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3. Molecular growth upon ionization of van der Waals clusters containing HCCH and HCN is a pathway to prebiotic molecules.

Author

Stein, Tamar, Stein, Tamar, Bera, Partha P, Lee, Timothy J, Head-Gordon, Martin, Stein, Tamar, Stein, Tamar, Bera, Partha P, Lee, Timothy J, and Head-Gordon, Martin

Abstract

The growth mechanisms of organic molecules in an ionizing environment such as the interstellar medium are not completely understood. Here we examine by means of ab initio molecular dynamics (AIMD) simulations and density functional theory (DFT) computations the possibility of bond formation and molecular growth upon ionization of van der Waals clusters of pure HCN clusters, and mixed clusters of HCN and HCCH, both of which are widespread in the interstellar medium. Ionization of van der Waals clusters can potentially lead to growth in low temperature and low-density environments. Our results show, that upon ionization of the pure HCN clusters, strongly bound stable structures are formed that contain NH bonds, and growth beyond pairwise HCN molecules is seen only in a small percentage of cases. In contrast, mixed clusters, where HCCH is preferentially ionized over HCN, can grow up to 3 or 4 units long with new carbon-carbon and carbon-nitrogen covalent bonds. Moreover, cyclic molecules formed, such as the radical cation of pyridine, which is a prebiotic molecule. The results presented here are significant as they provide a feasible pathway for molecular growth of small organic molecules containing both carbon and nitrogen in cold and relatively denser environments such as in dense molecular clouds but closer to the photo-dissociation regions, and protoplanetary disks. In the mechanism we propose, first, a neutral van der Waals cluster is formed. Once the cluster is formed it can undergo photoionization which leads to chemical reactivity without any reaction barrier.

Published
2020

4. Molecular growth upon ionization of van der Waals clusters containing HCCH and HCN is a pathway to prebiotic molecules.

Author

Stein, Tamar, Stein, Tamar, Bera, Partha P, Lee, Timothy J, Head-Gordon, Martin, Stein, Tamar, Stein, Tamar, Bera, Partha P, Lee, Timothy J, and Head-Gordon, Martin

Abstract

The growth mechanisms of organic molecules in an ionizing environment such as the interstellar medium are not completely understood. Here we examine by means of ab initio molecular dynamics (AIMD) simulations and density functional theory (DFT) computations the possibility of bond formation and molecular growth upon ionization of van der Waals clusters of pure HCN clusters, and mixed clusters of HCN and HCCH, both of which are widespread in the interstellar medium. Ionization of van der Waals clusters can potentially lead to growth in low temperature and low-density environments. Our results show, that upon ionization of the pure HCN clusters, strongly bound stable structures are formed that contain NH bonds, and growth beyond pairwise HCN molecules is seen only in a small percentage of cases. In contrast, mixed clusters, where HCCH is preferentially ionized over HCN, can grow up to 3 or 4 units long with new carbon-carbon and carbon-nitrogen covalent bonds. Moreover, cyclic molecules formed, such as the radical cation of pyridine, which is a prebiotic molecule. The results presented here are significant as they provide a feasible pathway for molecular growth of small organic molecules containing both carbon and nitrogen in cold and relatively denser environments such as in dense molecular clouds but closer to the photo-dissociation regions, and protoplanetary disks. In the mechanism we propose, first, a neutral van der Waals cluster is formed. Once the cluster is formed it can undergo photoionization which leads to chemical reactivity without any reaction barrier.

Published
2020

5. Electrochemical deposition of N-heterocyclic carbene monolayers on metal surfaces.

Author

Amit, Einav, Amit, Einav, Dery, Linoy, Dery, Shahar, Kim, Suhong, Roy, Anirban, Hu, Qichi, Gutkin, Vitaly, Eisenberg, Helen, Stein, Tamar, Mandler, Daniel, Dean Toste, F, Gross, Elad, Amit, Einav, Amit, Einav, Dery, Linoy, Dery, Shahar, Kim, Suhong, Roy, Anirban, Hu, Qichi, Gutkin, Vitaly, Eisenberg, Helen, Stein, Tamar, Mandler, Daniel, Dean Toste, F, and Gross, Elad

