Identity Proton-Transfer Reactions from C−H, N−H, and O−H Acids. An ab Initio, DFT, and CPCM-B3LYP Aqueous Solvent Model Study

Keeffe, James R.; Gronert, Scott; Colvin, Michael E.; Tran, Ngoc L.

doi:10.1021/ja0356683

Cited by 53 publications

(74 citation statements)

References 59 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…The valence bond picture of such transition states reveals that the height of the barrier depends on the energy of the structure Y − ⋅⋅H + ⋅⋅X − , and that its energy is stabilized by the electrostatic interaction between the central proton and the X and Y groups 23. Ab initio calculations also support the stabilization of the transition state by an increase in the charge on the in‐flight hydrogen in the transition state, or equivalently, as reaction termini X and Y become more electronegative 25…”

Section: Resultsmentioning

confidence: 81%

Absolute Rate Calculations: Atom and Proton Transfers in Hydrogen‐Bonded Systems

2005

View full text Add to dashboard Cite

We calculate energy barriers of atom‐ and proton‐transfer reactions in hydrogen‐bonded complexes in the gas phase. Our calculations do not involve adjustable parameters and are based on bond‐dissociation energies, ionization potentials, electron affinities, bond lengths, and vibration frequencies of the reactive bonds. The calculated barriers are in agreement with experimental data and high‐level ab initio calculations. We relate the height of the barrier with the molecular properties of the reactants and complexes. The structure of complexes with strong hydrogen bonds approaches that of the transition state, and substantially reduces the barrier height. We calculate the hydrogen‐abstraction rates in H‐bonded systems using the transition‐state theory with the semiclassical correction for tunneling, and show that they are in excellent agreement with the experimental data. H‐bonding leads to an increase in tunneling corrections at room temperature.

show abstract

Section: Resultsmentioning

confidence: 81%

Absolute Rate Calculations: Atom and Proton Transfers in Hydrogen‐Bonded Systems

2005

View full text Add to dashboard Cite

show abstract

“…The solvent effect is included in both optimization and single point calculations through the polarized continuum using the conductor polarizable continuum model (CPCM) [57][58][59][60][61] with tetrahydrofuran (THF) dielectric. Density functional theory calculations are performed with hybrid parameter B3LYP as implemented in Gaussian 09W.…”

Section: Computational Detailsmentioning

confidence: 99%

The Role of Carbonate and Sulfite Additives in Propylene Carbonate-Based Electrolytes on the Formation of SEI Layers at Graphitic Li-Ion Battery Anodes

Bhatt¹,

O’Dwyer²

2014

J. Electrochem. Soc.

View full text Add to dashboard Cite

Density functional theory (DFT) was used to investigate the effect of electrolyte additives such as vinylene carbonate (VC), vinyl ethylene carbonate (VEC), vinyl ethylene sulfite (VES), and ethylene sulfite (ES) in propylene carbonate (PC)-based Li-ion battery electrolytes on SEI formation at graphitic anodes. The higher desolvation energy of PC limits Li + intercalation into graphite compared to solvated Li + in EC. Li + (PC) 3 clusters are found to be unstable with graphite intercalation compounds and become structurally deformed, preventing decomposition mechanisms and associated SEI formation in favor of co-intercalation that leads to exfoliation. DFT calculations demonstrate that the reduction decomposition of PC and electrolyte additives is such that the first electron reduction energies scale as ES > VES > VEC >PC. The second electron reduction follows ES > VES > VEC > VC > PC. The reactivity of the additives under consideration follows ES > VES > VEC > VC. The data demonstrate the supportive role of certain additives, particularly sulfites, in PC-based electrolytes for SEI film formation and stable cycling at graphitic carbon-based Li-ion battery anodes without exfoliation or degradation of the anode structure. The lithium ion battery has been one of the primary power sources driving the digital age, and witnessed a resurgence in interest with the advent of nanoscale materials and advances in cell performance. [1][2][3][4][5][6] Much of the processes and mechanisms underpinning carbonate-based electrolytes in Li-ion batteries, particularly at the anode, still need to be resolved. 7,8 Some commonly used organic solvents are ethylene carbonate (EC), propylene carbonate (PC), dimethyl carbonate (DMC), diethyl carbonate (DEC), and ethyl methyl carbonate (EMC) etc. These organic electrolytes are decomposed during intercalation of lithium ions into graphite anode, resulting in the formation of the crucial solid electrolyte interphase (SEI) film. [9][10][11] This film plays an important role in determining capacity retention, cycle life and safety concerns in lithium ion batteries.12,13 SEI films typically comprise Li 2 O, Li 2 CO 3 and related carbonates, LiF (depending on salt used), and polymer phases together with olefins.14 Effective SEI films provide stable surface passivation without significant reduction in electron conduction (higher transfer resistance). On carbon (graphite) anodes, stable SEI films are crucial for stable cycling and are formed below ∼0.8 V vs. Li + /Li. In practical applications of lithium-ion batteries, the selection of the electrode material is critical, particularly when using high surface area nanomaterials. 15 Enhanced chemical stability against electrolyte oxidation and reduction, high ionic conductivity, high boiling points, and low melting points are required, as well as the ability to solvate a wide range of lithium salts such as LiPF 6 , LiBF 4 or LiClO 4 , 16-21 in aprotic and organic solvents such as ethylene carbonate (EC), propylene carbonate (PC), their mixtures, and ...

