Establishing the structural motifs present in small ammonium and aminium bisulfate clusters of relevance to atmospheric new particle formation

Kreinbihl, John; Frederiks, Nicoline; Waller, Sarah E.; Yang, Yi; Johnson, Christopher J.

doi:10.1063/5.0015094

Cited by 18 publications

(41 citation statements)

References 73 publications

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“…Scaling harmonic frequencies or calculating anharmonic frequencies is critical for spectroscopists who are trying to locate hydrogen-bonded molecular clusters in their experiments. ,, Yet, previous work has indicated that scaling has less impact on the resulting Gibbs free energy of formation values. ,, At the suggestion of a reviewer, we investigated this point by computing the effects of scaling frequencies on the thermodynamics of formation of structure T2, the DFT global minimum for Gibbs free energy. Truhlar and co-workers have shown that scaling M08-HX/MG3S harmonic frequencies by a factor of 0.973 yields accurate zero-point vibrational energy (ZPE) values for a comprehensive database of molecules …”

Section: Results and Discussionmentioning

confidence: 99%

Calculating Reliable Gibbs Free Energies for Formation of Gas-Phase Clusters that Are Critical for Atmospheric Chemistry: (H₂SO₄)₃

2021

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The effects of atmospheric aerosols on our climate are one of the biggest uncertainties in global climate models. Calculating the pathway for the formation of prenucleation clusters that become aerosols is challenging, requiring a comprehensive analysis of configurational space and highly accurate Gibbs free energy calculations. We identified a large set of minimum energy configurations of (H 2 SO 4 ) 3 using a sampling technique based on a genetic algorithm and a stepwise density functional theory (DFT) approach and computed the thermodynamics of formation of these configurations with more accurate wavefunction-based electronic energies computed on the DFT geometries. The DLPNO-CCSD(T) methods always return more positive energies compared to the DFT energies. Within the DLPNO-CCSD(T) methods, extrapolating to the complete basis set limit gives more positive free energies compared to explicitly correlated single-point energies. The CBS extrapolation was shown to be robust as both the 4-5 inverse polynomial and Riemann zeta function schemes were within chemical accuracy of one another.

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Section: Results and Discussionmentioning

confidence: 99%

Calculating Reliable Gibbs Free Energies for Formation of Gas-Phase Clusters that Are Critical for Atmospheric Chemistry: (H₂SO₄)₃

2021

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“…Atmospheric aerosol particles represent the largest uncertainty in our understanding of global climate through their participation in cloud formation and the absorption and scattering of radiation (Kerminen et al, 2005;Kuang et al, 2009;Lohmann and Feichter, 2005;Merikanto et al, 2009;Spracklen et al, 2008). In particular, particle formation by nucleation is still not well understood and is difficult to represent in models (Kerminen et al, 2018).…”

Section: Introductionmentioning

confidence: 99%

A predictive model for salt nanoparticle formation using heterodimer stability calculations

2021

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Abstract. Acid–base clusters and stable salt formation are critical drivers of new particle formation events in the atmosphere. In this study, we explore salt heterodimer (a cluster of one acid and one base) stability as a function of gas-phase acidity, aqueous-phase acidity, heterodimer proton transference, vapor pressure, dipole moment and polarizability for salts comprised of sulfuric acid, methanesulfonic acid and nitric acid with nine bases. The best predictor of heterodimer stability was found to be gas-phase acidity. We then analyzed the relationship between heterodimer stability and J4×4, the theoretically predicted formation rate of a four-acid, four-base cluster, for sulfuric acid salts over a range of monomer concentrations from 105 to 109 molec cm−3 and temperatures from 248 to 348 K and found that heterodimer stability forms a lognormal relationship with J4×4. However, temperature and concentration effects made it difficult to form a predictive expression of J4×4. In order to reduce those effects, heterodimer concentration was calculated from heterodimer stability and yielded an expression for predicting J4×4 for any salt, given approximately equal acid and base monomer concentrations and knowledge of monomer concentration and temperature. This parameterization was tested for the sulfuric acid–ammonia system by comparing the predicted values to experimental data and was found to be accurate within 2 orders of magnitude. We show that one can create a simple parameterization that incorporates the dependence on temperature and monomer concentration on J4×4 by defining a new term that we call the normalized heterodimer concentration, Φ. A plot of J4×4 vs. Φ collapses to a single monotonic curve for weak sulfate salts (difference in gas-phase acidity >95 kcal mol−1) and can be used to accurately estimate J4×4 within 2 orders of magnitude in atmospheric models.