Abstract

N-heterocyclic carbenes (NHCs) have been widely utilized for the formation of self-assembled monolayers (SAMs) on various surfaces. The main methodologies for preparation of NHCs-based SAMs either requires inert atmosphere and strong base for deprotonation of imidazolium precursors or the use of specifically-synthesized precursors such as NHC(H)[HCO3] salts or NHC-CO2 adducts. Herein, we demonstrate an electrochemical approach for surface-anchoring of NHCs which overcomes the need for dry environment, addition of exogenous strong base or restricting synthetic steps. In the electrochemical deposition, water reduction reaction is used to generate high concentration of hydroxide ions in proximity to a metal electrode. Imidazolium cations were deprotonated by hydroxide ions, leading to carbenes formation that self-assembled on the electrode's surface. SAMs of NO2-functionalized NHCs and dimethyl-benzimidazole were electrochemically deposited on Au films. SAMs of NHCs were also electrochemically deposited on Pt, Pd and Ag films, demonstrating the wide metal scope of this deposition technique.

Published
2020

6. Electrochemical deposition of N-heterocyclic carbene monolayers on metal surfaces.

Author

Amit, Einav, Amit, Einav, Dery, Linoy, Dery, Shahar, Kim, Suhong, Roy, Anirban, Hu, Qichi, Gutkin, Vitaly, Eisenberg, Helen, Stein, Tamar, Mandler, Daniel, Dean Toste, F, Gross, Elad, Amit, Einav, Amit, Einav, Dery, Linoy, Dery, Shahar, Kim, Suhong, Roy, Anirban, Hu, Qichi, Gutkin, Vitaly, Eisenberg, Helen, Stein, Tamar, Mandler, Daniel, Dean Toste, F, and Gross, Elad

Abstract

N-heterocyclic carbenes (NHCs) have been widely utilized for the formation of self-assembled monolayers (SAMs) on various surfaces. The main methodologies for preparation of NHCs-based SAMs either requires inert atmosphere and strong base for deprotonation of imidazolium precursors or the use of specifically-synthesized precursors such as NHC(H)[HCO3] salts or NHC-CO2 adducts. Herein, we demonstrate an electrochemical approach for surface-anchoring of NHCs which overcomes the need for dry environment, addition of exogenous strong base or restricting synthetic steps. In the electrochemical deposition, water reduction reaction is used to generate high concentration of hydroxide ions in proximity to a metal electrode. Imidazolium cations were deprotonated by hydroxide ions, leading to carbenes formation that self-assembled on the electrode's surface. SAMs of NO2-functionalized NHCs and dimethyl-benzimidazole were electrochemically deposited on Au films. SAMs of NHCs were also electrochemically deposited on Pt, Pd and Ag films, demonstrating the wide metal scope of this deposition technique.

Published
2020

7. Ab initio dynamics and photoionization mass spectrometry reveal ion-molecule pathways from ionized acetylene clusters to benzene cation.

Author

Stein, Tamar, Stein, Tamar, Bandyopadhyay, Biswajit, Troy, Tyler P, Fang, Yigang, Kostko, Oleg, Ahmed, Musahid, Head-Gordon, Martin, Stein, Tamar, Stein, Tamar, Bandyopadhyay, Biswajit, Troy, Tyler P, Fang, Yigang, Kostko, Oleg, Ahmed, Musahid, and Head-Gordon, Martin

