Molecular Dynamics Simulation of C–C Bond Scission in Polyethylene and Linear Alkanes: Effects of the Condensed Phase

Попов, К. В.; Knyazev, Vadim D.

doi:10.1021/jp411474u

Cited by 10 publications

(16 citation statements)

References 27 publications

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“…These computational approximations were able to illustrate a highly complex chemical reaction network, emphasizing the most important reaction pathways. The results obtained from the kinetic analysis are detailed in Table 2, which is also consistent with other work in this field [93]. These significant insights present a better understanding required to tune the reaction parameters and implement plastic-to-fuel technologies.…”

Section: Quantum Mechanics For Plastic Pyrolysissupporting

confidence: 84%

Application of computational approach in plastic pyrolysis kinetic modelling: a review

Armenise

Wong

Ramírez-Velásquez

et al. 2021

Reac Kinet Mech Cat

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During the past decade, pyrolysis routes have been identified as one of the most promising solutions for plastic waste management. However, the industrial adoption of such technologies has been limited and several unresolved blind spots hamper the commercial application of pyrolysis. Despite many years and efforts to explain pyrolysis models based on global kinetic approaches, recent advances in computational modelling such as machine learning and quantum mechanics offer new insights. For example, the kinetic and mechanistic information about plastic pyrolysis reactions necessary for scaling up processes is unravelling. This selective literature review reveals some of the foundational knowledge and accurate views on the reaction pathways, product yields, and other features of pyrolysis created by these new tools. Pyrolysis routes mapped by machine learning and quantum mechanics will gain more relevance in the coming years, especially studies that combine computational models with different time and scale resolutions governed by “first principles.” Existing research suggests that, as machine learning is further coupled to quantum mechanics, scientists and engineers will better predict products, yields, and compositions, as well as more complicated features such as ideal reactor design.

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Section: Quantum Mechanics For Plastic Pyrolysissupporting

confidence: 84%

Application of computational approach in plastic pyrolysis kinetic modelling: a review

Armenise

Wong

Ramírez-Velásquez

et al. 2021

Reac Kinet Mech Cat

View full text Add to dashboard Cite

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“…The simulations were performed at constant temperature, pressure and number of particles. The temperature of the protein, lipid and solvent (waters and ions) were separately coupled using the Nosé-Hoover thermostat ( Popov and Knyazev, 2014 ) at 310°K, with a coupling constant, τ T = 0.1 ps. System pressures were semi-isotropically coupled using the Parrinello-Rahman barostat ( Parrinello and Rahman, 1981 ) at 1 bar with a coupling constant, τ P = 1 ps and compressibility = 4.5 × 10 –5 bar −1 .…”

Section: Methodsmentioning

confidence: 99%

Proton currents constrain structural models of voltage sensor activation

Randolph

Mokrab

Bennett

et al. 2016

eLife

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The Hv1 proton channel is evidently unique among voltage sensor domain proteins in mediating an intrinsic ‘aqueous’ H+ conductance (GAQ). Mutation of a highly conserved ‘gating charge’ residue in the S4 helix (R1H) confers a resting-state H+ ‘shuttle’ conductance (GSH) in VGCs and Ci VSP, and we now report that R1H is sufficient to reconstitute GSH in Hv1 without abrogating GAQ. Second-site mutations in S3 (D185A/H) and S4 (N4R) experimentally separate GSH and GAQ gating, which report thermodynamically distinct initial and final steps, respectively, in the Hv1 activation pathway. The effects of Hv1 mutations on GSH and GAQ are used to constrain the positions of key side chains in resting- and activated-state VS model structures, providing new insights into the structural basis of VS activation and H+ transfer mechanisms in Hv1.DOI: http://dx.doi.org/10.7554/eLife.18017.001

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“…The study on polymer combustion and fire retardancy is a complex multidisciplinary topic, encompassing physical and chemical phenomena occurring in the gas and condensed phase. Thus, aspects involved are physical chemistry of flames and thermal degradation of polymers, respectively [33]. Combustion and flammability of polymeric materials are important topics of practical interest directly related to fire safety [34].…”

Section: Recent Developments In Different Techniquesmentioning

confidence: 99%

Advances in Flame Retardant of Different Types of Nanocomposites

Visakh

2015

Flame Retardants

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The present chapter deals with a brief account on various types topics in flame retardant of polymer nanocomposites. This chapter discussed with different topics such as flame retardancy of polymer nanocomposite, recent developments in different techniques used for the flame retardancy, recent development of phosphorus flame retardants in thermoplastic blends and nanocomposites, non-halogen flame retardants in epoxy-based composites and nanocomposites, flame retardant/ resistant based nanocomposites in textile, flame retardants in bitumens and nanocomposites, fire retardant for phase change material, flame retardant finishing for textiles, flame retardant of cellulosic materials and their composites. Flame Retardancy of Polymer NanocompositeFrom the application view polymers are very flammable materials, for preventing this flammability, scientists need to improve polymer fire retardancies, and this is a major challenging. Developing the effective environmentally friendly flame retardants is challenging. Because of this materials are very hazardous; they are widely used owing to their effectiveness and low cost. Flame retardant nanocomposites with conventional fire retardants to develop more-efficient materials showing improved mechanical properties. There are numerous nanofiller/conventionalfire-retardant already prepared. From some of the work related to CNTs shows that improve the flammable properties of nanocomposites also improved the mechanical properties such as electrical, thermal properties. Nanofiller-based flame retardants show high flame-retardant efficiencies. Nanofiller can reduce the peak heat release rates (PHRRs) of polymers and thus reduce the speed at which

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Molecular Dynamics Simulation of C–C Bond Scission in Polyethylene and Linear Alkanes: Effects of the Condensed Phase

Cited by 10 publications

References 27 publications

Application of computational approach in plastic pyrolysis kinetic modelling: a review

Application of computational approach in plastic pyrolysis kinetic modelling: a review

Proton currents constrain structural models of voltage sensor activation

Advances in Flame Retardant of Different Types of Nanocomposites

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