Co-reporter:Ryan J. Yoder, Qinggeng Zhuang, Jeremy M. Beck, Andrew Franjesevic, Travis G. Blanton, Sydney Sillart, Tyler Secor, Leah Guerra, Jason D. Brown, Carolyn Reid, Craig A. McElroy, Özlem Doğan Ekici, Christopher S. Callam, and Christopher M. Hadad
ACS Medicinal Chemistry Letters June 8, 2017 Volume 8(Issue 6) pp:622-622
Publication Date(Web):May 8, 2017
DOI:10.1021/acsmedchemlett.7b00037
Acetylcholinesterase (AChE) is an essential enzyme that can be targeted by organophosphorus (OP) compounds, including nerve agents. Following exposure to OPs, AChE becomes phosphylated (inhibited) and undergoes a subsequent aging process where the OP–AChE adduct is dealkylated. The aged AChE is unable to hydrolyze acetylcholine, resulting in accumulation of the neurotransmitter in the central nervous system (CNS) and elsewhere. Current therapeutics are only capable of reactivating inhibited AChE. There are no known therapeutic agents to reverse the aging process or treat aged AChE. Quinone methides (QMs) have been shown to alkylate phosphates under physiological conditions. In this study, a small library of novel quinone methide precursors (QMPs) has been synthesized and examined as potential alkylating agents against model nucleophiles, including a model phosphonate. Computational studies have been performed to evaluate the affinity of QMPs for the aged AChE active site, and preliminary testing with electric eel AChE has been performed.Keywords: Acetylcholinesterase; organophosphorus chemical nerve agents; quinone methide;
Co-reporter:Sonia S. So, Shameema Oottikkal, Jovica D. Badjić, Christopher M. Hadad, and Anita E. Mattson
The Journal of Organic Chemistry 2014 Volume 79(Issue 11) pp:4832-4842
Publication Date(Web):May 5, 2014
DOI:10.1021/jo500698q
The power of hydrogen-bond donor catalysis has been harnessed to elicit and control carbene-like reactivity from nitrodiazoesters. Specifically, select ureas have been identified as effective catalysts for N–H insertion and multicomponent coupling reactions of nitrodiazoesters, anilines, and aromatic nucleophiles, thereby preparing a variety of α-aryl glycines in high yield. Experimental and computational studies designed to probe the plausible reaction pathways suggest that difluoroboronate ureas are particularly well-suited to catalyze reactions of nitrodiazoesters with a range of anilines through a polar reaction pathway. Urea-facilitated loss of nitrite followed by addition of a nucleophile conceivably generates the observed aryl glycine products.
Co-reporter:Gotard Burdzinski, Hoi Ling Luk, Carolyn S. Reid, Yunlong Zhang, Christopher M. Hadad, and Matthew S. Platz
The Journal of Physical Chemistry A 2013 Volume 117(Issue 22) pp:4551-4555
Publication Date(Web):May 10, 2013
DOI:10.1021/jp4003406
The photochemistry of 4,5-carbomethoxy-1,2,3-thiadiazole in solution was studied at room temperature with use of UV–vis and IR transient absorption spectroscopies (λex = 266 nm). Ultrafast time-resolved techniques demonstrate that there is a very fast rise (<0.4 ps) of bis(carbomethoxy)thiirene in acetonitrile, and that it is the only intermediate formed. The lifetime of the thiirene is limited by dimerization to eventually form tetra(carbomethoxy)thiophene.
Co-reporter:Yian Ruan, Hashem A. Taha, Ryan J. Yoder, Veselin Maslak, Christopher M. Hadad, and Jovica D. Badjić
The Journal of Physical Chemistry B 2013 Volume 117(Issue 11) pp:3240-3249
Publication Date(Web):February 27, 2013
DOI:10.1021/jp401841w
We designed, prepared, and characterized three cup-shaped cavitands 1–3 for trapping organophosphonates (O═PR(OR′)2, 118–197 Å3) whose shape and size correspond to G-type chemical warfare agents (132–186 Å3). With the assistance of computational (molecular dynamics) and experimental (1H NMR spectroscopy) methods, we found that host [1–H3]3+ orients its protonated histamine residues at the rim outside the cavity, in bulk water. In this unfolded form, the cavitand traps a series of organophosphonates 5–13 (Kapp = 87 ± 1 to 321 ± 6 M–1 at 298.0 K), thereby placing the P–CH3 functional group in the inner space of the host. A comparison of experimental and computed 1H NMR chemical shifts of both hosts and guests allowed us to derive structure–activity relationships and deduce that, upon the complexation, the more sizable P–OR functional groups in guests drive organophosphonates to the northern portion of the basket [1–H3]3+. This, in turn, causes a displacement of the guest’s P–CH3 group and a contraction of the cup-shaped scaffold. The proposed induced-fit model of the recognition is important for turning these modular hosts into useful receptors capable of a selective detection/degradation of organophosphorus nerve agents.
