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Quantum chemicals

As a multidimensional PES for the reaction from quantum chemical calculations is not available at present, one does not know the reason for the surprismg barrier effect in excited tran.s-stilbene. One could suspect diat tran.s-stilbene possesses already a significant amount of zwitterionic character in the confomiation at the barrier top, implying a fairly Tate barrier along the reaction path towards the twisted perpendicular structure. On the other hand, it could also be possible that die effective barrier changes with viscosity as a result of a multidimensional barrier crossing process along a curved reaction path. [Pg.857]

In most of the connnonly used ab initio quantum chemical methods [26], one fonns a set of configurations by placing N electrons into spin orbitals in a maimer that produces the spatial, spin and angular momentum syimnetry of the electronic state of interest. The correct wavefimction T is then written as a linear combination of tire mean-field configuration fimctions qj = example, to describe the... [Pg.2164]

So, within the limitations of the single-detenninant, frozen-orbital model, the ionization potentials (IPs) and electron affinities (EAs) are given as the negative of the occupied and virtual spin-orbital energies, respectively. This statement is referred to as Koopmans theorem [47] it is used extensively in quantum chemical calculations as a means for estimating IPs and EAs and often yields results drat are qualitatively correct (i.e., 0.5 eV). [Pg.2174]

An excellent, up-to-date treatise on geometry optimization and reaction path algorithms for ab initio quantum chemical calculations, including practical aspects. [Pg.2360]

The Hamiltonian provides a suitable analytic form that can be fitted to the adiabatic surfaces obtained from quantum chemical calculations. As a simple example we take the butatriene molecule. In its neutral ground state it is a planar molecule with D2/1 symmetry. The lowest two states of the radical cation, responsible for the first two bands in the photoelectron spectrum, are and... [Pg.286]

Quantum chemical methods, exemplified by CASSCF and other MCSCF methods, have now evolved to an extent where it is possible to routinely treat accurately the excited electronic states of molecules containing a number of atoms. Mixed nuclear dynamics, such as swarm of trajectory based surface hopping or Ehrenfest dynamics, or the Gaussian wavepacket based multiple spawning method, use an approximate representation of the nuclear wavepacket based on classical trajectories. They are thus able to use the infoiination from quantum chemistry calculations required for the propagation of the nuclei in the form of forces. These methods seem able to reproduce, at least qualitatively, the dynamics of non-adiabatic systems. Test calculations have now been run using duect dynamics, and these show that even a small number of trajectories is able to produce useful mechanistic infomiation about the photochemistry of a system. In some cases it is even possible to extract some quantitative information. [Pg.311]

Dining a chemical reaction, a chemical system ("or substance) A is converted to another, B. Viewed from a quantum chemical point of view, A and B together are a single system that evolves with time. It may be approximated by a combination of two states, A at time zero and B as time approaches infinity. The first is represented by the wave function A) and the second by B). At any time during the reaction, the system may be described by a combination of the two... [Pg.330]

We begin by considering a three-atom system, the allyl radical. A two anchor loop applies in this case as illush ated in Figure 12 The phase change takes place at the allyl anchor, and the phase-inverting coordinate is the asymmetric stretch C3 mode of the allyl radical. Quantum chemical calculations confiiin this qualitative view [24,56]. In this particular case only one photochemical product is expected. [Pg.349]

It was shown by several workers that in this case the first-order Jahn-Teller distortion is due to an ej vibration, and that the second-order distortion vanishes. Therefore, in terms of simple Jahn-Teller theoi, the moat around the symmetric point should be a Mexican hat type, without secondary minima. This expectation was borne out by high-level quantum chemical calculations, which showed that the energy difference between the two expected C2v structures ( A2 and Bi) were indeed very small [73]. [Pg.359]

Quantum chemical descriptors such as atomic charges, HOMO and LUMO energies, HOMO and LUMO orbital energy differences, atom-atom polarizabilities, super-delocalizabilities, molecular polarizabilities, dipole moments, and energies sucb as the beat of formation, ionization potential, electron affinity, and energy of protonation are applicable in QSAR/QSPR studies. A review is given by Karelson et al. [45]. [Pg.427]

