Chemistry 6440 / 7440 Computational Chemistry and Molecular Modeling MidTerm Review.
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Transcript of Chemistry 6440 / 7440 Computational Chemistry and Molecular Modeling MidTerm Review.
Chemistry 6440 / 7440
Computational Chemistry
and Molecular Modeling
MidTerm Review
Types of Molecular Models
• Wish to model molecular structure, properties and reactivity
• Range from simple qualitative descriptions to accurate, quantitative results
• Costs range from trivial to months of supercomputer time
• Some compromises necessary between cost and accuracy of modeling methods
Molecular mechanics
• Ball and spring description of molecules• Better representation of equilibrium geometries than
plastic models• Able to compute relative strain energies• Cheap to compute• Lots of empirical parameters that have to be carefully
tested and calibrated• Limited to equilibrium geometries• Does not take electronic interactions into account • No information on properties or reactivity• Cannot readily handle reactions involving the making
and breaking of bonds
Semi-empirical molecular orbital methods
• Approximate description of valence electrons• Obtained by solving a simplified form of the
Schrödinger equation• Many integrals approximated using empirical
expressions with various parameters• Semi-quantitative description of electronic
distribution, molecular structure, properties and relative energies
• Cheaper than ab initio electronic structure methods, but not as accurate
Ab Initio Molecular Orbital Methods
• More accurate treatment of the electronic distribution using the full Schroedinger equation
• Can be systematically improved to obtain chemical accuracy
• Does not need to be parameterized or calibrated with respect to experiment
• Can describe structure, properties, energetics and reactivity
• Expensive
Potential Energy Surfaces• The concept of potential energy surfaces is central to
computational chemistry• The structure, energetics, properties, reactivity, spectra
and dynamics of molecules can be readily understood in terms of potential energy surfaces
• Except in very simple cases, the potential energy surface cannot be obtained from experiment
• The field of computational chemistry has developed a wide array of methods for exploring potential energy surface
• The challenge for computational chemistry is to explore potential energy surfaces with methods that are efficient and accurate enough to describe the chemistry of interest
• Equilibrium molecular structures correspond to the positions of the minima in the valleys on a PES
• Energetics of reactions can be calculated from the energies or altitudes of the minima for reactants and products
• A reaction path connects reactants and products through a mountain pass• A transition structure is the highest point on the lowest energy path• Reaction rates can be obtained from the height and profile of the potential
energy surface around the transition structure
• The shape of the valley around a minimum determines the vibrational spectrum
• Each electronic state of a molecule has a separate potential energy surface, and the separation between these surfaces yields the electronic spectrum
• Properties of molecules such as dipole moment, polarizability, NMR shielding, etc. depend on the response of the energy to applied electric and magnetic fields
Asking the Right Questions• molecular modeling can answer some
questions easier than others • stability and reactivity are not precise
concepts– need to give a specific reaction
• similar difficulties with other general concepts:– resonance– nucleophilicity– leaving group ability– VSEPR– etc.
Asking the Right Questions
• phrase questions in terms of energy differences, energy derivatives, geometries, electron distributions
• trends easier than absolute numbers • gas phase much easier than solution • structure and electron distribution easier than
energetics • vibrational spectra and NMR easier than electronic
spectra • bond energies, IP, EA, activation energies are hard
(PA not quite as hard) • excited states much harder than ground states • solvation by polarizable continuum models (very hard
by dynamics)
Molecular Mechanics
• PES calculated using empirical potentials fitted to experimental and calculated data
• composed of stretch, bend, torsion and non-bonded components
E = Estr + Ebend + Etorsion + Enon-bond
• e.g. the stretch component has a term for each bond in the molecule
Bond Stretch Term
• many force fields use just a quadratic term, but the energy is too large for very elongated bonds
Estr = ki (r – r0)2
• Morse potential is more accurate, but is usually not used because of expense
Estr = De [1-exp(-(r – r0)]2
• a cubic polynomial has wrong asymptotic form, but a quartic polynomial is a good fit for bond length of interest
Estr = { ki (r – r0)2 + k’i (r – r0)3 + k”i (r – r0)4 }
• The reference bond length, r0, not the same as the equilibrium bond length, because of non-bonded contributions
Angle Bend Term
• usually a quadratic polynomial is sufficient
Ebend = ki ( – 0)2
• for very strained systems (e.g. cyclopropane) a higher polynomial is better
Ebend = ki ( – 0)2 + k’i ( – 0)3
+ k”i ( – 0)4 + . . .