Abstract

The growth mechanism of hydrocarbons in ionizing environments, such as the interstellar medium (ISM), and some combustion conditions remains incompletely understood. Ab initio molecular dynamics (AIMD) simulations and molecular beam vacuum-UV (VUV) photoionization mass spectrometry experiments were performed to understand the ion-molecule growth mechanism of small acetylene clusters (up to hexamers). A dramatic dependence of product distribution on the ionization conditions is demonstrated experimentally and understood from simulations. The products change from reactive fragmentation products in a higher temperature, higher density gas regime toward a very cold collision-free cluster regime that is dominated by products whose empirical formula is (C2H2) n+, just like ionized acetylene clusters. The fragmentation products result from reactive ion-molecule collisions in a comparatively higher pressure and temperature regime followed by unimolecular decomposition. The isolated ionized clusters display rich dynamics that contain bonded C4H4+ and C6H6+ structures solvated with one or more neutral acetylene molecules. Such species contain large amounts (>2 eV) of excess internal energy. The role of the solvent acetylene molecules is to affect the barrier crossing dynamics in the potential energy surface (PES) between (C2H2)n+ isomers and provide evaporative cooling to dissipate the excess internal energy and stabilize products including the aromatic ring of the benzene cation. Formation of the benzene cation is demonstrated in AIMD simulations of acetylene clusters with n > 3, as well as other metastable C6H6+ isomers. These results suggest a path for aromatic ring formation in cold acetylene-rich environments such as parts of the ISM.

Published
2017

8. Ab initio dynamics and photoionization mass spectrometry reveal ion-molecule pathways from ionized acetylene clusters to benzene cation.

Author

Stein, Tamar, Stein, Tamar, Bandyopadhyay, Biswajit, Troy, Tyler P, Fang, Yigang, Kostko, Oleg, Ahmed, Musahid, Head-Gordon, Martin, Stein, Tamar, Stein, Tamar, Bandyopadhyay, Biswajit, Troy, Tyler P, Fang, Yigang, Kostko, Oleg, Ahmed, Musahid, and Head-Gordon, Martin

Abstract

The growth mechanism of hydrocarbons in ionizing environments, such as the interstellar medium (ISM), and some combustion conditions remains incompletely understood. Ab initio molecular dynamics (AIMD) simulations and molecular beam vacuum-UV (VUV) photoionization mass spectrometry experiments were performed to understand the ion-molecule growth mechanism of small acetylene clusters (up to hexamers). A dramatic dependence of product distribution on the ionization conditions is demonstrated experimentally and understood from simulations. The products change from reactive fragmentation products in a higher temperature, higher density gas regime toward a very cold collision-free cluster regime that is dominated by products whose empirical formula is (C2H2) n+, just like ionized acetylene clusters. The fragmentation products result from reactive ion-molecule collisions in a comparatively higher pressure and temperature regime followed by unimolecular decomposition. The isolated ionized clusters display rich dynamics that contain bonded C4H4+ and C6H6+ structures solvated with one or more neutral acetylene molecules. Such species contain large amounts (>2 eV) of excess internal energy. The role of the solvent acetylene molecules is to affect the barrier crossing dynamics in the potential energy surface (PES) between (C2H2)n+ isomers and provide evaporative cooling to dissipate the excess internal energy and stabilize products including the aromatic ring of the benzene cation. Formation of the benzene cation is demonstrated in AIMD simulations of acetylene clusters with n > 3, as well as other metastable C6H6+ isomers. These results suggest a path for aromatic ring formation in cold acetylene-rich environments such as parts of the ISM.

Published
2017

10. Mechanisms of the Formation of Adenine, Guanine, and Their Analogues in UV-Irradiated Mixed NH3:H2O Molecular Ices Containing Purine.

Author

Bera, Partha P, Bera, Partha P, Stein, Tamar, Head-Gordon, Martin, Lee, Timothy J, Bera, Partha P, Bera, Partha P, Stein, Tamar, Head-Gordon, Martin, and Lee, Timothy J

Abstract

We investigated the formation mechanisms of the nucleobases adenine and guanine and the nucleobase analogues hypoxanthine, xanthine, isoguanine, and 2,6-diaminopurine in a UV-irradiated mixed 10:1 H2O:NH3 ice seeded with precursor purine by using ab initio and density functional theory computations. Our quantum chemical investigations suggest that a multistep reaction mechanism involving purine cation, hydroxyl and amino radicals, together with water and ammonia, explains the experimentally obtained products in an independent study. The relative abundances of these products appear to largely follow from relative thermodynamic stabilities. The key role of the purine cation is likely to be the reason why purine is not functionalized in pure ammonia ice, where cations are promptly neutralized by free electrons from NH3 ionization. Amine group addition to purine is slightly favored over hydroxyl group attachment based on energetics, but hydroxyl is much more abundant due to higher abundance of H2O. The amino group is preferentially attached to the 6 position, giving 6-aminopurine, that is, adenine, while the hydroxyl group is preferentially attached to the 2 position, leading to 2-hydroxypurine. A second substitution by hydroxyl or amino group occurs at either the 6 or the 2 position depending on the first substitution. Given that H2O is far more abundant than NH3 in the experimentally studied ices (as well as based on interstellar abundances), xanthine and isoguanine are expected to be the most abundant bi-substituted photoproducts. Key Words: Astrophysical ice-Abiotic organic synthesis-Nucleic acids-Origin of life-RNA world. Astrobiology 17, 771-785.