Interactions between hydrogen-bond donor and acceptor groups in different molecules play a pivotal role in many chemical and biological problems. Hydrogen bonds can be studied with quantum chemical calculations and empirical methods. [Pg.429]

CODESSA (calculation of a series of difFerent descriptors including quantum chemical descriptors) Semichem Inc. - 7204 Mullen, Shawnee, KS 66216, USA http //www.semichem.com... [Pg.433]

Descriptors have to be found representing the structural features which are related to the target property. This is the most important step in QSPR, and the development of powerful descriptors is of central interest in this field. Descriptors can range from simple atom- or functional group counts to quantum chemical descriptors. They can be derived on the basis of the connectivity (topological or... [Pg.489]

The resultant corrections to the SCF picture are therefore quite large when measured in kcal/mole. For example, the differences AE between the true (state-of-the-art quantum chemical calculation) energies of interaction among the four electrons in Be and the SCF mean-field estimates of these interactions are given in the table shown below in eV (recall that 1 eV = 23.06 kcal/mole). [Pg.232]

CODESSA can compute or import over 500 molecular descriptors. These can be categorized into constitutional, topological, geometric, electrostatic, quantum chemical, and thermodynamic descriptors. There are automated procedures that will omit missing or bad descriptors. Alternatively, the user can manually define any subset of structures or descriptors to be used. [Pg.354]

Quantum Chemical Deer Park, Tex. ethylene coproduct petroleum 14 1,4-butanediol... [Pg.395]

Fig. 3. Blown film extmsion procedure. Courtesy of Quantum Chemical Co. Fig. 3. Blown film extmsion procedure. Courtesy of Quantum Chemical Co.
Petrothene Poljolefims A. Processing Guide 5th ed.. Quantum Chemical Co., Cincinnati, Ohio, 1986. [Pg.378]

See other pages where Quantum chemicals is mentioned: [Pg.834]    [Pg.837]    [Pg.838]    [Pg.838]    [Pg.2115]    [Pg.2144]    [Pg.2145]    [Pg.2160]    [Pg.2222]    [Pg.2332]    [Pg.2977]    [Pg.2980]    [Pg.253]    [Pg.287]    [Pg.309]    [Pg.382]    [Pg.390]    [Pg.477]    [Pg.176]    [Pg.249]    [Pg.432]    [Pg.672]    [Pg.245]    [Pg.246]    [Pg.1263]    [Pg.395]    [Pg.389]    [Pg.402]    [Pg.485]    [Pg.491]    [Pg.471]    [Pg.91]   
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1,3,5-Triazines quantum-chemical calculations

3,3 -Di derivatives quantum chemical calculations and

A Quantum Chemical Approach to Magnetic Interactions in the Solid State

Ab initio quantum chemical calculations

Ab-initio quantum chemical methods

Ah initio Quantum Chemical Methods

Analysis of crystal polymorphism by Pixel and quantum chemical calculations

Applications of Quantum Chemical Methods to Tautomeric Equilibria

Approximate quantum chemical methods NDO and EHT

B3LYP quantum chemical molecular dynamic

Bond activation quantum-chemical view

Bond energies quantum chemical calculations

Bond strength quantum-chemical

Calculation quantum chemical calculations

Carbon monoxide quantum chemical calculations

Characteristics quantum-chemical modeling

Chemical Bonding as a Bosonic Quantum Condensate

Chemical bond, quantum mechanical

Chemical bond, quantum mechanical description

Chemical bonding quantum mechanical theory

Chemical reactions quantum-mechanical tunneling

Chemical reactions, quantum dynamics

Chemical reactions, quantum dynamics basic properties

Chemical reactions, quantum dynamics overview

Chemical solvent model, explicit quantum

Cluster quantum-chemical calculations

Cluster quantum-chemical models

Computational Quantum Chemical Considerations

Computational quantum chemical methods

Computational quantum chemical methods INDEX

Computational studies quantum chemical

Correlation of Log P with Calculated Quantum Chemical Parameters

Cytosine quantum chemical calculation

Density functional theory quantum chemical procedures

Deprotonation quantum chemical studies

Determining rate parameters using quantum chemical calculations and transition state theory

