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25) Reactivity of Aluminum Cluster Anions with Water: Origins of Reactivity and Mechanisms for H2 Release.
A.C Reber, S.N. Khanna, P.J. Roach, W.H. Woodward, and A.W. Castleman Jr. J. Phys Chem. A ASAP (2010) | 24) Crystal field effects on the reactivity of aluminum-copper cluster anions.
P.J. Roach, W.H. Woodward, A.C. Reber, S.N. Khanna, A.W. Castleman Jr. Phys. Rev B 81 195404 (2010) | | 23) Cluster Assembled Materials: Towards Nanomaterials with Precise Control over Properties. M.
Qian, A.C. Reber, A. Ugrinov, N.K. Chaki, S. Mandal, H.M.
Saavedra, S.N. Khanna, A. Sen, and P.S. Weiss. ACS Nano 4, 235 (2010) | | 22) Grain Formation Modulated by Molecular Hydrogen Evaporation in the Interstellar Medium. A. Reber, K. Kostov, and R.S. Berry. J. Phys Chem. A 114 1277 (2010). | 21) Magnetic Superatoms. J.U. Reveles, P.A. Clayborne, A.C. Reber, S.N. Khanna, K. Pradhan, P. Sen, M.R. Pederson. Nature Chemistry 1 310 (2009)
| 20) Helical and linear [K(As11)]2- chains: Role of Solvent on the conformation of chains formed by Zintl anions. A.C. Reber, A. Ugrinov, A. Sen, M. Qian, S.N. Khanna. Chemical Physics Letters 473 305 (2009)
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| 19) Complementary Active Sites Cause Size-Selective Reactivity of Aluminum Cluster Anions with Water.
P.J. Roach, W.H. Woodward, A.W. Castleman Jr., A.C. Reber, and S.N. Khanna. Science, 323 492 (2009).
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| 18) Production of Equal Sized Atomic Clusters by a Hot Wire.
C. Peineke, M Attoui, R. Robles, A.C. Reber, S.N. Khanna, and A. Schmidt-Ott. J. Aerosol Science, 40 423 (2009).
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| 17) Effect of Charge and Composition on the Structural Fluxionality and Stability of Nine Atom Tin Bismuth Zintl Analogues.
U. Gupta, A.C. Reber, P.A. Clayborne, J.J. Melko, S.N. Khanna, and A.W. Castleman Jr. Inorg. Chem. 47 10953 (2008).
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| 16)
From SiO Molecules to Silicates in Circumstellar Space: Atomic
Structures, Growth Patterns, and Optical Signatures of SinOm Clusters.
A.C. Reber, S. Paranthaman, P.A. Clayborne, S.N. Khanna, and A.W. Castleman Jr. ACS Nano 2, 1729 (2008).
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| 15) [Te2As2]-2 : A Planar Motif with "Conflicting" Aromaticity.
A. Ugrinov, A. Sen, A.C. Reber, M. Qian, and S.N. Khanna. J. Amer. Chem. Soc. 130, 782 (2008).
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| 14) Thermodynamic Stability of polyacrylamide and poly(N,N-dimethly acylamide).
A.C. Reber, S.N. Khanna, and R. Ottenbrite. Polym. Adv. Technol. 18, 978 (2007).
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| 13) Spin Accommodation and Reactivity of Aluminum Based Clusters with O2.
A.C. Reber, S.N. Khanna, P.J. Roach, W.H. Woodward, and A.W. Castleman jr. J. Amer. Chem. Soc. 129, 16098, 2007.
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| 12) Electron-Atom Superelastic Scattering in Magnesium at Millielectron Volt Energies.
T. Baynard, A.C. Reber, R.F. Niedziela, S.A. Darveau, B. Prutzman, and R.S. Berry. J. Phys. Chem. A 111(49) 12487 (2007).
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| 11) Superatoms and their assemblies based on alkali and super-alkali motifs
P. Clayborne, N.O. Jones, A.C. Reber, J.U. Reveles, M. Qian, and S.N. Khanna. J. Comp. Meth. Sci. Eng. 7 417 (2007).
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| 10) Al4H7- is a resilient building block for aluminum hydrogen cluster materials.
P.J. Roach, A.C. Reber, W.H. Woodward, S.N. Khanna, and A.W. Castleman Jr. Proc. Nat. Acad. Sci. 104 14565 (2007).
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| 9) From Designer Clusters to Synthetic Crystalline Nanoassemblies.
A.W.
Castleman Jr., S.N. Khanna, A. Sen, A.C. Reber, M. Qian, K.M. Davis,
S.J. Peppernick, A. Ugrinov, and M.D. Meritt. Nano Letters 7 2734 (2007).
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| 8) Superatom Compounds, Clusters, and Assemblies: Ultra Alkali Motifs and Architectures. A.C. Reber, S.N. Khanna, and A.W. Castleman Jr. J. Amer. Chem. Soc. 129 10189 (2007).
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7) Rings, towers, and cages of ZnO.
A.C. Reber, S.N. Khanna, J.S. Hunjan, and M.R. Beltran. Eur. Phys. J. D 43 221 (2007).
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6) Cobalt doped rings and cages of ZnO clusters: Motifs for magnetic cluster-assembled materials. A.C. Reber, S.N. Khanna J.S. Hunjan, and M.R. Beltran. Chem. Phys. Lett. 428, 376 (2006). |
| 5) Silicon oxide nanoparticles reveal the origin of silicate grains in circumstellar environments. A.C. Reber, P.A. Clayborne, J.U. Reveles, S.N. Khanna,A.W. Castleman, Jr., and A. Ali Nano Letters, 6, 1190 (2006).
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| 4) Visualization of electron correlation in autoionizing statesabove the 3p threshold in Magnesium. A. Reber, C. Gordon, and R.S. Berry. PCCP, 7, 3276 (2005). (Cover Article)
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A.Reber, Superelastic Scattering and
Above-Threshold Ionization and Superelastic Scattering in Magnesium. Doctoral Thesis, University of Chicago. |
| 3) Above-threshold ionization near the 3p4d 1Fo autoionizing state in Magnesium. A. Reber, T. Baynard, F. Martín, H. Bachau, and R.S. Berry. Phys. Rev. A. 71, 053402 (2005).
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| 2) Three-photon above threshold ionization of Magnesium.ton above threshold ionization of Magnesium. A. Reber, F. Martín, H. Bachau, and R. S. Berry. Phys. Phys. Rev. A 68, 063401, (2003).
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| 1) Two-photon above threshold ionization of Magnesium. A. Reber, F. Martín, H. Bachau, and R. S. Berry. Phys. Rev. A 65, 063413 (2002).
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