Co-reporter:Xiaoguang Bao;Xiaowa Nie;Dieter von Deak;Elizabeth J. Biddinger
Topics in Catalysis 2013 Volume 56( Issue 18-20) pp:1623-1633
Publication Date(Web):2013 December
DOI:10.1007/s11244-013-0097-z
Density functional theory (DFT) was used to investigate O2 chemisorption on the edge sites of graphene doped with quaternary nitrogen (N-graphene). The location of the doped quaternary N within the graphene cluster was systematically varied to determine the effect of interior versus edge doping on the reactivity of the edge graphene sites. Model 1b, where a quaternary-N atom is at the zigzag edge of the graphene cluster, is found to be the most favored structure and strongly adsorbs O2 molecule via a “two feet” geometry. For this most stable O2 binding configuration, the potential-dependent free energy of reaction for the subsequent oxygen reduction reaction (ORR) steps was evaluated. The favored four electron-proton transfer mechanism passes through a dissociative O*+OH* state instead of an OOH* intermediate, followed by a series of reduction steps to produce water. At the equilibrium potential for ORR of 1.23 V-NHE, the protonation of O* and OH* both show uphill steps, but the production of O* is facile with a small overpotential. An applied potential of −0.15 V-NHE is required to facilitate the protonation of OH* to water, a larger overpotential than observed experimentally. While solvent effects may reduce this overpotential, our results suggest that the edge of the N-graphene is very active towards activation of O2 and production of O* and OH* but because of strong binding of the oxygen atom, the subsequent steps of the ORR reaction will be hindered. Mechanisms that have OH* formed at the edge site and then move to adjacent sites for more facile protonation will have to be explored in the future.
Co-reporter:Jacek Kubicki ; Hoi Ling Luk ; Yunlong Zhang ; Shubham Vyas ; Huo-Lei Peng ; Christopher M. Hadad ;Matthew S. Platz
Journal of the American Chemical Society 2012 Volume 134(Issue 16) pp:7036-7044
Publication Date(Web):April 1, 2012
DOI:10.1021/ja212085d
The photochemistry of 2-naphthylsulfonyl azide (2-NpSO2N3) was studied by femtosecond time-resolved infrared (TR-IR) spectroscopy and with quantum chemical calculations. Photolysis of 2-NpSO2N3 with 330 nm light promotes 2-NpSO2N3 to its S1 state. The S1 excited state has a prominent azide vibrational band. This is the first direct observation of the S1 state of a sulfonyl azide, and this vibrational feature allows a mechanistic study of its decay processes. The S1 state decays to produce the singlet nitrene. Evidence for the formation of the pseudo-Curtius rearrangement product (2-NpNSO2) was inconclusive. The singlet sulfonylnitrene 1(2-NpSO2N) is a short-lived species (τ ≈ 700 ± 300 ps in CCl4) that decays to the lower-energy and longer-lived triplet nitrene 3(2-NpSO2N). Internal conversion of the S1 excited state to the ground state S0 is an efficient deactivation process. Intersystem crossing of the S1 excited state to the azide triplet state contributes only modestly to deactivation of the S1 state of 2-NpSO2N3.
Co-reporter:Peng Tao, Jon R. Parquette, and Christopher M. Hadad
Journal of Chemical Theory and Computation 2012 Volume 8(Issue 12) pp:5137-5149
Publication Date(Web):August 30, 2012
DOI:10.1021/ct2009335
Some unnatural polymers/oligomers have been designed to adopt a well-defined, compact, three-dimensional folding capability. Azobenzene units are common linkages in these oligomer designs. Two alternating pyridinedicarboxamide/m-(phenylazo)azobenzene oligomers that can fold into both right- and left-handed helices were studied computationally in order to understand their dynamical properties. Helical structures were shown to be the global minima among the many different conformations generated from the Monte Carlo simulations, and extended conformations have higher potential energies than compact ones. To understand the interconversion process between right- and left-handed helices, replica-exchange molecular dynamic (REMD) simulations were performed on both oligomers, and with this method, both right- and left-handed helices were successfully sampled during the simulations. REMD trajectories revealed twisted conformations as intermediate structures in the interconversion pathway between the two helical forms of these azobenzene oligomers. This mechanism was observed in both oligomers in current study and occurred locally in the larger oligomer. This discovery indicates that the interconversion between helical structures with different handedness goes through a compact and partially folded structure instead of globally unfold and extended structure. This is also verified by the nudged elastic band (NEB) calculations. The temperature weighted histogram analysis method (T-WHAM) was applied on the REMD results to generate contour maps of the potential of mean force (PMF). Analysis showed that right- and left-handed helices are equally sampled in these REMD simulations. In large oligomers, both right- and left-handed helices can be adopted by different parts of the molecule simultaneously. The interconversion between two helical forms can occur in the middle of the helical structure and not necessarily at the termini of the oligomer.