Donor quantum chemical calculations

Electronic excitation quantum chemical calculations

Elementary Quantum Chemistry of the Surface Chemical Bond

Empirical descriptors, quantum-chemical

Empirical descriptors, quantum-chemical modeling

Enzyme reactions, quantum chemical

Enzyme reactions, quantum chemical cluster model approach

Enzyme reactions, quantum chemical investigations

Enzyme reactions, quantum chemical study

Evolution of quantum chemical calculations Beyond Hartree-Fock

Examples of Quantum Chemical Methods

Excitation energy quantum chemical calculation

Excited states of dioxins as studied by ab initio quantum chemical computations anomalous luminescence characteristics

First-principles quantum chemical

First-principles quantum chemical methods

Four-atom quantum dynamics, chemical

Four-atom quantum dynamics, chemical reactions

Functional groups quantum chemical description

Graphitic quantum chemical calculations

High-temperature quantum chemical molecular dynamic

Hydride transfer quantum chemical study

Hydrocarbon activation quantum-chemical calculations

Hydrogen bonding quantum chemical investigation

INDO quantum chemical method

Metal with multireference quantum chemical

Metalloproteins, quantum chemical calculations

Metalloproteins, quantum chemical calculations models

Modeling with quantum chemical

Modeling with quantum chemical descriptors

Molecular body quantum chemical representation

Molecular descriptor quantum chemical method

Molecular dynamics/quantum chemical studie

Molecular dynamics/simulation quantum chemical calculations

Molecular shape quantum chemical concept

Multilevel X-Pol as a Quantum Chemical Model for Macromolecules

Naphthyridines quantum chemical calculations

Nitrogen fixation quantum chemical investigations

Nuclear shielding tensor, quantum-chemical

Optimization of MIP performance through quantum chemical methods

Oxide catalysts quantum-chemical cluster models

Oxygen quantum chemical calculations

PCILO quantum chemical method

Parameters quantum-chemical

Potential energy surfaces quantum chemical equations

Progress in Quantum Chemical Methods

Proteins quantum chemical methods

Proton affinities quantum-chemical calculations

QMSTAT quantum chemical methods

Quanta, chemical conventions

Quantitative structure-activity relationship quantum chemical descriptors

Quantitative structure-property quantum chemical method

Quantum Chemical Calculation ofTautomeric Equilibria

Quantum Chemical Calculations of Electronic Excitation

Quantum Chemical Characterization of Hydrogen Bonds

Quantum Chemical Descriptors for Basicity Scales

Quantum Chemical Program Exchange

Quantum Chemical Studies of Very Large Molecules

Quantum Chemical Topology Force Field

Quantum Chemical Treatment of Electronic Couplings in DNA Fragments

Quantum Chemical le Chatelier Principle

Quantum Chemical le Chatelier Principle for

Quantum Chemical le Chatelier Principle for Molecular Shapes

Quantum Chemicals Pty Ltd

Quantum Chemistry and Chemical Physics

Quantum Chemistry of the Surface Chemical Bond

Quantum Field Theory and the Molecular Hypothesis for Chemical Substances

Quantum Mechanical Description of the Chemical Bond

Quantum Mechanical Tunneling of Hydrogen Atoms in Some Simple Chemical Systems

Quantum Picture of the Chemical Bond

Quantum Theory of Chemical Bonds

Quantum chemical approach to free energy

Quantum chemical approach to free energy calculation

Quantum chemical approaches

Quantum chemical approaches conformation

Quantum chemical calculation

Quantum chemical calculation continuum solvation models

Quantum chemical calculation molecular cluster model

Quantum chemical calculation of tautomeric

Quantum chemical calculation of tautomeric equilibria

Quantum chemical calculation sulfur cation

Quantum chemical calculations 1,5-hydride shift

Quantum chemical calculations Moller-Plesset theory

Quantum chemical calculations QCISD level

Quantum chemical calculations Subject

Quantum chemical calculations activity coefficients

Quantum chemical calculations bond rotations

Quantum chemical calculations charge distribution

Quantum chemical calculations charging free energy contributions

Quantum chemical calculations classifications

Quantum chemical calculations coefficient