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“…When performing calculations on clusters where hydrogen bonding plays a key role, it is crucial to keep in mind the importance of scaling harmonic frequencies or calculating anharmonic frequencies. − In previous research, we have used Truhlar’s M08-HX/MG3S scaling factor (0.973) and applied it to the thermodynamics of formation for our lowest Gibbs free energy clusters and compared the resulting data to unscaled data. , Our group found the changes in the thermodynamic corrections used to compute the Gibbs free energy of formation to be negligible (about 0.19 kcal mol –1 ), and this conclusion is supported by similar studies. ,, We also checked the effects of applying the quasiharmonic approximation, which applies scaling factors to low-frequency vibrational modes in the partition function, and found no significant effect …”

Section: Resultsmentioning

confidence: 99%

Monomers of Glycine and Serine Have a Limited Ability to Hydrate in the Atmosphere

et al. 2021

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The role of atmospheric aerosols on climate change is one of the biggest uncertainties in most global climate models. Organic aerosols have been identified as potential cloud condensation nuclei (CCN), and amino acids are organic molecules that could serve as CCN. Amino acids make up a significant portion of the total organic material in the atmosphere, and herein we present a systematic study of hydration for two of the most common atmospheric amino acids, glycine and serine. We compute DLPNO/CCSD(T)//M08-HX/ MG3S thermodynamic properties and atmospheric concentrations of Gly(H 2 O) n and Ser(H 2 O) n , where n = 1−5. We predict that serine−water clusters have higher concentrations at n = 1 and 5, while glycine−water clusters have higher concentrations at n = 2−4. However, both glycine and serine are inferred to exist primarily in their nonhydrated monomer forms in the absence of other species such as sulfuric acid.

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Establishing the structural motifs present in small ammonium and aminium bisulfate clusters of relevance to atmospheric new particle formation

Cited by 18 publications

References 73 publications

Calculating Reliable Gibbs Free Energies for Formation of Gas-Phase Clusters that Are Critical for Atmospheric Chemistry: (H₂SO₄)₃

Calculating Reliable Gibbs Free Energies for Formation of Gas-Phase Clusters that Are Critical for Atmospheric Chemistry: (H₂SO₄)₃

A predictive model for salt nanoparticle formation using heterodimer stability calculations

Monomers of Glycine and Serine Have a Limited Ability to Hydrate in the Atmosphere

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Establishing the structural motifs present in small ammonium and aminium bisulfate clusters of relevance to atmospheric new particle formation

Cited by 18 publications

References 73 publications

Calculating Reliable Gibbs Free Energies for Formation of Gas-Phase Clusters that Are Critical for Atmospheric Chemistry: (H2SO4)3

Calculating Reliable Gibbs Free Energies for Formation of Gas-Phase Clusters that Are Critical for Atmospheric Chemistry: (H2SO4)3

A predictive model for salt nanoparticle formation using heterodimer stability calculations

Monomers of Glycine and Serine Have a Limited Ability to Hydrate in the Atmosphere

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Product

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Calculating Reliable Gibbs Free Energies for Formation of Gas-Phase Clusters that Are Critical for Atmospheric Chemistry: (H₂SO₄)₃

Calculating Reliable Gibbs Free Energies for Formation of Gas-Phase Clusters that Are Critical for Atmospheric Chemistry: (H₂SO₄)₃