An alternative interpretation of the ultracold methylhydroxycarbene rearrangement mechanism: cooperative effects

Morais, Sara Figueirêdo de Alcântara; Mundim, Kleber C.; Ferreira, Daví A. C.

doi:10.1039/c4cp05842a

Cited by 7 publications

(10 citation statements)

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“…Literature of pyruvic acid photolysis using such radiation typically can be separated into two categories. The first investigates the low-pressure (0–150 Torr of buffer gas) photochemistry of approximately 1 Torr of pyruvic acid, a concentration several orders of magnitude higher than would be expected in the lower atmosphere. − These studies, bolstered by computational work, − conclude that, following photon absorption, gas-phase pyruvic acid undergoes simultaneous concerted hydrogen atom transfer and decarboxylation with a quantum yield of unity. − The immediate products are carbon dioxide and a reactive intermediate, methylhydroxycarbene (CH 3 COH), which is observed as acetaldehyde (CH 3 CHO) following isomerization. − …”

Section: Introductionmentioning

confidence: 99%

Atmospheric Simulation Chamber Studies of the Gas-Phase Photolysis of Pyruvic Acid

et al. 2017

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Pyruvic acid is an atmospherically abundant α-keto-acid that degrades efficiently from the troposphere via gas-phase photolysis. To explore conditions relevant to the environment, 2-12 ppm pyruvic acid is irradiated by a solar simulator in the environmental simulation chamber, CESAM. The combination of the long path length available in the chamber and its low surface area to volume ratio allows us to quantitatively examine the quantum yield and photochemical products of pyruvic acid. Such details are new to the literature for the low initial concentrations of pyruvic acid employed here. We determined photolysis quantum yields of ϕ = 0.84 ± 0.1 in nitrogen and ϕ = 3.2 ± 0.5 in air, which are higher than those reported by previous studies that used higher partial pressures of pyruvic acid. The quantum yield greater than unity in air is due to secondary chemistry, driven by O, that emerges under the conditions in these experiments. The low concentration of pyruvic acid and the resulting oxygen effect also alter the product distribution such that acetic acid, rather than acetaldehyde, is the primary product in air. These results indicate that tropospheric pyruvic acid may degrade in part via photoinduced mechanisms that are different than previously expected.

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Section: Introductionmentioning

confidence: 99%

Atmospheric Simulation Chamber Studies of the Gas-Phase Photolysis of Pyruvic Acid

et al. 2017

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“…Temperature ranges for the validity of the approach are assessed with respect to features of the potential energy barrier to reaction [20,112], permitting comparison with experiments and tests against alternative formulations. Elementary reactions, widely investigated both experimentally and theoretically, which have been described successfully, are F + H 2 [28,96], F + HD [113], CH 4 + OH [20], CH 3 Cl + OH [20], H 2 + CN [20], and also abstraction and dissociation in the nitrogen trifluoride channels [114], and proton rearrangement in curcumin [115] and methylhydroxycarbene [116]. The deformed formulation has also been found useful to describe other reactions not involving tunnelling but showing non-negligible sub-Arrhenius behaviour, such as the C + CH + reaction [117], which is of relevance in cold interstellar clouds.…”

Section: (I) Transition State Theorymentioning

confidence: 99%

Kinetics of low-temperature transitions and a reaction rate theory from non-equilibrium distributions

Aquilanti

Coutinho

Carvalho-Silva

2017

Phil. Trans. R. Soc. A.