Published
2017

11. Mechanisms of the Formation of Adenine, Guanine, and Their Analogues in UV-Irradiated Mixed NH3:H2O Molecular Ices Containing Purine

Author

Bera, Partha P, Bera, Partha P, Stein, Tamar, Head-Gordon, Martin, Lee, Timothy J, Bera, Partha P, Bera, Partha P, Stein, Tamar, Head-Gordon, Martin, and Lee, Timothy J

Abstract

We investigated the formation mechanisms of the nucleobases adenine and guanine and the nucleobase analogues hypoxanthine, xanthine, isoguanine, and 2,6-diaminopurine in a UV-irradiated mixed 10:1 H2O:NH3 ice seeded with precursor purine by using ab initio and density functional theory computations. Our quantum chemical investigations suggest that a multistep reaction mechanism involving purine cation, hydroxyl and amino radicals, together with water and ammonia, explains the experimentally obtained products in an independent study. The relative abundances of these products appear to largely follow from relative thermodynamic stabilities. The key role of the purine cation is likely to be the reason why purine is not functionalized in pure ammonia ice, where cations are promptly neutralized by free electrons from NH3 ionization. Amine group addition to purine is slightly favored over hydroxyl group attachment based on energetics, but hydroxyl is much more abundant due to higher abundance of H2O. The amino group is preferentially attached to the 6 position, giving 6-aminopurine, that is, adenine, while the hydroxyl group is preferentially attached to the 2 position, leading to 2-hydroxypurine. A second substitution by hydroxyl or amino group occurs at either the 6 or the 2 position depending on the first substitution. Given that H2O is far more abundant than NH3 in the experimentally studied ices (as well as based on interstellar abundances), xanthine and isoguanine are expected to be the most abundant bi-substituted photoproducts. Key Words: Astrophysical ice-Abiotic organic synthesis-Nucleic acids-Origin of life-RNA world. Astrobiology 17, 771-785.