Co-reporter:Shubham Vyas;Jacek Kubicki;Hoi Ling Luk;Yunlong Zhang;Nina P. Gritsan;Christopher M. Hadad;Matthew S. Platz
Journal of Physical Organic Chemistry 2012 Volume 25( Issue 8) pp:693-703
Publication Date(Web):
DOI:10.1002/poc.2903
The photochemistry of pivaloyl, benzoyl, 4-phenylbenzoyl, and 2-anthroyl azides has been studied using femtosecond (fs) time-resolved infrared (TRIR) and UV–vis spectroscopy and interpreted with the aid of computational chemistry. Density functional theory calculations revealed a significant difference in the nature of the lowest singlet excited state for these carbonyl azides. The lowest singlet excited states (S1) of p-phenylbenzoyl and 2-anthroyl azides are (π,π*) in nature, while the pivaloyl and benzoyl azides S1 states involve (n,π*) excitations. Nevertheless, for all acyl azides studied here, a similar, and intense, IR band at about 2100 cm−1 has been detected in the ultrafast TRIR experiments following 270 nm excitation. These bands were shifted to lower energy by about 100 cm−1 relative to the N3 stretching mode for the ground states of these azides. These 2100 cm−1 vibrational bands were assigned to the S1 states of acyl azides in agreement with density functional theory calculations. The decay of the acyl azide S1 states was described by bi-exponential functions. The fast component was attributed to the decay of the hot S1 state and the longer component to the decay of the thermally relaxed S1 state. A strong and broad transient absorption in the 350–650 nm spectral range was observed in the fs UV–vis experiments for p-phenylbenzoyl and 2-anthroyl azides. The carrier of this absorption also decayed bi-exponentially, and the time constants were in excellent agreement with those found in the fs TRIR experiments. The slow component of the S1 state decay was found to be dependent on the solvent polarity. When the lifetime of the acyl azide S1 state is substantially longer than the time constant for vibrational cooling of nascent (hot) isocyanate, the correlation between the S1 decay and isocyanate formation was clear. The 270 nm excitation populates the Sn (n ≥ 2) states of these acyl azides. It was established that a hot nitrene is produced more efficiently from both the Sn and hot S1 states than from the relaxed S1 state of these acyl azides. Thus, time-resolved study provides direct experimental evidence that the S1 state is the precursor of nitrene only when the S1 state is pumped directly and when the S1 state lifetime is longer than the time constant of vibrational cooling of the newborn nitrene. All of these results are consistent with the data obtained recently for 2-napththoyl azide. Copyright © 2012 John Wiley & Sons, Ltd.
Co-reporter:Sivaramakrishnan Muthukrishnan;Vivekan S. Shete;Toby T. Sanan;Shubham Vyas;Shameema Oottikkal;Lauren M. Porter;Thomas J. Magliery;Christopher M. Hadad
Journal of Physical Organic Chemistry 2012 Volume 25( Issue 12) pp:1247-1260
Publication Date(Web):
DOI:10.1002/poc.3002
We designed, synthesized, and screened a library of analogs of the organophosphate pesticide metabolite paraoxon against a recombinant variant of human serum paraoxonase-1. Alterations of both the aryloxy leaving group and the retained alkyl chains of paraoxon analogs resulted in substantial changes to binding and hydrolysis, as measured directly by spectrophotometric methods or in competition experiments with paraoxon. Increases or decreases in the steric bulk of the retained groups generally reduced the rate of hydrolysis, while modifications of the leaving group modulated both binding and turnover. Studies on the hydrolysis of phosphoryl azide analogs as well as amino-modified paraoxon analogs, the former being developed as photoaffinity labels, found enhanced tolerance of structural modifications when compared with O-alkyl-substituted molecules. Results from computational modeling predict a predominant active site binding mode for these molecules, which is consistent with several proposed catalytic mechanisms in the literature and from which a molecular-level explanation of the experimental trends is attempted. Overall, the results of this study suggest that while paraoxonase-1 is a promiscuous enzyme, there are substantial constraints in the active site pocket, which may relate to both the leaving group and the retained portion of paraoxon analogs. Copyright © 2012 John Wiley & Sons, Ltd.
