteratively Pi12 Pi1
Given Pi, Pi1, Wi, Wi1/2, need Li1 to find
Wi1
Solve iteratively Wi1 Pi1 Pi1 Wi1 Wi1

15
Idempotency To obtain Pi1

Given Pi2 Pi, need to find indempotent Pi1
Guess
Or guess
Iterate Pi1 to satisfy Pi12 Pi1
Rational for choice PiTPi QiTQi above

16
Idempotency To obtain Wi1

Given WiPi PiWi Wi, find appropriate Wi1
Guess
Iterate Wi1 to satisfy Wi1Pi1 Pi1Wi1
Wi1

17
How it all works

Initial config. R(0). Converged SCF P(0)
Initial velocities V(0) and W(0) flexible
P(Dt), W(Dt) from analytical gradients and
idempotency
Similarly for R(Dt)
And the loop continues

18
Protonated Water Clusters

Important systems for
Ion transport in biological and condensed systems
Enzyme kinetics
Acidic water clusters Atmospheric interest
Electrochemistry
Experimental work
Mass Spec. Castleman
IR M. A. Johnson, Mike Duncan, M. Okumura
Sum Frequency Generation (SFG) Y. R. Shen, M.
J. Schultz and coworkers
Lots of theory too Jordan, McCoy, Bowman, Klein,
Singer (not exhaustive by any means..)
Variety of medium-sized protonated clusters using
ADMP

19
Protonated Water Clusters Hopping via the
Grotthuss mechanism
True for 20, 30, 40, 50 and larger clusters
20
(H2O)20H3O Magic number cluster

Hydronium goes to surface 150K, 200K and 300K
B3LYP/6-31G and BPBE/6-31G

Castlemans experimental results
10 dangling hydrogens in cluster
Found by absorption of trimethylamine (TMA)
10 dangling hydrogens consistent with our ADMP
simulations
But hydronium on the surface

21
(H2O)20H3O A recent spectroscopic quandry
Theory
Experiment
J.-W. Shin, N. I. Hammer, E. G. Diken et al.,
Science 304, 1137 2004.
22
Spectroscopy A recent quandry
Water Clusters Important in Atmospheric Chemistry
Bottom-right spectrum From ADMP agrees well with
expt dynamical effects in IR spectroscopy
Explains the experiments of M. A. Johnson
23
Spectroscopy A recent quandry
24
(H2O)20H3O Magic number cluster

Hydronium goes to surface 150K, 200K and 300K
B3LYP/6-31G and BPBE/6-31G

Castlemans experimental results
10 dangling hydrogens in cluster
Found by absorption of trimethylamine (TMA)
10 dangling hydrogens consistent with our ADMP
simulations
But hydronium on the surface

25
Larger Clusters and water/vacuum interfaces
Similar results
26
Predicting New Chemistry Theoretically
A Quanlitative explanation to the remarkable Sum
Frequency Generation (SFG) of Y. R. Shen, M. J.
Schultz and coworkers
27
Protonated Water Cluster Conceptual Reasons for
hopping to surface
Hydrophobic and hydrophillic regions Directional
hydrophobicity (it is amphiphilic)

H3O has reduced density around
Reduction of entropy of surrounding waters

Is Hydronium hydrophobic ?
H2O coordination 4
H3O coordination 3
28
Experimental results suggest this as well

Y. R. Shen Sum Frequency Generation (SFG)
IR for water/vapor interface shows dangling O-H
bonds
intensity substantially diminishes as acid conc.
is increased
Consistent with our results
Hydronium on surface lone pair outwards, instead
of dangling O-H
acid concentration is higher on the surface
Schultz and coworkers acidic moieties alter the
structure of water/vapor interfaces

29
QM/MM treatment ONIOM ADMP
Unified treatment of the full system within ADMP
(I)
(This talk will not overview the ONIOM scheme,
but the interested reader should look at the
reference below)
N. Rega, S. S. Iyengar, G. A. Voth, H. B.
Schlegel, T. Vreven and M. J. Frisch, J. Phys.
Chem. B 108 4210 (2004).
30
Side-chain contribute to hop Eigen like
configuration possible using protein backbone
B3LYP and BLYP qualitatively different
results
31
HCHO photodissociation