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relaxing the thermodynamic equilibrium limit, either for a binomial distribution if d > 0 or for a negative binomial distribution if d < 0, formally corresponding to Fermionlike or Boson-like statistics, respectively. The current status of the phenomenology is illustrated emphasizing case studies; specifically (i) the super-Arrhenius kinetics, where transport phenomena accelerate processes as the temperature increases; (ii) the sub-Arrhenius kinetics, where quantum mechanical tunnelling propitiates low-temperature reactivity; (iii) the anti-Arrhenius kinetics, where processes with no energetic obstacles are rate-limited by molecular reorientation requirements. Particular attention is given for case (i) to the treatment of diffusion and viscosity, for case (ii) to formulation of a transition rate theory for chemical kinetics including quantum mechanical tunnelling, and for case (iii) to the stereodirectional specificity of the dynamics of reactions strongly hindered by the increase of temperature.This article is part of the themed issue 'Theoretical and computational studies of nonequilibrium and non-statistical dynamics in the gas phase, in the condensed phase and at interfaces'.

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“…Also worth mentioning are selected entropic applications beyond BG in other areas of knowledge: complex networks [ 16 , 17 , 18 ]; economics [ 149 , 150 , 151 , 152 , 153 , 154 , 155 , 156 ]; geophysics (earthquakes, atmosphere) [ 157 , 158 , 159 , 160 , 161 , 162 , 163 , 164 , 165 , 166 ]; general and quantum chemistry [ 139 , 167 , 168 , 169 , 170 , 171 ]; hydrology and engineering (water engineering [ 172 ] and materials engineering [ 173 , 174 ]); power grids [ 175 ]; the environment [ 176 ]; medicine [ 177 , 178 , 179 ]; biology [ 180 , 181 ]; computational processing of medical images (microcalcifications in mammograms [ 182 ] and magnetic resonance for multiple sclerosis [ 183 ]) and time series (e.g., ECG in coronary disease [ 184 ] and EEG in epilepsy [ 185 , 186 ]); train delays [ 187 ]; citations of scientific publications and scientometrics [ 188 , 189 ]; global optimization techniques [ 190 ...…”

Section: Non-boltzmannian Entropy Measures and Distributionsmentioning

confidence: 99%

Beyond Boltzmann–Gibbs–Shannon in Physics and Elsewhere

Tsallis

2019

Entropy

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The pillars of contemporary theoretical physics are classical mechanics, Maxwell electromagnetism, relativity, quantum mechanics, and Boltzmann–Gibbs (BG) statistical mechanics –including its connection with thermodynamics. The BG theory describes amazingly well the thermal equilibrium of a plethora of so-called simple systems. However, BG statistical mechanics and its basic additive entropy S B G started, in recent decades, to exhibit failures or inadequacies in an increasing number of complex systems. The emergence of such intriguing features became apparent in quantum systems as well, such as black holes and other area-law-like scenarios for the von Neumann entropy. In a different arena, the efficiency of the Shannon entropy—as the BG functional is currently called in engineering and communication theory—started to be perceived as not necessarily optimal in the processing of images (e.g., medical ones) and time series (e.g., economic ones). Such is the case in the presence of generic long-range space correlations, long memory, sub-exponential sensitivity to the initial conditions (hence vanishing largest Lyapunov exponents), and similar features. Finally, we witnessed, during the last two decades, an explosion of asymptotically scale-free complex networks. This wide range of important systems eventually gave support, since 1988, to the generalization of the BG theory. Nonadditive entropies generalizing the BG one and their consequences have been introduced and intensively studied worldwide. The present review focuses on these concepts and their predictions, verifications, and applications in physics and elsewhere. Some selected examples (in quantum information, high- and low-energy physics, low-dimensional nonlinear dynamical systems, earthquakes, turbulence, long-range interacting systems, and scale-free networks) illustrate successful applications. The grounding thermodynamical framework is briefly described as well.

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An alternative interpretation of the ultracold methylhydroxycarbene rearrangement mechanism: cooperative effects

Cited by 7 publications

References 59 publications

Atmospheric Simulation Chamber Studies of the Gas-Phase Photolysis of Pyruvic Acid

Atmospheric Simulation Chamber Studies of the Gas-Phase Photolysis of Pyruvic Acid

Kinetics of low-temperature transitions and a reaction rate theory from non-equilibrium distributions

Beyond Boltzmann–Gibbs–Shannon in Physics and Elsewhere

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