Machine Learning Science and Technology,
Journal Year:
2020,
Volume and Issue:
1(4), P. 043001 - 043001
Published: June 12, 2020
Abstract
Machine
learning
is
employed
at
an
increasing
rate
in
the
research
field
of
quantum
chemistry.
While
majority
approaches
target
investigation
chemical
systems
their
electronic
ground
state,
inclusion
light
into
processes
leads
to
electronically
excited
states
and
gives
rise
several
new
challenges.
Here,
we
survey
recent
advances
for
excited-state
dynamics
based
on
machine
learning.
In
doing
so,
highlight
successes,
pitfalls,
challenges
future
avenues
light-induced
molecular
processes.
Chemical Reviews,
Journal Year:
2021,
Volume and Issue:
121(16), P. 10142 - 10186
Published: March 11, 2021
In
recent
years,
the
use
of
machine
learning
(ML)
in
computational
chemistry
has
enabled
numerous
advances
previously
out
reach
due
to
complexity
traditional
electronic-structure
methods.
One
most
promising
applications
is
construction
ML-based
force
fields
(FFs),
with
aim
narrow
gap
between
accuracy
ab
initio
methods
and
efficiency
classical
FFs.
The
key
idea
learn
statistical
relation
chemical
structure
potential
energy
without
relying
on
a
preconceived
notion
fixed
bonds
or
knowledge
about
relevant
interactions.
Such
universal
ML
approximations
are
principle
only
limited
by
quality
quantity
reference
data
used
train
them.
This
review
gives
an
overview
ML-FFs
insights
that
can
be
obtained
from
core
concepts
underlying
described
detail,
step-by-step
guide
for
constructing
testing
them
scratch
given.
text
concludes
discussion
challenges
remain
overcome
next
generation
ML-FFs.
Chemical Reviews,
Journal Year:
2021,
Volume and Issue:
121(16), P. 10073 - 10141
Published: Aug. 16, 2021
We
provide
an
introduction
to
Gaussian
process
regression
(GPR)
machine-learning
methods
in
computational
materials
science
and
chemistry.
The
focus
of
the
present
review
is
on
atomistic
properties:
particular,
construction
interatomic
potentials,
or
force
fields,
Approximation
Potential
(GAP)
framework;
beyond
this,
we
also
discuss
fitting
arbitrary
scalar,
vectorial,
tensorial
quantities.
Methodological
aspects
reference
data
generation,
representation,
regression,
as
well
question
how
a
data-driven
model
may
be
validated,
are
reviewed
critically
discussed.
A
survey
applications
variety
research
questions
chemistry
illustrates
rapid
growth
field.
vision
outlined
for
development
methodology
years
come.
The Journal of Physical Chemistry Letters,
Journal Year:
2020,
Volume and Issue:
11(6), P. 2336 - 2347
Published: March 3, 2020
As
the
quantum
chemistry
(QC)
community
embraces
machine
learning
(ML),
number
of
new
methods
and
applications
based
on
combination
QC
ML
is
surging.
In
this
Perspective,
a
view
current
state
affairs
in
exciting
research
field
offered,
challenges
using
are
described,
potential
future
developments
outlined.
Specifically,
examples
how
used
to
improve
accuracy
accelerate
chemical
shown.
Generalization
classification
existing
techniques
provided
ease
navigation
sea
literature
guide
researchers
entering
field.
The
emphasis
Perspective
supervised
learning.
Chemical Reviews,
Journal Year:
2020,
Volume and Issue:
121(16), P. 9873 - 9926
Published: Nov. 19, 2020
Electronically
excited
states
of
molecules
are
at
the
heart
photochemistry,
photophysics,
as
well
photobiology
and
also
play
a
role
in
material
science.
Their
theoretical
description
requires
highly
accurate
quantum
chemical
calculations,
which
computationally
expensive.
In
this
review,
we
focus
on
not
only
how
machine
learning
is
employed
to
speed
up
such
excited-state
simulations
but
branch
artificial
intelligence
can
be
used
advance
exciting
research
field
all
its
aspects.
Discussed
applications
for
include
dynamics
simulations,
static
calculations
absorption
spectra,
many
others.
order
put
these
studies
into
context,
discuss
promises
pitfalls
involved
techniques.
