A computational study of the chlorination and hydroxylation of amines by hypochlorous acid

Šakić, Davor; Hanževački, Marko; Smith, David M.; Vrček, Valerije

doi:10.1039/c5ob01823d

Cited by 27 publications

(5 citation statements)

References 80 publications

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“…The net result is a mild increase of NCl 3 under higher RH (Fig. 2d,f), consistent with theoretical predictions 34,35 that suggest water is indispensable for ammonia chlorination favored over hydroxylation when reacting with free chlorines. Atmospheric NCl 3 formation could thus be promoted under high RH when aerosols tend to be highly hygroscopic and deliquescent, exhibiting liquid-like properties.…”

Section: Chemical Mechanism Of Ncl 3 Aqueous-phase Productionsupporting

confidence: 88%

Aqueous-phase chloramine production as a missing chain in atmospheric chlorine chemistry

Jiang,

Chen,

Xia

et al. 2024

Preprint

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Chlorine radical (Cl·) profoundly impacts atmospheric oxidation capacity, and therefore climate change and air pollution. Chloramines, especially trichloramine (NCl3), is a potentially important Cl· source, while their formation mechanism remains elusive. Here, we present evidence of aerosol aqueous-phase production of chloramines with observations in Beijing and develop a comprehensive box model which incorporates ~40 aerosol aqueous reactions initiated by Cl2 and NH3 and multiple phase transfer processes. The model can well reproduce the diurnal variation of NCl3. We show that this atmospheric production of chloramines could be ubiquitous globally with the co-existence of aerosol water, Cl2, and NH3, while NCl3 formation is mainly influenced by Cl2 and relative humidity as NH3 is typically in great excess. The contribution of chloramines (mostly NCl3) to Cl· production is much higher in clean periods (up to 85%) than polluted periods (~5%) in Beijing, and in clean environments (e.g., ~64% in Canada) than polluted areas (e.g., ~1% in India). Therefore, chloramines can play an increasingly important role in a cleaner future and may partially offset the on-going efforts on air pollution mitigation. The missing representation of chloramines in current models could significantly underestimate the climate, health and ecological impacts of Cl·.

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Section: Chemical Mechanism Of Ncl 3 Aqueous-phase Productionsupporting

confidence: 88%

Aqueous-phase chloramine production as a missing chain in atmospheric chlorine chemistry

Jiang,

Chen,

Xia

et al. 2024

Preprint

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“…In H 2 O, the N62-H85 distance was increased (d=1.68 Å) and more directional (N62…H85-O10 = 178 A), whereas the O10-H85 hydrogen bond was slightly decreases (d=0.99 Å). The binding constant of the Neu5Ac-ClQOH + ( Table 2 ) in water increased (-20.4 kcal/mol), which attributed to the decreasing the proton-transfer energy barrier in presence of water molecules [ 42 , 43 ]. However, Neu5Ac-ClQOH + - II was stabilized by a set of hydrogen bonding and vdW short contact, which facilitate the encapsulation of Neu5Ac by ClQOH + ( Fig.…”

Section: Resultsmentioning

confidence: 99%

Chloroquine and hydroxychloroquine inhibitors for COVID-19 sialic acid cellular receptor: Structure, hirshfeld atomic charge analysis and solvent effect

Altalhi

Alswat

Alsanie

et al. 2021

Journal of Molecular Structure

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Highlights Molecular interactions between sialic acid (Neu5Ac) with Chloroquine (ClQ) and hydroxychloroquine (ClQOH) in the gas phase and water. Water facilitates the charge transfer from Neu5Ac to ClQ and ClQOH that enhanced molecular recognition. The monoprotonated forms Neu5Ac-ClQ + and Neu5Ac-ClQOH + were the most stable adducts. Hydrogen bonding dominated the molecular recognition forces for the molecule adducts, except Neu5Ac-ClQOH + that stabilized by the proton transfer process.

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“…The initial structures of molecular complexes were generated randomly using the “kick” algorithm 45 . Geometry optimizations have been performed using the (U)B3LYP hybrid functional, either alone or complemented by the D3 dispersion correction 44 .…”

Section: Methodsmentioning

confidence: 99%

The stability of oxygen‐centered radicals and its response to hydrogen bonding interactions

Korotenko,

Zipse

2023

J Comput Chem

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The stability of various alkoxy/aryloxy/peroxy radicals, as well as TEMPO and triplet dioxygen (3O2) has been explored at a variety of theoretical levels. Good correlations between RSEtheor and RSEexp are found for hybrid DFT methods, for compound schemes such as G3B3‐D3, and also for DLPNO‐CCSD(T) calculations. The effects of hydrogen bonding interactions on the stability of oxygen‐centered radicals have been probed by addition of a single solvating water molecule. While this water molecule always acts as a H‐bond donor to the oxygen‐centered radical itself, it can act as a H‐bond donor or acceptor to the respective closed‐shell parent.

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A computational study of the chlorination and hydroxylation of amines by hypochlorous acid

Cited by 27 publications

References 80 publications

Aqueous-phase chloramine production as a missing chain in atmospheric chlorine chemistry

Aqueous-phase chloramine production as a missing chain in atmospheric chlorine chemistry

Chloroquine and hydroxychloroquine inhibitors for COVID-19 sialic acid cellular receptor: Structure, hirshfeld atomic charge analysis and solvent effect

The stability of oxygen‐centered radicals and its response to hydrogen bonding interactions

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