MassKinetics: a theoretical model of mass spectra incorporating physical processes, reaction kinetics and mathematical descriptions

Drahos, László; Vékey, Károly

doi:10.1002/jms.142

Cited by 144 publications

(200 citation statements)

References 72 publications

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“…31 To prove that this process is possible to occur on the time-scale of the present experiment after absorption of one photon, the unimolecular dissociation rate constants k d of the investigated Au n Cu m + (n + m = 4) are calculated according to statistical RRKM (Rice, Ramsperger, Kassel, Marcus) theory 32,33 by employing the software package MASS KINETICS. 34 The required vibrational frequencies and the bond dissociation energies of Au 4 + , Au 3 Cu + , and Au 2 Cu 2 + are taken from our theoretical computations performed for the minimum energy structures. For modeling the transition state, the vibrational frequencies are taken to be the same as for the ground state structures minus the middle frequency that is treated as internal translation along the reaction coordinate, and two neighboring frequencies are scaled by a factor of 0.5.…”

Section: B Data Analysismentioning

confidence: 99%

Copper doping of small gold cluster cations: Influence on geometric and electronic structure

Lang

Claes

Cuong

et al. 2011

The Journal of Chemical Physics

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Analytical approach for the excited-state Hessian in time-dependent density functional theory: Formalism, implementation, and performance J. Chem. Phys. 135, 184111 (2011) Stability analysis of multiple nonequilibrium fixed points in self-consistent electron transport calculations J. Chem. Phys. 135, 174111 (2011) Communication: Orbital instabilities and triplet states from time-dependent density functional theory and longrange corrected functionals J. Chem. Phys. 135, 151103 (2011) All-electron time-dependent density functional theory with finite elements: Time-propagation approach J. Chem. Phys. 135, 154104 (2011) Additional information on J. Chem. Phys. The effect of Cu doping on the properties of small gold cluster cations is investigated in a joint experimental and theoretical study. Temperature-dependent Ar tagging of the clusters serves as a structural probe and indicates no significant alteration of the geometry of Au n + (n = 1-16) upon Cu doping. Experimental cluster-argon bond dissociation energies are derived as a function of cluster size from equilibrium mass spectra and are in the 0.10-0.25 eV range. Near-UV and visible light photodissociation spectroscopy is employed in conjunction with time-dependent density functional theory calculations to study the electronic absorption spectra of Au 4-m Cu m + (m = 0, 1, 2) and their Ar complexes in the 2.00−3.30 eV range and to assign their fragmentation pathways. The tetramers Au 4 + , Au 4 + · Ar, Au 3 Cu + , and Au 3 Cu + · Ar exhibit distinct optical absorption features revealing a pronounced shift of electronic excitations to larger photon energies upon substitution of Au by Cu atoms. The calculated electronic excitation spectra and an analysis of the character of the optical transitions provide detailed insight into the composition-dependent evolution of the electronic structure of the clusters.

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Section: B Data Analysismentioning

confidence: 99%

Copper doping of small gold cluster cations: Influence on geometric and electronic structure

Lang

Claes

Cuong

et al. 2011

The Journal of Chemical Physics

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“…The primary difference between their model and the present simulation is that they ignored the exponential kinetic terms in eq 16 (effectively using t 1 ϭ 0 and t 2 ϭ ϱ) and instead replaced P 0 (E) with a displaced Boltzmann distribution (internal energies shifted up by an arbitrary amount) as an ad hoc method of selecting the internal energy distribution for the dissociating ions. The present work, as well as two previous simulations using classical RRK theory by Bojesen and Breindahl [6] and by Ervin [10] and the RRKM treatment by Drahos and Vékey [11,12], properly uses the kinetic expression in eq 16 to select the energy distribution that would be observed in an experiment. In the RRKM and finite heat bath theory treatments of Laskin and Futrell [9], the integration over the distribution of the internal energies of the dissociating ions represented by eq 17 is replaced by evaluation at the single most-probable value of the internal energy.…”

Section: Relationship To Previous Workmentioning

confidence: 99%

“…By measuring the product intensity ratios for proton-bound dimers composed of partners with known acidity, the slope of the correlation is found and then the acidity of an unknown can be measured versus a reference acid. Theoretical formulations of varying levels of sophistication have been given that justify the correlation given by eq 3 [1,2,[5][6][7][8][9][10][11][12], but its use and the meaning of the effective temperature parameter are points of active discussion [4,10,11,[13][14][15].…”

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confidence: 99%

Microcanonical analysis of the kinetic method. The meaning of the “apparent entropy”