show abstract

“…To do this, we use acidities as measured by the calculated Δ H ACID values for the R–CH 3 compounds shown in Table 7, taking advantage of a previously established relationship between calculated (MP2/6-311+G**) Δ H ACID values 28 and gas-phase substituent constants. 29 The acids considered here are two singlet carbenes and 6-methylfulvene.…”

Section: Gas-phase Proton Affinity Measurementmentioning

confidence: 99%

“…By this measure, the electron-withdrawing group (EWG) order is CH ≥ CCH 3 > fulvenyl. We can then estimate the resonance portion of the electron withdrawing effects in the form of the gas phase resonance substituent constant, σ R- 29 using an established three-parameter correlation obtained for Δ H ACID values obtained in earlier work, 28 given here as eq 1, and in which the resonance effect, ρ R – = 143.2, is seen to be dominant.…”

Section: Gas-phase Proton Affinity Measurementmentioning

confidence: 99%

Effect of Allylic Groups on S_N2 Reactivity

et al. 2014

Self Cite

View full text Add to dashboard Cite

The activating effects of the benzyl and allyl groups on SN2 reactivity are well-known. 6-Chloromethyl-6-methylfulvene, also a primary, allylic halide, reacts 30 times faster with KI/acetone than does benzyl chloride at room temperature. The latter result, as well as new experimental observations, suggests that the fulvenyl group is a particularly activating allylic group in SN2 reactions. Computational work on identity SN2 reactions, e.g., chloride– displacing chloride– and ammonia displacing ammonia, shows that negatively charged SN2 transition states (tss) are activated by allylic groups according to the Galabov–Allen–Wu electrostatic model but with the fulvenyl group especially effective at helping to delocalize negative charge due to some cyclopentadienide character in the transition state (ts). In contrast, the triafulvenyl group is deactivating. However, the positively charged SN2 transition states of the ammonia reactions are dramatically stabilized by the triafulvenyl group, which directly conjugates with a reaction center having SN1 character in the ts. Experiments and calculations on the acidities of a variety of allylic alcohols and carboxylic acids support the special nature of the fulvenyl group in stabilizing nearby negative charge and highlight the ability of fulvene species to dramatically alter the energetics of processes even in the absence of direct conjugation.

show abstract

Identity Proton-Transfer Reactions from C−H, N−H, and O−H Acids. An ab Initio, DFT, and CPCM-B3LYP Aqueous Solvent Model Study

Cited by 53 publications

References 59 publications

Absolute Rate Calculations: Atom and Proton Transfers in Hydrogen‐Bonded Systems

Absolute Rate Calculations: Atom and Proton Transfers in Hydrogen‐Bonded Systems

The Role of Carbonate and Sulfite Additives in Propylene Carbonate-Based Electrolytes on the Formation of SEI Layers at Graphitic Li-Ion Battery Anodes

Effect of Allylic Groups on S_N2 Reactivity

Contact Info

Product

Resources

About

Identity Proton-Transfer Reactions from C−H, N−H, and O−H Acids. An ab Initio, DFT, and CPCM-B3LYP Aqueous Solvent Model Study

Cited by 53 publications

References 59 publications

Absolute Rate Calculations: Atom and Proton Transfers in Hydrogen‐Bonded Systems

Absolute Rate Calculations: Atom and Proton Transfers in Hydrogen‐Bonded Systems

The Role of Carbonate and Sulfite Additives in Propylene Carbonate-Based Electrolytes on the Formation of SEI Layers at Graphitic Li-Ion Battery Anodes

Effect of Allylic Groups on SN2 Reactivity

Contact Info

Product

Resources

About

Effect of Allylic Groups on S_N2 Reactivity