5 research outputs found
Beyond Kohn–Sham Approximation: Hybrid Multistate Wave Function and Density Functional Theory
A multistate density
functional theory (MSDFT) is presented in
which the energies and densities for the ground and excited states
are treated on the same footing using multiconfigurational approaches.
The method can be applied to systems with strong correlation and to
correctly describe the dimensionality of the conical intersections
between strongly coupled dissociative potential energy surfaces. A
dynamic-then-static framework for treating electron correlation is
developed to first incorporate dynamic correlation into contracted
state functions through block-localized Kohn–Sham density functional
theory (KSDFT), followed by diagonalization of the effective Hamiltonian
to include static correlation. MSDFT can be regarded as a hybrid of
wave function and density functional theory. The method is built on
and makes use of the current approximate density functional developed
in KSDFT, yet it retains its computational efficiency to treat strongly
correlated systems that are problematic for KSDFT but too large for
accurate WFT. The results presented in this work show that MSDFT can
be applied to photochemical processes involving conical intersections
Multistate Density Functional Theory for Effective Diabatic Electronic Coupling
Multistate density functional theory
(MSDFT) is presented to estimate
the effective transfer integral associated with electron and hole
transfer reactions. In this approach, the charge-localized diabatic
states are defined by block localization of Kohn–Sham orbitals,
which constrain the electron density for each diabatic state in orbital
space. This differs from the procedure used in constrained density
functional theory that partitions the density within specific spatial
regions. For a series of model systems, the computed transfer integrals
are consistent with experimental data and show the expected exponential
attenuation with the donor–acceptor separation. The present
method can be used to model charge transfer reactions including processes
involving coupled electron and proton transfer
Pore-Forming Monopeptides as Exceptionally Active Anion Channels
We describe here
a unique family of pore-forming anion-transporting
peptides possessing a single-amino-acid-derived peptidic backbone
that is the shortest among natural and synthetic pore-forming peptides.
These monopeptides with built-in H-bonding capacity self-assemble
into an H-bonded 1D columnar structure, presenting three types of
exteriorly arranged hydrophobic side chains that closely mimic the
overall topology of an α-helix. Dynamic interactions among these
side chains and membrane lipids proceed in a way likely similar to
how α-helix bundle is formed. This subsequently enables oligomerization
of these rod-like structures to form ring-shaped ensembles of varying
sizes with a pore size of smaller than 1.0 nm in diameter but sufficiently
large for transporting anions across the membrane. The intrinsic high
modularity in the backbone further allows rapid tuning in side chains
for combinatorial optimization of channel’s ion-transport activity,
culminating in the discovery of an exceptionally active anion-transporting
monopeptide <b>6L10</b> with an EC<sub>50</sub> of 0.10 μM
for nitrate anions
A New Type of Electron Relay Station in Proteins: Three-Piece S:Π∴S↔S∴Π:S Resonance Structure
A type
of relay station for electron transfer in proteins, three-piece
five-electron bonding, is introduced in this paper, which is also
first proposed here. The ab initio calculations predict the formation
of S:Π∴S↔S∴Π:S resonance binding
with an aromatic ring located in the middle of two sulfur-containing
groups, which may participate in electron-hole transport in proteins.
These special structures can lower the local ionization energies to
capture electron holes efficiently and may be easily formed and broken
because of their proper binding energies. In addition, the UV–vis
spectra provide evidence of the formations of the three-piece five-electron
binding. The cooperation of three adjacent pieces may be advantage
to promote electron transfer a longer distance
Two Aromatic Rings Coupled a Sulfur-Containing Group to Favor Protein Electron Transfer by Instantaneous Formations of π∴S:π↔π:S∴π or π∴π:S↔π:π∴S Five-Electron Bindings
The
cooperative interactions among two aromatic rings with a S-containing
group are described, which may participate in electron hole transport
in proteins. Ab initio calculations reveal the possibility for the
formations of the π∴S:π↔π:S∴π
and π∴π:S↔π:π∴S five-electron
bindings in the corresponding microsurrounding structures in proteins,
both facilitating electron hole transport as efficient relay stations.
The relay functionality of these two special structures comes from
their low local ionization energies and proper binding energies, which
varies with the different aromatic amino acids, S-containing residues,
and the arrangements of the same aromatic rings according to the local
microsurroundings in proteins