Co-reporter:Jiadan Xue, Hoi Ling Luk, S. V. Eswaran, Christopher M. Hadad, and Matthew S. Platz
The Journal of Physical Chemistry A 2012 Volume 116(Issue 22) pp:5325-5336
Publication Date(Web):May 8, 2012
DOI:10.1021/jp3025705
The photochemistry of 4-methoxycarbonylphenyl azide (2a), 2-methoxycarbonylphenyl azide (3a), and 2-methoxy-6-methoxycarbonylphenyl azide (4a) were studied by ultrafast time-resolved infrared (IR) and UV–vis spectroscopies in solution. Singlet nitrenes and ketenimines were observed and characterized for all three azides. Isoxazole species 3g and 4g are generated after photolysis of 3a and 4a, respectively, in acetonitrile. Triplet nitrene 4e formation correlated with the decay of singlet nitrene 4b. The presence of water does not change the chemistry or kinetics of singlet nitrenes 2b and 3b, but leads to protonation of 4b to produce nitrenium ion 4f. Singlet nitrenes 2b and 3b have lifetimes of 2 ns and 400 ps, respectively, in solution at ambient temperature. The singlet nitrene 4b in acetonitrile has a lifetime of about 800 ps, and reacts with water with a rate constant of 1.9 × 108 L·mol–1·s–1 at room temperature. These results indicate that a methoxycarbonyl group at either the para or ortho positions has little influence on the ISC rate, but that the presence of a 2-methoxy group dramatically accelerates the ISC rate relative to the unsubstituted phenylnitrene. An ortho-methoxy group highly stabilizes the corresponding nitrenium ion and favors its formation in aqueous solvents. This substituent has little influence on the ring-expansion rate. These results are consistent with theoretical calculations for the various intermediates and their transition states. Cyclization from the nitrene to the azirine intermediate is favored to proceed toward the electron-deficient ester group; however, the higher energy barrier is the ring-opening process, that is, azirine to ketenimine formation, rendering the formation of the ester–ketenimine (4d′) to be less favorable than the isomeric MeO–ketenimine (4d).
Co-reporter:Jeremy M. Beck, Shawn M. Miller, Mark W. Peczuh, and Christopher M. Hadad
The Journal of Organic Chemistry 2012 Volume 77(Issue 9) pp:4242-4251
Publication Date(Web):April 11, 2012
DOI:10.1021/jo202639g
A computational investigation into the hydrolysis of two methyl septanosides, methyl-α-d-glycero-d-guloseptanoside and methyl-β-d-glycero-d-guloseptanoside was undertaken. These septanosides were chosen as model compounds for comparison to methyl pyranosides and allowed direct comparison of α versus β hydrolysis rates for a specific septanoside isomer. Results suggest that hydrolysis takes place without proceeding through a transition state, an observation that was suggested in previous computational studies on exocyclic bond cleavage of carbohydrates. A conformational analysis of α- and β-anomers 1 and 2 and their corresponding oxocarbenium 3, coupled with relaxed potential energy surface (PES) scans (M06-2X/6-311+G**, implicit methanol), indicated that hydrolysis of the α-anomer is favored by 1–2 kcal/mol over the β-anomer, consistent with experiment. Model systems revealed that the lowest energy conformations of the septanoside ring system destabilize the β-anomer by 2–3 kcal/mol relative to the α-anomer, and the addition of a single hydroxyl group at the C2-position on a minimal oxepane acetal can reproduce the PES for the septanoside 1. These results suggest that the C2 hydroxyl plays a unique role in the hydrolysis mechanism, destabilizing the septanoside via its proximity to the anomeric carbon and also through its interaction with the departing methanol from the α-anomer via hydrogen-bonding interactions.