Published
2017

13. Advances in molecular quantum chemistry contained in the Q-Chem 4 program package

Author

Shao, Yihan, Gan, Zhengting, Epifanovsky, Evgeny, Gilbert, Andrew T. B., Wormit, Michael, Kussmann, Joerg, Lange, Adrian W., Behn, Andrew, Deng, Jia, Feng, Xintian, Ghosh, Debashree, Stein, Tamar, Stück, David, Su, Yu-Chuan, Thom, Alex J.W., Tsuchimochi, Takashi, Vanovschi, Vitalii, Vogt, Leslie, Vydrov, Oleg, Wang, Tao, Watson, Mark A., Goldey, Matthew, Wenzel, Jan, White, Alec, Williams, Christopher F., Yang, Jun, Yeganeh, Sina, Yost, Shane R., You, Zhi-Qiang, Zhang, Igor Ying, Zhang, Xing, Zhao, Yan, Horn, Paul R., Brooks, Bernard R., Chan, Garnet K.L., Chipman, Daniel M., Cramer, Christopher J., Goddard, William A., Gordon, Mark S., Hehre, Warren, Klamt, Andreas, Schaefer, Henry F., Schmidt, Michael W., Jacobson, Leif D., Sherrill, C. David, Truhlar, Donald G., Warshel, Arieh, Xu, Xin, Aspuru-Guzik, Alán, Baer, Roi, Bell, Alexis T., Besley, Nicholas A., Chai, Jeng-Da, Dreuw, Andreas, Kaliman, Ilya, Dunietz, Barry D., Furlani, Thomas R., Gwaltney, Steven R., Hsu, Chao-Ping, Jung, Yousung, Kong, Jing, Lambrecht, Daniel S., Liang, WanZhen, Ochsenfeld, Christian, Rassolov, Vitaly A., Khaliullin, Rustam Z., Slipchenko, Lyudmila V., Subotnik, Joseph E., Van Voorhis, Troy, Herbert, John M., Krylov, Anna I., Gill, Peter M.W., Head-Gordon, Martin, Kuś, Tomasz, Landau, Arie, Liu, Jie, Proynov, Emil I., Rhee, Young Min, Richard, Ryan M., Rohrdanz, Mary A., Steele, Ryan P., Sundstrom, Eric J., Woodcock, H. Lee, Zimmerman, Paul M., Zuev, Dmitry, Albrecht, Ben, Alguire, Ethan, Austin, Brian, Beran, Gregory J. O., Bernard, Yves A., Berquist, Eric, Brandhorst, Kai, Bravaya, Ksenia B., Brown, Shawn T., Casanova, David, Chang, Chun-Min, Chen, Yunqing, Chien, Siu Hung, Closser, Kristina D., Crittenden, Deborah L., Diedenhofen, Michael, DiStasio, Robert A., Do, Hainam, Dutoi, Anthony D., Edgar, Richard G., Fatehi, Shervin, Fusti-Molnar, Laszlo, Ghysels, An, Golubeva-Zadorozhnaya, Anna, Gomes, Joseph, Hanson-Heine, Magnus W.D., Harbach, Philipp H.P., Hauser, Andreas W., Hohenstein, Edward G., Holden, Zachary C., Jagau, Thomas-C., Ji, Hyunjun, Kaduk, Benjamin, Khistyaev, Kirill, Kim, Jaehoon, Kim, Jihan, King, Rollin A., Klunzinger, Phil, Kosenkov, Dmytro, Kowalczyk, Tim, Krauter, Caroline M., Lao, Ka Un, Laurent, Adèle D., Lawler, Keith V., Levchenko, Sergey V., Lin, Ching Yeh, Liu, Fenglai, Livshits, Ester, Lochan, Rohini C., Luenser, Arne, Manohar, Prashant, Manzer, Samuel F., Mao, Shan-Ping, Mardirossian, Narbe, Marenich, Aleksandr V., Maurer, Simon A., Mayhall, Nicholas J., Neuscamman, Eric, Oana, C. Melania, Olivares-Amaya, Roberto, O’Neill, Darragh P., Parkhill, John A., Perrine, Trilisa M., Peverati, Roberto, Prociuk, Alexander, Rehn, Dirk R., Rosta, Edina, Russ, Nicholas J., Sharada, Shaama M., Sharma, Sandeep, Small, David W., Sodt, Alexander, Shao, Yihan, Gan, Zhengting, Epifanovsky, Evgeny, Gilbert, Andrew T. B., Wormit, Michael, Kussmann, Joerg, Lange, Adrian W., Behn, Andrew, Deng, Jia, Feng, Xintian, Ghosh, Debashree, Stein, Tamar, Stück, David, Su, Yu-Chuan, Thom, Alex J.W., Tsuchimochi, Takashi, Vanovschi, Vitalii, Vogt, Leslie, Vydrov, Oleg, Wang, Tao, Watson, Mark A., Goldey, Matthew, Wenzel, Jan, White, Alec, Williams, Christopher F., Yang, Jun, Yeganeh, Sina, Yost, Shane R., You, Zhi-Qiang, Zhang, Igor Ying, Zhang, Xing, Zhao, Yan, Horn, Paul R., Brooks, Bernard R., Chan, Garnet K.L., Chipman, Daniel M., Cramer, Christopher J., Goddard, William A., Gordon, Mark S., Hehre, Warren, Klamt, Andreas, Schaefer, Henry