Ervin

2002

J. Am. Soc. Mass Spectrom.

135

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A rigorous analysis of the kinetic method is carried out using Rice-Ramsperger-KasselMarcus (RRKM) theory of microcanonical statistical unimolecular dissociation rates. The model employs a kinetics treatment appropriate for metastable ion dissociation. Protonbound alkoxide dimer anions are used as model systems, with realistic vibrational and rotational parameters calculated by ab initio methods for the cluster ion and transition states leading to the competitive dissociation channels. The numerical simulations show that the kinetic method plots of ln(I 2 /I 1 ) versus ⌬⌬H are nearly linear but can exhibit significant curvature. The apparent entropy obtained in the extended kinetic method is not approximately equal to the thermodynamic entropy difference for dissociation, ⌬⌬S(T), or for activation, ⌬⌬S ‡ (T), either at the effective temperature or at any fixed equilibrium temperature. Instead, the apparent entropy term can be related to the ratio of the microcanonical sum of states of the dissociation transition states for the kinetically selected internal energy of the dissociating ions. (J Am Soc Mass Spectrom 2002, 13, 435-452)

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“…The amount of energy available for conversion to internal energy is proportional to the sum of the initial internal energy of the precursor ion (E=), the internal energy of the collision gas (E G ), and the E com . The fraction of this energy that is partitioned between the energy levels in the precursor ion (E) is given by eq 2; where D i is the number of degrees of freedom of the sample molecule, D G is the number of degrees of freedom of the collision gas, and D T is the translational degrees of freedom [3]. …”

mentioning

confidence: 99%

“…In CID, transferring a portion of the kinetic energy of the accelerated precursor ion to internal energy by collisions with relatively stationary gas atoms increases the internal energy of a sample ion. The maximum energy available for absorption (E com ) by the precursor ion in the collision process is described by eq 1 [3]:…”

mentioning

confidence: 99%

CE₅₀: Quantifying collision induced dissociation energy for small molecule characterization and identification

Kertesz

Hall

Hill

et al. 2009

J. Am. Soc. Mass Spectrom.

102

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Survival yield analysis is routinely used in mass spectroscopy as a tool for assessing precursor ion stability and internal energy. Because ion internal energy and decomposition reaction rates are dependent on chemical structure, we reasoned that survival yield curves should be compound-specific and therefore useful for chemical identification. In this study, a quantitative approach for analyzing the correlation between survival yield and collision energy was developed and validated. This method is based on determining the collision energy (CE) at which the survival yield is 50% (CE 50 ) and, further, provides slope and intercept values for each survival yield curve. In initial experiments using a defined set of homologous compounds, we found that CE 50 values were easily determined, quantitative, highly reproducible, and could discriminate between structural and even positional isomers. Further analysis demonstrated that CE 50 values were independent of cone potential and orthogonal to compound mass. Experimentally determined CE 50 values for a diverse set of 54 compounds were correlated to Molconn molecular structure descriptors. The resulting model yielded a statistically significant linear correlation between experimental and calculated CE 50 values and identified several structural characteristics related to precursor ion stability and fragmentation mechanism. Thus, the CE 50 is a promising method for compound identification and discrimination. S urvival yield analysis was initially developed as a tool to quantify the distribution of precursor ion internal energies to explain fragmentation patterns that occur using mass spectrometry [1]. Survival yield has since been used as a method to correlate conditions in the mass spectrometer to the energetics of sample ions. These studies have developed a wide array of equations for understanding molecular decomposition in a mass spectrometer. The quasi-equilibrium theory of a unimolecular reaction indicates that the rate of molecular decomposition, as occurs in collision induced dissociation (CID), is dependent on the molecule's internal energy (E), activation energy (E 0 ), number of vibrational degrees of freedom (n), and the entropy of the reaction transition-state (⌬S*). E 0 , n, and ⌬S* are dependent on the structure of the molecule [2], whereas E is a function of the kinetic energy applied to the molecule in the collision cell. The fraction of a precursor molecule that survives a CID reaction (survival yield) depends on the reaction rate and the reaction time in the collision cell. In CID, transferring a portion of the kinetic energy of the accelerated precursor ion to internal energy by collisions with relatively stationary gas atoms increases the internal energy of a sample ion. The maximum energy available for absorption (E com ) by the precursor ion in the collision process is described by eq 1 [3]:where, E com is the center of mass kinetic energy, m G is the mass of the collision gas, E kin is the kinetic energy of the sample ion, and m i is the mass of t...

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MassKinetics: a theoretical model of mass spectra incorporating physical processes, reaction kinetics and mathematical descriptions

Cited by 144 publications

References 72 publications

Copper doping of small gold cluster cations: Influence on geometric and electronic structure

Copper doping of small gold cluster cations: Influence on geometric and electronic structure

Microcanonical analysis of the kinetic method. The meaning of the “apparent entropy”

CE₅₀: Quantifying collision induced dissociation energy for small molecule characterization and identification

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MassKinetics: a theoretical model of mass spectra incorporating physical processes, reaction kinetics and mathematical descriptions

Cited by 144 publications

References 72 publications

Copper doping of small gold cluster cations: Influence on geometric and electronic structure

Copper doping of small gold cluster cations: Influence on geometric and electronic structure

Microcanonical analysis of the kinetic method. The meaning of the “apparent entropy”

CE50: Quantifying collision induced dissociation energy for small molecule characterization and identification

Contact Info

Product

Resources

About

CE₅₀: Quantifying collision induced dissociation energy for small molecule characterization and identification