Co-reporter:Jacek Kubicki ; Yunlong Zhang ; Shubham Vyas ; Gotard Burdzinski ; Hoi Ling Luk ; Jin Wang ; Jiadan Xue ; Huo-Lei Peng ; Elena A. Pritchina ; Michel Sliwa ; Guy Buntinx ; Nina P. Gritsan ; Christopher M. Hadad ;Matthew S. Platz
Journal of the American Chemical Society 2011 Volume 133(Issue 25) pp:9751-9761
Publication Date(Web):May 9, 2011
DOI:10.1021/ja109098w
The photochemistry of 2-naphthoyl azide was studied in various solvents by femtosecond time-resolved transient absorption spectroscopy with IR and UV–vis detection. The experimental findings were interpreted with the aid of computational studies. Using polar and nonpolar solvents, the formation and decay of the first singlet excited state (S1) was observed by both time-resolved techniques. Three processes are involved in the decay of the S1 excited state of 2-naphthoyl azide: intersystem crossing, singlet nitrene formation, and isocyanate formation. The lifetime of the S1 state decreases significantly as the solvent polarity increases. In all solvents studied, isocyanate formation correlates with the decay of the azide S1 state. Nitrene formation correlates with the decay of the relaxed S1 state only upon 350 nm excitation (S0 → S1 excitation). When Sn (n ≥ 2) states are populated upon excitation (λex = 270 nm), most nitrene formation takes place within a few picoseconds through the hot S1 and higher singlet excited states (Sn) of 2-naphthoyl azide. The data correlate with the results of electron density difference calculations that predict nitrene formation from the higher-energy singlet excited states, in addition to the S1 state. For all of these experiments, no recovery of the ground state was observed up to 3 ns after photolysis, which indicates that both internal conversion and fluorescence have very low efficiencies.
Co-reporter:Jiadan Xue, Shubham Vyas, Yong Du, Hoi Ling Luk, Yung Ping Chuang, Tracy Yuen Sze But, Patrick H. Toy, Jin Wang, Arthur H. Winter, David Lee Phillips, Christopher M. Hadad, and Matthew S. Platz
The Journal of Physical Chemistry A 2011 Volume 115(Issue 26) pp:7521-7530
Publication Date(Web):June 7, 2011
DOI:10.1021/jp201821d
A time-resolved resonance Raman (TR3) and computational investigation of the photochemistry of 4-acetamidophenyl azide and 4-N-methylacetamidophenyl azide in acetonitrile is presented. Photolysis of 4-acetamidophenyl azide appears to initially produce singlet 4-acetamidophenylnitrene which undergoes fast intersystem crossing (ISC) to form triplet 4-acetamidophenylnitrene. The latter species formally produces 4,4′-bisacetamidoazobenzene. RI-CC2/TZVP and TD-B3LYP/TZVP calculations predict the formation of the singlet nitrene from the photogenerated S1 surface of the azide excited state. The triplet 4-acetamidophenylnitrene and 4,4′-bisacetamidoazobenzene species are both clearly observed on the nanosecond to microsecond time-scale in TR3 experiments. In contrast, only one species can be observed in analogous TR3 experiments after photolysis of 4-N-methylacetamidophenyl azide in acetonitrile, and this species is tentatively assigned to the compound resulting from dimerization of a 1,2-didehydroazepine. The different photochemical reaction outcomes for the photolysis of 4-acetamidophenyl azide and 4-N-methylacetamidophenyl azide molecules indicate that the 4-acetamido group has a substantial influence on the ISC rate of the corresponding substituted singlet phenylnitrene, but the 4-N-methylacetamido group does not. CASSCF analyses predict that both singlet nitrenes have open-shell electronic configurations and concluded that the dissimilarity in the photochemistry is probably due to differential geometrical distortions between the states. We briefly discuss the probable implications of this intriguing substitution effect on the photochemistry of phenyl azides and the chemistry of the related nitrenes.