F., Schmidt, Michael W., Jacobson, Leif D., Sherrill, C. David, Truhlar, Donald G., Warshel, Arieh, Xu, Xin, Aspuru-Guzik, Alán, Baer, Roi, Bell, Alexis T., Besley, Nicholas A., Chai, Jeng-Da, Dreuw, Andreas, Kaliman, Ilya, Dunietz, Barry D., Furlani, Thomas R., Gwaltney, Steven R., Hsu, Chao-Ping, Jung, Yousung, Kong, Jing, Lambrecht, Daniel S., Liang, WanZhen, Ochsenfeld, Christian, Rassolov, Vitaly A., Khaliullin, Rustam Z., Slipchenko, Lyudmila V., Subotnik, Joseph E., Van Voorhis, Troy, Herbert, John M., Krylov, Anna I., Gill, Peter M.W., Head-Gordon, Martin, Kuś, Tomasz, Landau, Arie, Liu, Jie, Proynov, Emil I., Rhee, Young Min, Richard, Ryan M., Rohrdanz, Mary A., Steele, Ryan P., Sundstrom, Eric J., Woodcock, H. Lee, Zimmerman, Paul M., Zuev, Dmitry, Albrecht, Ben, Alguire, Ethan, Austin, Brian, Beran, Gregory J. O., Bernard, Yves A., Berquist, Eric, Brandhorst, Kai, Bravaya, Ksenia B., Brown, Shawn T., Casanova, David, Chang, Chun-Min, Chen, Yunqing, Chien, Siu Hung, Closser, Kristina D., Crittenden, Deborah L., Diedenhofen, Michael, DiStasio, Robert A., Do, Hainam, Dutoi, Anthony D., Edgar, Richard G., Fatehi, Shervin, Fusti-Molnar, Laszlo, Ghysels, An, Golubeva-Zadorozhnaya, Anna, Gomes, Joseph, Hanson-Heine, Magnus W.D., Harbach, Philipp H.P., Hauser, Andreas W., Hohenstein, Edward G., Holden, Zachary C., Jagau, Thomas-C., Ji, Hyunjun, Kaduk, Benjamin, Khistyaev, Kirill, Kim, Jaehoon, Kim, Jihan, King, Rollin A., Klunzinger, Phil, Kosenkov, Dmytro, Kowalczyk, Tim, Krauter, Caroline M., Lao, Ka Un, Laurent, Adèle D., Lawler, Keith V., Levchenko, Sergey V., Lin, Ching Yeh, Liu, Fenglai, Livshits, Ester, Lochan, Rohini C., Luenser, Arne, Manohar, Prashant, Manzer, Samuel F., Mao, Shan-Ping, Mardirossian, Narbe, Marenich, Aleksandr V., Maurer, Simon A., Mayhall, Nicholas J., Neuscamman, Eric, Oana, C. Melania, Olivares-Amaya, Roberto, O’Neill, Darragh P., Parkhill, John A., Perrine, Trilisa M., Peverati, Roberto, Prociuk, Alexander, Rehn, Dirk R., Rosta, Edina, Russ, Nicholas J., Sharada, Shaama M., Sharma, Sandeep, Small, David W., and Sodt, Alexander

Abstract

A summary of the technical advances that are incorporated in the fourth major release of the Q-Chem quantum chemistry program is provided, covering approximately the last seven years. These include developments in density functional theory methods and algorithms, nuclear magnetic resonance (NMR) property evaluation, coupled cluster and perturbation theories, methods for electronically excited and open-shell species, tools for treating extended environments, algorithms for walking on potential surfaces, analysis tools, energy and electron transfer modelling, parallel computing capabilities, and graphical user interfaces. In addition, a selection of example case studies that illustrate these capabilities is given. These include extensive benchmarks of the comparative accuracy of modern density functionals for bonded and non-bonded interactions, tests of attenuated second order Møller–Plesset (MP2) methods for intermolecular interactions, a variety of parallel performance benchmarks, and tests of the accuracy of implicit solvation models. Some specific chemical examples include calculations on the strongly correlated Cr2 dimer, exploring zeolite-catalysed ethane dehydrogenation, energy decomposition analysis of a charged ter-molecular complex arising from glycerol photoionisation, and natural transition orbitals for a Frenkel exciton state in a nine-unit model of a self-assembling nanotube.

Published
2015

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