• alternatively, special atom types may be used for very strained atoms
Torsional Term
• most force fields use a single cosine with appropriate barrier multiplicity, n
Etors = Vi cos[n( – 0)]
• some use a sum of cosines for 1-fold (dipole), 2-fold (conjugation) and 3-fold (steric) contributions
Etors = { Vi cos[( – 0)] + V’i cos[2( – 0)]
+ V”i cos[3( – 0)] }
Non-Bonded Terms
• Lennard-Jones potential
– EvdW = 4 ij ( (ij / rij)12 - (ij / rij)6 )
– easy to compute, but r -12 rises too rapidly
• Buckingham potential
– EvdW = A exp(-B rij) - C rij-6
– QM suggests exponential repulsion better, but is harder to compute
• tabulate and for each atom – obtain mixed terms as arithmetic and geometric means
AB = (AA + BB)/2; AB = (AA BB)1/2
Parameterization
• difficult, computationally intensive, inexact • fit to structures (and properties) for a training set of
molecules • recent generation of force fields fit to ab initio data
at minima and distorted geometries • trial and error fit, or least squares fit (need to avoid
local minima, excessive bias toward some parameters at the expense of others)
• different parameter sets and functional forms can give similar structures and energies but different decomposition into components
• don't mix and match
Applications
• good geometries and relative energies of conformers of the same molecule (provided that electronic interactions are not important)
• effect of substituents on geometry and strain energy • well parameterized for organics, less so for inorganics • specialty force fields available for proteins, DNA, for liquid
simulation • molecular mechanics cannot be used for reactions that
break bonds • useful for simple organic problems: ring strain in
cycloalkanes, conformational analysis, Bredt's rule, etc. • high end biochemistry problems: docking of substrates into
active sites, refining x-ray structures, determining structures from NMR data, free energy simulations
Schrödinger Equation
• H is the quantum mechanical Hamiltonian for the system (an operator containing derivatives)
• E is the energy of the system is the wavefunction (contains everything we
are allowed to know about the system)• ||2 is the probability distribution of the particles
EH
Hamiltonian for a Molecule
• kinetic energy of the electrons• kinetic energy of the nuclei• electrostatic interaction between the electrons
and the nuclei• electrostatic interaction between the electrons• electrostatic interaction between the nuclei
nuclei
BA AB
BAelectrons
ji ij
nuclei
A iA
Aelectrons
iA
nuclei
A Ai
electrons
i e r
ZZe
r
e
r
Ze
mm
2222
22
2
22ˆ H
Variational Theorem
• the expectation value of the Hamiltonian is the variational energy
• the variational energy is an upper bound to the lowest energy of the system
• any approximate wavefunction will yield an energy higher than the ground state energy
• parameters in an approximate wavefunction can be varied to minimize the Evar
• this yields a better estimate of the ground state energy and a better approximation to the wavefunction
exactEEd
d
var*
* ˆ
H
Born-Oppenheimer Approximation
• the nuclei are much heavier than the electrons and move more slowly than the electrons
• in the Born-Oppenheimer approximation, we freeze the nuclear positions, Rnuc, and calculate the electronic wavefunction, el(rel;Rnuc) and energy E(Rnuc)
• E(Rnuc) is the potential energy surface of the molecule (i.e. the energy as a function of the geometry)
• on this potential energy surface, we can treat the motion of the nuclei classically or quantum mechanically
Hartree Approximation
• assume that a many electron wavefunction can be written as a product of one electron functions
• if we use the variational energy, solving the many electron Schrödinger equation is reduced to solving a series of one electron Schrödinger equations
• each electron interacts with the average distribution of the other electrons
)()()(),,,( 321321 rrrrrr
Hartree-Fock Approximation
• the Pauli principle requires that a wavefunction for electrons must change sign when any two electrons are permuted
• the Hartree-product wavefunction must be antisymmetrized
• can be done by writing the wavefunction as a determinant
n
nnn n
n
n
n
21222
111
)()1()1(
)()2()1(
)()2()1(
1
Fock Equation
• take the Hartree-Fock wavefunction
• put it into the variational energy expression
• minimize the energy with respect to changes in the orbitals
• yields the Fock equation
n 21
d
dE
*
*
var
H
iii F
0/var iE
Fock Operator
• Coulomb operator (electron-electron repulsion)
• exchange operator (purely quantum mechanical -arises from the fact that the wavefunction must switch sign when you exchange to electrons)
ijij
j
electrons
ji d
r
e }{ˆ2
J
jiij
j
electrons
ji d
r
e }{ˆ2
K
KJVTF ˆˆˆˆˆ NE
Solving the Fock Equations
1. obtain an initial guess for all the orbitals i
2. use the current I to construct a new Fock operator
3. solve the Fock equations for a new set of I
4. if the new I are different from the old I, go back to step 2.