Co-reporter:Shubham Vyas ; Sivaramakrishnan Muthukrishnan ; Jacek Kubicki ; Ryan D. McCulla ; Gotard Burdzinski ; Michel Sliwa ; Matthew S. Platz ;Christopher M. Hadad
Journal of the American Chemical Society 2010 Volume 132(Issue 47) pp:16796-16804
Publication Date(Web):November 4, 2010
DOI:10.1021/ja909327z
The photochemistry of diphenylphosphoryl azide was studied by femtosecond transient absorption spectroscopy, by chemical analysis of light-induced reaction products, and by RI-CC2/TZVP and TD-B3LYP/TZVP computational methods. Theoretical methods predicted two possible mechanisms for singlet diphenylphosphorylnitrene formation from the photoexcited phosphoryl azide. (i) Energy transfer from the (π,π*) singlet excited state, localized on a phenyl ring, to the azide moiety, thereby leading to the formation of the singlet excited azide, which subsequently loses molecular nitrogen to form the singlet diphenylphosphorylnitrene. (ii) Direct irradiation of the azide moiety to form an excited singlet state of the azide, which in turn loses molecular nitrogen to form the singlet diphenylphosphorylnitrene. Two transient species were observed upon ultrafast photolysis (260 nm) of diphenylphosphoryl azide. The first transient absorption, centered at 430 nm (lifetime (τ) ∼ 28 ps), was assigned to a (π,π*) singlet S1 excited state localized on a phenyl ring, and the second transient observed at 525 nm (τ ∼ 480 ps) was assigned to singlet diphenylphosphorylnitrene. Experimental and computational results obtained from the study of diphenyl phosphoramidate, along with the results obtained with diphenylphosphoryl azide, supported the mechanism of energy transfer from the singlet excited phenyl ring to the azide moiety, followed by nitrogen extrusion to form the singlet phosphorylnitrene. Ultrafast time-resolved studies performed on diphenylphosphoryl azide with the singlet nitrene quencher, tris(trimethylsilyl)silane, confirmed the spectroscopic assignment of singlet diphenylphosphorylnitrene to the 525 nm absorption band.
Co-reporter:Xiaoguang Bao, Dieter von Deak, Elizabeth J. Biddinger, Umit S. Ozkan and Christopher M. Hadad
Chemical Communications 2010 vol. 46(Issue 45) pp:8621-8623
Publication Date(Web):12 Oct 2010
DOI:10.1039/C0CC03190A
Oxygen reduction reaction (ORR) over a carbonaceous catalyst (1) with a phosphinate (>P(O)OH) moiety was explored computationally. Under the acidic environment of a fuel cell, 1 could be active for ORR and be converted to 2 with a >P(OH)2 moiety. An edge phosphinate could be active for both 2- and 4-electron ORR.
Co-reporter:Toby T. Sanan;Sivaramakrishnan Muthukrishnan;Jeremy M. Beck;Peng Tao;Carrigan J. Hayes;Tamara C. Otto;Douglas M. Cerasoli;David E. Lenz;Christopher M. Hadad
Journal of Physical Organic Chemistry 2010 Volume 23( Issue 4) pp:357-369
Publication Date(Web):
DOI:10.1002/poc.1678
Abstract
The enzyme human paraoxonase 1 (huPON1) has demonstrated significant potential for use as a bioscavenger for treatment of exposure to organophosphorus (OP) nerve agents. Herein we report the development of protein models for the human isoform derived from a crystal structure of a chimeric version of the protein (pdb ID: 1V04) and a homology model derived from the related enzyme diisopropylfluorophosphatase (pdb ID: 1XHR). From these structural models, binding modes for OP substrates are predicted, and these poses are found to orient substrates in proximity to residues known to modulate specificity of the enzyme. Predictions are made with regard to the role that residues play in altering substrate binding and turnover, in particular with regard to the stereoselectivity of the enzyme, and the known differences in activity related to a natural polymorphism in the enzyme. Potential mechanisms of action of the protein for catalytic hydrolysis of OP substrates are also evaluated in light of the proposed binding modes. Copyright © 2010 John Wiley & Sons, Ltd.
Co-reporter:Yunlong Zhang, Shubham Vyas, Christopher M. Hadad and Matthew S. Platz
The Journal of Physical Chemistry A 2010 Volume 114(Issue 18) pp:5902-5912
Publication Date(Web):April 20, 2010
DOI:10.1021/jp1012939
Phenyldiazirine and phenyldiazomethane were studied at the B3LYP/6-31+G(d) and RI-CC2/TZVP levels of theory, and the three lowest singlet excited states of both compounds were optimized at the RI-CC2/TZVP level. The calculations predict that the S1 state of phenyldiazirine is a σ → π* state, with a quinoidal structure, and the C−N bonds of the diazirine group are slightly deformed from the Cs symmetry of the ground state’s geometry. Both the S2 and S3 states are predicted to be π → π* states localized primarily on the phenyl group. The S1 state was predicted to have an exceedingly large dipole moment with a strong and distinct aromatic C═C vibrational mode around ∼1600 cm−1, which is not present in any of the other electronic states examined in this study. The calculations are consistent with the assignment of the S1 state of phenyldiazirine to the polar intermediate recently observed by ultrafast time-resolved UV−vis and IR spectroscopic studies of arylhalo- and arylalkyldiazirines. The excited states of phenyldiazomethane were also studied, and the implications of interconversion between phenyldiazirine and phenyldiazomethane are discussed. The calculations predict that the chemistry of the ground state and the S1 excited state of phenyldiazirine are very different. Formation of phenylcarbene is favored on the ground state surface of phenyldiazirine, whereas the S1 excited state favors isomerization to the first excited state of phenyldiazomethane, which rapidly extrudes nitrogen and forms carbene.