Quantum chemical calculations consequence

Quantum chemical calculations density functional theory

Quantum chemical calculations effects

Quantum chemical calculations energy surfaces

Quantum chemical calculations packages

Quantum chemical calculations self-consistent field theory

Quantum chemical calculations semiempirical methods

Quantum chemical calculations semiempirical molecular orbital

Quantum chemical calculations solvation models

Quantum chemical calculations structural effects

Quantum chemical calculations theory

Quantum chemical calculations thymine

Quantum chemical calculations, molecular

Quantum chemical calculations, molecular modeling

Quantum chemical calculations, solvents

Quantum chemical changes

Quantum chemical characterization

Quantum chemical computations

Quantum chemical concepts

Quantum chemical dynamics

Quantum chemical energy calculation

Quantum chemical energy procedures

Quantum chemical equations

Quantum chemical equations accuracy

Quantum chemical equations methodology

Quantum chemical equations particle basis functions

Quantum chemical indices

Quantum chemical method/calculation

Quantum chemical methodology

Quantum chemical methods

Quantum chemical methods basis sets

Quantum chemical methods density matrix elements

Quantum chemical methods shielding tensor

Quantum chemical methods, computational applicability

Quantum chemical model

Quantum chemical models/calculation

Quantum chemical molecular descriptors

Quantum chemical molecular descriptors QSARs

Quantum chemical molecular dynamics

Quantum chemical procedures

Quantum chemical procedures calculations

Quantum chemical programs

Quantum chemical software

Quantum chemical software package

Quantum chemical studies

Quantum chemical studies cyclizations

Quantum chemical studies, organometallic

Quantum chemical study of the

Quantum chemical theory

Quantum chemical topology

Quantum chemical tree code

Quantum chemical view, initial

Quantum chemically derived potentials

Quantum mechanical models of the chemical bond

Quantum mechanical treatments, chemical

Quantum mechanical treatments, chemical acids

Quantum mechanics chemical reactions

Quantum mechanics chemical reactivity

Quantum numbers, chemical conventions

Quantum tunneling in chemical reactions

Quantum world chemical bonding

Quantum-Chemical Calculations of NMR Parameters

Quantum-chemical Comments

Quantum-chemical Dynamics with the Slater-Roothaan Method

Quantum-chemical Remarks about the Continuum

Quantum-chemical analysis

Quantum-chemical basis for second-order polarizabilities

Quantum-chemical calculations initio

Quantum-chemical calculations radical cation

Quantum-chemical calculations thienothiophenes

Quantum-chemical computer programs

Quantum-chemical descriptors

Quantum-chemical methods poly

Quantum-chemical methods valence bond method

Quantum-chemical methods, for molecular

Quantum-chemical modeling

Quantum-chemical prediction

Quantum-chemical techniques

Quantum-chemical variational principle

Reactive force-field quantum chemical methods

Recent quantum chemical studies of the ORR mechanism

Reflection, quantum chemical

Relativistic Quantum Chemical Calculations in Practice

Relativistic quantum-chemical calculations

Results from Quantum Chemical Calculations

Semiempirical quantum chemical

Semiempirical quantum chemical methods

Simple quantum chemical models of electronic excitation

Solvation quantum-chemical calculations

Some aspects of quantum molecular scattering in chemical dynamics

Spectroscopic parameters, quantum chemical calculations

State correlation diagrams quantum chemical calculations

Static quantum chemical calculations

Static quantum chemical calculations approach

Static quantum chemical calculations chemistry

Strong coupling quantum chemical equations

Sub-Quantum Chemistry Chemical Bonding Field and Bondons

Sulfur quantum-chemical calculation

The Quantum-Chemical Approach

The Quantum-Chemical View of Bond Activation

The Stable Complex Species in Melts of Alkali Metal Halides Quantum-Chemical Approach

Theoretical and Quantum Chemical Calculations

Thermal quantum chemical simulations

Toxicity quantum-chemical descriptors

Transition elementary quantum-chemical model

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