iii F
LCAO Approximation
• numerical solutions for the Hartree-Fock orbitals only practical for atoms and diatomics
• diatomic orbitals resemble linear combinations of atomic orbitals
• e.g. sigma bond in H2
1sA + 1sB
• for polyatomics, approximate the molecular orbital by a linear combination of atomic orbitals (LCAO)
c
Roothaan-Hall Equations
• basis set expansion leads to a matrix form of the Fock equations
F Ci = i S Ci
• F – Fock matrix
• Ci – column vector of the molecular orbital coefficients
I – orbital energy
• S – overlap matrix
Slater-type Basis Functions
• exact for hydrogen atom• used for atomic calculations• right asymptotic form• correct nuclear cusp condition• 3 and 4 center two electron integrals cannot be
done analytically
)2/exp(32/)(
)2/exp(96/)(
)exp(/)(
2
2/1522
2
2/1522
1
2/1311
rxr
rrr
rr
pppx
sss
sss
Gaussian-type Basis Functions
• die off too quickly for large r• no cusp at nucleus• all two electron integrals can be done
analytically
)exp(/2048)(
)exp(9/2048)(
)exp(/128)(
)exp(/2)(
24/137
224/137
24/135
24/13
rxyrg
rxrg
rxrg
rrg
xy
xx
x
s
Minimal Basis Set• only those shells of orbitals needed for a
neutral atom
• e.g. 1s, 2s, 2px, 2py, 2pz for carbon
• STO-3G– 3 gaussians fitted to a Slater-type orbital (STO)– STO exponents obtained from atomic
calculations, adjusted for a representative set of molecules
• also known as single zeta basis set (zeta, , is the exponent used in Slater-type orbitals)
Double Zeta Basis Set (DZ)• each function in a minimal basis set is doubled• one set is tighter (closer to the nucleus, larger
exponents), the other set is looser (further from the nucleus, smaller exponents)
• allows for radial (in/out) flexibility in describing the electron cloud
• if the atom is slightly positive, the density will be somewhat contracted
• if the atom is slightly negative, the density will be somewhat expanded
Split Valence Basis Set
• only the valence part of the basis set is doubled (fewer basis functions means less work and faster calculations
• core orbitals are represented by a minimal basis, since they are nearly the same in atoms an molecules
• 3-21G (3 gaussians for 1s, 2 gaussians for the inner 2s,2p, 1 gaussian for the outer 2s,2p)
• 6-31G (6 gaussians for 1s, 3 gaussians for the inner 2s,2p, 1 gaussian for the outer 2s,2p)
Polarization Functions• higher angular momentum functions added to a basis
set to allow for angular flexibility• e.g. p functions on hydrogen, d functions on carbon• large basis Hartree Fock calculations without
polarization functions predict NH3 to be flat • without polarization functions the strain energy of
cyclopropane is too large• 6-31G(d) (also known as 6-31G*) – d functions on
heavy atoms • 6-31G(d,p) (also known as 6-31G**) – p functions on
hydrogen as well as d functions on heavy atoms• DZP – DZ with polarization functions
Diffuse Functions
• functions with very small exponents added to a basis set
• needed for anions, very electronegative atoms, calculating electron affinities and gas phase acidities
• 6-31+G – one set of diffuse s and p functions on heavy atoms
• 6-31++G – a diffuse s function on hydrogen as well as one set of diffuse s and p functions on heavy atoms
Correlation-Consistent Basis Functions
• a family of basis sets of increasing size • can be used to extrapolate to the basis set limit• cc-pVDZ – DZ with d’s on heavy atoms, p’s on H• cc-pVTZ – triple split valence, with 2 sets of d’s
and one set of f’s on heavy atoms, 2 sets of p’s and 1 set of d’s on hydrogen
• cc-pVQZ, cc-pV5Z, cc-pV6Z• can also be augmented with diffuse functions
(aug cc-pVXZ)
Molecular Orbital Plots
• plot a surface where |i(r)|2 = c
i(r) can have positive and negative values
• shade in different colors
• only the change in sign matters, not the absolute sign
)()( rcr ii
Population Analysis