Co-reporter:Valentyna Voskresenska ; R. Marshall Wilson ; Maxim Panov ; Alexander N. Tarnovsky ; Jeanette A. Krause ; Shubham Vyas ; Arthur H. Winter ;Christopher M. Hadad
Journal of the American Chemical Society 2009 Volume 131(Issue 32) pp:11535-11547
Publication Date(Web):July 22, 2009
DOI:10.1021/ja902224m
Phenyl azides with powerful electron-donating substituents are known to deviate from the usual photochemical behavior of other phenyl azides. They do not undergo ring expansion but form basic nitrenes that protonate to form nitrenium ions. The photochemistry of the widely used photoaffinity labeling system 4-amino-3-nitrophenyl azide, 5, has been studied by transient absorption spectroscopy from femtosecond to microsecond time domains and from a theoretical perspective. The nitrene generation from azide 5 occurs on the S2 surface, in violation of Kasha’s rule. The resulting nitrene is a powerful base and abstracts protons extremely rapidly from a variety of sources to form a nitrenium ion. In methanol, this protonation occurs in about 5 ps, which is the fastest intermolecular protonation observed to date. Suitable proton sources include alcohols, amine salts, and even acidic C−H bonds such as acetonitrile. The resulting nitrenium ion is stabilized by the electron-donating 4-amino group to afford a diiminoquinone-like species that collapses relatively slowly to form the ultimate cross-linked product. In some cases in which the anion is a good hydride donor, cross-linking is replaced by reduction of the nitrenium ion to the corresponding amine.
Co-reporter:Carrigan J. Hayes and Christopher M. Hadad
The Journal of Physical Chemistry A 2009 Volume 113(Issue 45) pp:12370-12379
Publication Date(Web):April 30, 2009
DOI:10.1021/jp809356y
The bond dissociation enthalpies (BDEs) of the alkyl groups of the alkyl-substituted heterocycles have been studied and compiled using DFT methodology, with the intent of modeling the larger heterocyclic functionalities found in coal. DFT results were calibrated against CBS-QB3 calculations, and qualitative trends were reproduced between these methods. Loss of hydrogen at the benzylic position provided the most favorable route to radical formation, for both the azabenzenes and five-membered heterocycles. The ethyl derivatives had lower BDE values than the methyl derivatives due to increased stabilization of the corresponding radicals. Calculated spin densities correlated well with bond dissociation enthalpies for these compounds, while geometric effects were minimal with respect to the heterocycles themselves. Temperature effects on the bond dissociation enthalpies were minor, ranging by about 5 kcal/mol from 298 to 2000 K; the free energies of reaction dropped significantly over the same range due to entropic effects. Monocyclic heteroaromatic rings were seen to replicate the chemistry of multicyclic heteroaromatic systems.
Co-reporter:Shubham Vyas, Kefa K. Onchoke, Cheruvallil S. Rajesh, Christopher M. Hadad and Prabir K. Dutta
The Journal of Physical Chemistry A 2009 Volume 113(Issue 45) pp:12558-12565
Publication Date(Web):July 15, 2009
DOI:10.1021/jp904234q
Spectroscopic properties, including absorption, emission spectra, and excited-state lifetimes of the mononitrated benzo[a]pyrenes (NBaPs), specifically 1-, 3-, and 6-nitrobenzo[a]pyrenes (1-, 3-, and 6-NBaP), are reported, and correlations with structure are developed. With 1- and 3-NBaP, bathochromic shifts are observed in the absorption spectra. The quantum yields of emission display the following trend: BaP ≫ 6-NBaP > 1-NBaP ≈ 3-NBaP. Fluorescence lifetimes for nitrated BaPs were ∼6 to 7 times shorter than that of BaP. With the help of time-dependent density functional theory (TD-DFT), assignments of the electronic transitions are proposed and are in good agreement with the electronic spectra for the NBaPs in methanol. On the basis of optimization of the triplet states, different photochemical consequences are discussed, and the observed fluorescence quenching is explained. Changes in the electron density distributions in the ground and excited states calculated at the second-order coupled-cluster level using the resolution-of-the-identity approximation (RI-CC2) provide information about the possible mechanism of photochemical reactions of NBaPs. Correlations between the orientation of the nitro group relative to the aromatic plane and the observed properties of the NBaP are discussed.