Since
latter
mostly
based
chemistry
provide
short
introduction
electronic
structure
methods
approaches
nonadiabatic
describe
tricks
problems
when
using
them
molecules.
Nature Communications,
Journal Year:
2020,
Volume and Issue:
11(1)
Published: Nov. 11, 2020
Abstract
Combustion
is
a
complex
chemical
system
which
involves
thousands
of
reactions
and
generates
hundreds
molecular
species
radicals
during
the
process.
In
this
work,
neural
network-based
dynamics
(MD)
simulation
carried
out
to
simulate
benchmark
combustion
methane.
During
MD
simulation,
detailed
reaction
processes
leading
creation
specific
including
various
intermediate
products
are
intimately
revealed
characterized.
Overall,
total
798
different
were
recorded
some
new
pathways
discovered.
We
believe
that
present
work
heralds
dawn
era
in
reactive
can
be
practically
applied
simulating
important
systems
at
ab
initio
level,
provides
atomic-level
understanding
as
well
discovery
an
unprecedented
level
detail
beyond
what
laboratory
experiments
could
accomplish.
The Journal of Physical Chemistry Letters,
Journal Year:
2020,
Volume and Issue:
11(13), P. 5120 - 5131
Published: June 9, 2020
In
this
Perspective,
we
review
recent
advances
in
constructing
high-fidelity
potential
energy
surfaces
(PESs)
from
discrete
ab
initio
points,
using
machine
learning
tools.
Such
PESs,
albeit
with
substantial
initial
investments,
provide
significantly
higher
efficiency
than
direct
dynamics
methods
and/or
high
accuracy
at
a
level
that
is
not
affordable
by
on-the-fly
approaches.
These
PESs
only
are
necessity
for
quantum
dynamical
studies
because
of
delocalization
wave
packets
but
also
enable
the
study
low-probability
and
long-time
events
(quasi-)classical
treatments.
Our
focus
here
on
inelastic
reactive
scattering
processes,
which
more
challenging
bound
systems
involvement
continua.
Relevant
applications
developments
processes
both
gas
phase
gas-surface
interfaces
discussed.
The Journal of Physical Chemistry Letters,
Journal Year:
2020,
Volume and Issue:
11(10), P. 3828 - 3834
Published: April 20, 2020
In
recent
years,
deep
learning
has
become
a
part
of
our
everyday
life
and
is
revolutionizing
quantum
chemistry
as
well.
this
work,
we
show
how
can
be
used
to
advance
the
research
field
photochemistry
by
all
important
properties-multiple
energies,
forces,
different
couplings-for
photodynamics
simulations.
We
simplify
such
simulations
substantially
(i)
phase-free
training
skipping
costly
preprocessing
raw
data;
(ii)
rotationally
covariant
nonadiabatic
couplings,
which
either
trained
or
(iii)
alternatively
approximated
from
only
ML
potentials,
their
gradients,
Hessians;
(iv)
incorporating
spin-orbit
couplings.
As
deep-learning
method,
employ
SchNet
with
its
automatically
determined
representation
molecular
structures
extend
it
for
multiple
electronic
states.
combination
dynamics
program
SHARC,
approach
termed
SchNarc
tested
on
two
polyatomic
molecules
paves
way
toward
efficient
complex
systems.
The Journal of Chemical Physics,
Journal Year:
2021,
Volume and Issue:
154(23)
Published: June 21, 2021
Machine
learning
(ML)
methods
are
being
used
in
almost
every
conceivable
area
of
electronic
structure
theory
and
molecular
simulation.
In
particular,
ML
has
become
firmly
established
the
construction
high-dimensional
interatomic
potentials.
Not
a
day
goes
by
without
another
proof
principle
published
on
how
can
represent
predict
quantum
mechanical
properties-be
they
observable,
such
as
polarizabilities,
or
not,
atomic
charges.
As
is
becoming
pervasive
simulation,
we
provide
an
overview
atomistic
computational
modeling
transformed
incorporation
approaches.
From
perspective
practitioner
field,
assess
common
workflows
to
structure,
dynamics,
spectroscopy
affected
ML.
Finally,
discuss
tighter
lasting
integration
with
chemistry
materials
science
be
achieved
what
it
will
mean
for
research
practice,
software
development,
postgraduate
training.