matrixoverlapSmatrixdensityPcc ii
occ
i ,2 *
rgechaatomicMZq
atomstocondensedSPM
matrixanalysispopulationMullikenSPM
BABAA
A BAB
functionsbasisandatomsdifferentfrom
onscontributiintopartition eNSP
Dipole Moment
• for Hartree-Fock wavefunctions, the dipole is the expectation value of the classical expression for the dipole
• can be written in terms of the density matrix and a set of dipole integrals over the basis functions
AAA
AAAii
occ
i
AAA
ii
ReZdreP
ReZdre
ReZdre
)(
)(2
)(
*
*
Electron Density
• energy of a unit test charge placed at rC
AACAC
AACACC
ReZdreP
ReZdrerESP
/)/(
/)/()( *
Electrostatic Potential
)()()( rrPr
Features of Potential Energy Surfaces
Initial guess for geometry & Hessian
Calculate energy and gradient
Minimize along line between current and previous point
Update Hessian (Powell, DFP, MS, BFGS, Berny, etc.)
Take a step using the Hessian(Newton, RFO, Eigenvector following)
Check for convergence on the gradient and displacement
Update the geometry
yes DONE
no
Testing Minima• Compute the full Hessian (the partial Hessian from
an optimization is not accurate enough and contains no information about lower symmetries).
• Check the number of negative eigenvalues:– 0 required for a minimum.– 1 (and only 1) for a transition state
• For a minimum, if there are any negative eigenvalues, follow the associated eigenvector to a lower energy structure.
• For a transition state, if there are no negative eigenvalues, follow the the lowest eigenvector up hill.
Algorithms for Finding Transition States
• Surface fitting• Linear and quadratic synchronous transit• Coordinate driving• Hill climbing, walking up valleys, eigenvector
following• Gradient norm method• Quasi-Newton methods• Newton methods
Gradient Based Transition Structure
Optimization Algorithms • Quadratic Model
– fixed transition vector– constrained transition vector– associated surface– fully variable transition vector
• Non Quadratic Models-GDIIS• Eigenvector following/RFO for stepsize control• Bofill update of Hessian, rather than BFGS• Test Hessian for correct number of negative eigenvalues
Testing Transition Structures• Compute the full Hessian (the partial Hessian from an
optimization is not accurate enough and contains no information about lower symmetries).
• Check the number of negative eigenvalues:– 1 and only 1 for a transition state.
• Check the nature of the transition vector (it may be necessary to follow reaction path to be sure that the transition state connects the correct reactants and products).
• If there are too many negative eigenvalues, follow the appropriate eigenvector to a lower energy structure.
Reaction PathsTaylor expansion of reaction path
Tangent
Curvature
)0(61)0(21)0()0()( 23120 sssxsx
||
)(0
g
g
sd
sxd
||/))((
)()(
00001
2
20
1
g
sd
sxd
sd
sd
t
HH
Harmonic Vibrational Frequenciesfor a Polyatomic Molecule
I – eigenvalues of the mass weighted Cartesian force constant matrix
qi – normal modes of vibration
ijiji
ii
iji
nuc
mM
qq i
/
2
~
2
1
2ˆ
,,
22
2
,
2
MxLLq
MLkMLLkL
H
tt
tt
Calculating Vibrational Frequencies• optimize the geometry of the molecule• calculate the second derivatives of the Hartree-
Fock energy with respect to the x, y and z coordinates of each nucleus
• mass-weight the second derivative matrix and diagonalize
• 3 modes with zero frequency correspond to translation
• 3 modes with zero frequency correspond to overall rotation (if the forces are not zero, the normal modes for rotation may have non-zero frequencies; hence it may be necessary to project out the rotational components)
Pople, J. A.; Schlegel, H. B.; Krishnan, R.; DeFrees, D. J.; Binkley, J. S.; Frisch, M. J.; Whiteside, R. A.; Hout, R. F.; Hehre, W. J.; Molecular orbital studies of vibrational frequencies. Int. J. Quantum. Chem., Quantum Chem. Symp., 1981, 15, 269-278.