Co-reporter:Shubham Vyas, Christopher M. Hadad and David A. Modarelli
The Journal of Physical Chemistry A 2008 Volume 112(Issue 29) pp:6533-6549
Publication Date(Web):July 1, 2008
DOI:10.1021/jp802094r
Computational investigations into the ground and singlet excited-state structures and the experimental ground-state absorption spectra of N-confused tetraphenylporphyrin tautomers 1e and 1i and N-confused porphines (NCP) 2e and 2i have been performed. Structural data for the ground state, performed at the B3LYP/6-31G(d), B3LYP/6-31+G(d)//B3LYP/6-31G(d), and B3LYP/6-311+G(d)//B3LYP/6-31G(d) levels, are consistent with those performed at lower levels of theory. Calculations of the gas-phase, ground-state absorption spectrum are qualitatively consistent with condensed phase experiments for predicting the relative intensities of the Q(0,0) and Soret bands. Inclusion of implicit solvation in the calculations substantially improves the correlation of the energy of the Soret band with experiment for both tautomers (1e, 435 nm predicted, 442 nm observed in DMAc; 1i, 435 nm predicted, 437 nm observed in CH2Cl2). The x- and y-polarized Q-band transitions were qualitatively reproduced for 1e in both the gas phase and with solvation, although the low-energy absorption band in 1i was predicted at substantially higher energy (646 nm in the gas phase and 655 nm with solvation) than observed experimentally (724 nm in CH2Cl2). Franck−Condon state and equilibrated singlet excited-state geometries were calculated for unsubstituted NCP tautomers 2e and 2i at the TD-B3LYP/SVP and TD-B3LYP/TZVP//TD-B3LYP/SVP levels. Electronic difference density plots were calculated from these geometries, thereby indicating the change of electron density in the singlet excited states. Adiabatic S1 and S2 geometries of these compounds were also calculated at the TD-B3LYP/SVP level, and the results indicate that while 2i is a more stable ground-state molecule by ∼7.0 kcal mol−1, the energy difference for the S1 excited states is only ∼1.0 kcal mol−1 and is 6.1 kcal mol−1 for the S2 excited states.
Co-reporter:Matthew P. DeMatteo, Song Mei, Ryan Fenton, Martha Morton, Donna M. Baldisseri, Christopher M. Hadad, Mark W. Peczuh
Carbohydrate Research 2006 Volume 341(Issue 18) pp:2927-2945
Publication Date(Web):29 December 2006
DOI:10.1016/j.carres.2006.09.024
Methyl 5-O-methyl-α-d-glycero-d-idoseptanoside (3) and methyl 5-O-methyl-β-d-glycero-d-guloseptanoside (4) were investigated as (1→5)-linked di-/oligoseptanoside mimetics. Here we report the synthesis of 3 and 4 and describe their preferred solution conformations through a combination of ab initio/DFT calculations and 1H 3JH,H NMR coupling constant analysis. The conformations of 3 and 4 observed in this study are discussed in comparison to those of the parent (C5 hydroxy) compounds 1 and 2. The results indicate that methyl 5-O-methyl-α-septanoside 3 is relatively rigid and adopts the same 3,4TC5,6 conformation as 1. Methyl 5-O-methyl-β-septanoside 4 is somewhat less rigid than its parent septanoside (2). In addition to the 6,OTC4,5 conformation adopted by 2, β-septanoside 4 also populates the adjacent 3,4TC5,6 conformation. Glycosylation at C5 on β-septanoside 4 therefore increases its overall flexibility and allows access to alternative ring conformations.
Co-reporter:Xiaoguang Bao, Dieter von Deak, Elizabeth J. Biddinger, Umit S. Ozkan and Christopher M. Hadad
Chemical Communications 2010 - vol. 46(Issue 45) pp:NaN8623-8623
Publication Date(Web):2010/10/12
DOI:10.1039/C0CC03190A
Oxygen reduction reaction (ORR) over a carbonaceous catalyst (1) with a phosphinate (>P(O)OH) moiety was explored computationally. Under the acidic environment of a fuel cell, 1 could be active for ORR and be converted to 2 with a >P(OH)2 moiety. An edge phosphinate could be active for both 2- and 4-electron ORR.
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