Scaling of Vibrational Frequencies• calculated harmonic frequencies are typically 10%
higher than experimentally observed vibrational frequencies
• due to the harmonic approximation, and due to the Hartree-Fock approximation
• recommended scale factors for frequenciesHF/3-21G 0.9085, HF/6-31G(d) 0.8929, MP2/6-31G(d) 0.9434, B3LYP/6-31G(d) 0.9613
• recommended scale factors for zero point energiesHF/3-21G 0.9409, HF/6-31G(d) 0.9135, MP2/6-31G(d) 0.9676, B3LYP/6-31G(d) 0.9804
Electron Correlation Energy
• in the Hartree-Fock approximation, each electron sees the average density of all of the other electrons
• two electrons cannot be in the same place at the same time
• electrons must move two avoid each other, i.e. their motion must be correlated
• for a given basis set, the difference between the exact energy and the Hartree-Fock energy is the correlation energy
• ca 20 kcal/mol correlation energy per electron pair
Goals for Correlated Methods
• well defined– applicable to all molecules with no ad-hoc choices– can be used to construct model chemistries
• efficient– not restricted to very small systems
• variational – upper limit to the exact energy
• size extensive– E(A+B) = E(A) + E(B)– needed for proper description of thermochemistry
• hierarchy of cost vs. accuracy– so that calculations can be systematically improved
• determine CI coefficients using the variational principle
• CIS – include all single excitations – useful for excited states, but on for correlation of the ground state
• CISD – include all single and double excitations– most useful for correlating the ground state– O2V2 determinants (O=number of occ. orb., V=number of unocc. orb.)
• CISDT – singles, doubles and triples– limited to small molecules, ca O3V3 determinants
• Full CI – all possible excitations– ((O+V)!/O!V!)2 determinants– exact for a given basis set– limited to ca. 14 electrons in 14 orbitals
Configuration Interaction
tddE
ttt abcijk
ijkabc
abcijk
abij
ijab
abij
ai
ia
ai
respect towith /ˆminimize **
0
H
• choose H0 such that its eigenfunctions are determinants of molecular orbitals
• expand perturbed wavefunctions in terms of the Hartree-Fock determinant and singly, doubly and higher excited determinants
• perturbational corrections to the energy
Møller-Plesset Perturbation Theory
iFH ˆˆ0
baji jiaa
abij
HFHFHFMP
HF
dEdEEEE
ddEEE
,
20
1022
0000010
]ˆ[ˆ
ˆˆ
VV
VH
abcijk
ijkabc
abcijk
abij
ijab
abij
ai
ia
ai aaa1
• CISD can be written as
• T1 and T2 generate all possible single and double excitations with the appropriate coefficients
• coupled cluster theory wavefunction
Coupled Cluster Theory
021 )ˆˆ1( TTCISD
abij
baji
abijt
,02T
021 )ˆˆ1exp( TTCCSD
Theoretical Basis for Density Functional Theory
• Hohenberg and Kohn (1964)– energy is a functional of the density E[]– the functional is universal, independent of the system– the exact density minimizes E[]– applies only to the ground state
• Kohn and Sham (1965)– variational equations for a local functional
– density can be written as a single determinant of orbitals (but orbitals are not the same as Hartree-Fock)
– EXC takes care of electron correlation as well as exchange
nucxcNE VEJVTE ][][][][][
Density Functional Theory
• local functionals (LSDA)– depend only on the density– exchange and correlation functional from electron gas
• generalized gradient approximation (GGA)– depends on ||/4/3
– BLYP, BP86, BPW91, PBE
• hybrid functionals– mix some Hartree-Fock exchange– B3LYP, PBE1PBE, B3PW91
Semi-empirical MO Methods
• the high cost of ab initio MO calculations is largely due to the many integrals that need to be calculated (esp. two electron integrals)
• semi-empirical MO methods start with the general form of ab initio Hartree-Fock calculations, but make numerous approximations for the various integrals
• many of the integrals are approximated by functions with empirical parameters
• these parameters are adjusted to improve the agreement with experiment
Zero Differential Overlap (ZDO)
• two electron repulsion integrals are one of the most expensive parts of ab initio MO calculations
• neglect integrals if orbitals are not the same
• approximate integrals by using s orbitals only• CNDO, INDO and MINDO semi-empirical
methods
2112
)2()2(1
)1()1()|( ddr
ififwhere 0,1
)|()|(
Neglect of Diatomic Differential Overlap (NDDO)
• fewer integrals neglected
• neglect integrals if and are not on the same atom or and are not on the same atom
• integrals approximations are more accurate and have more adjustable parameters than in ZDO methods
• parameters are adjusted to fit experimental data and ab initio calculations
• MNDO, AM1 and PM3 semi-empirical methods
2112
)2()2(1
)1()1()|( ddr
Model Chemistries
• A theoretical model chemistry is a complete algorithm for the calculation of the energy of any molecular system.
• It cannot involve subjective decisions in its application. • It must be size consistent so that the energy of every
molecular species is uniquely defined. • A simple model chemistry employs a single theoretical
method and basis set. • A compound model chemistry combines several theoretical
methods and basis sets to achieve higher accuracy at lower cost.
• A model chemistry is useful if for some class of molecules it is the most accurate calculation we can afford to do.
Model ChartMinimalSTO-3G HF MP2 MP3 MP4 QCISD(T) . . . Full CI
Split-Valence3-21G
Polarized6-31G*
6-311G*
Diffuse6-311+G*
High Ang. Mom.6-311+G(3df,p)
…
SchrödingerEquation
Basis
Development of a Model Chemistry
• Set targets– accuracy goals– cost/size goals– validation data set
• Define and implement methods– Specify level of theory for geometry optimization,
electronic energy, vibrational zero point energy
• Test model on validation data set
Compound Model Chemistries:
G2 and G2(MP2)• Proposed by J. Pople and co-workers
• Goal: Atomization energies to 2 kcal/mol
• Strategy: Approximate QCISD(T)/6-311+G(3df,p) by assuming that basis set and correlation corrections are additive
• Mean absolute error of 1.21 kcal/mol in 125 comparisons
CBS Extrapolation
The slow, N-1, convergence of the correlation energy vs the one-electron basis set expansion is the result of the universal cusp in wave functions as interelectronic distances, .Thus, we can reasonably expect the N-1 form to also be universal.
rij 0
-40
-35
-30
-25
-20
-15
-10
-5
0
0.00 0.25 0.50 0.75 1.00
(uc
u)2(N + )-1
N=5
N=14N=30
N=1
2s
2px
2py
2pz
CBSLimit
1s
SCF MP2 MP4(SDQ) MP4(SDTQ) QCISD(T)
6-31G631G†
6-31+G†6-31+G††
6-311G(d,p)6-31+G(d(f),d,p)
6-311+G(d,p)6-311G(2df,p)
6-311+G(2df,p)6-311+G(3df,2p)
6-311+G(3d2f,2df,p)6-311++G(3d2f,2df,2p)
[6s6p3d2f,4s2p1d]
FCI
CBS Exact
0.0
0.5
1.0
1.5
2.0
2.5
3.0
0 5 10 15 20 25 30
Maximum Number of Heavy Atoms
RM
S E
rro
r: G
2 t
es
t s
et
(kc
al/m
ol)
CBS-QB3
CBS-QCI/APNO
G2
G2(MP2)
CBS-q CBS-4
Thermodynamic Functions
• U(T) - internal energy at absolute temperature T
• H(T) = U(T) + PV = U(T) + RT - enthalpy
• S(T) - entropy
• G(T) = H(T) – T S(T) – free energy
Thermodynamic Functions
• at absolute zero, T = 0
U(0) = H(0) = G(0)
U(0) = electronic energy
+ zero point energy
S(0) = 0 for a pure crystalline substance (third law of thermodynamics)
Thermodynamic Functions at T 0
• U(T) = U(0) + CvdT– heat at constant volume, molecule gains energy
for translation (3/2 RT), rotation (3/2 RT) and vibration ( 1/(1-exp(-i/kT))
• H(T) = H(0) + CpdT– heat at constant pressure, molecule gains
additional energy from expansion
• S(T) > 0 – more states become accessible as the
temperature increases