Isomerenselektive IR‐Spektroskopie von Benzol‐Acetylen‐Clustern: Vergleich mit der Struktur des Benzol‐Acetylen‐Cokristalls

“…The IR laser frequency was scanned over the vibrational transitions and removed the vibrational ground-state population if resonant, while the UV excitation laser was kept at a frequency resonant with a vibronic transition of a single cluster isomer. [20]. IR laser light was generated by a two-stage setup, [30] which produced IR radiation between 2800 and 4000 cm À1 (10 Hz, > 4 mJ pulse À1 ).…”

“…[20] Isomer 1 of BA 2 has a double T-shaped structure, which is also found in the benzene-acetylene 1:1 cocrystal [1] along the c-axis and might be the seed nucleus in the crystallization process of the cocrystal. [20] Isomer 1 of BA 2 has a double T-shaped structure, which is also found in the benzene-acetylene 1:1 cocrystal [1] along the c-axis and might be the seed nucleus in the crystallization process of the cocrystal.…”

“…[20] Isomer 1 of BA 2 has a double T-shaped structure, which is also found in the benzene-acetylene 1:1 cocrystal [1] along the c-axis and might be the seed nucleus in the crystallization process of the cocrystal. [8,20] To follow the pathway of crystallization from the simplest seed up to the packing motif of a crystal and to learn more about the interplay between CH···p bonds and p···p interactions, we decided to investigate benzene-acetylene clusters containing two benzene moieties. Isomer 1 of BA 2 with its double T-shaped structure grows to the BA 3 structure by addition of a third acetylene molecule sideways to one acetylene unit and the benzene ring.…”

“…[20]). Following the above argument we can immediately conclude that 1) the acetylene molecule forms a CH···p bond with the absorbing chromophore in B 2 A and 2) the structure of B 2 A probably derives directly from B 2 by adding acetylene in a Tshaped arrangement, because the magnitude of the blue shift is almost the same as that between B and BA.…”

Towards a Spectroscopic and Theoretical Identification of the Isolated Building Blocks of the Benzene–Acetylene Cocrystal

“…The IR laser frequency was scanned over the vibrational transitions and removed the vibrational ground-state population if resonant, while the UV excitation laser was kept at a frequency resonant with a vibronic transition of a single cluster isomer. [20]. IR laser light was generated by a two-stage setup, [30] which produced IR radiation between 2800 and 4000 cm À1 (10 Hz, > 4 mJ pulse À1 ).…”

“…[20] Isomer 1 of BA 2 has a double T-shaped structure, which is also found in the benzene-acetylene 1:1 cocrystal [1] along the c-axis and might be the seed nucleus in the crystallization process of the cocrystal. [20] Isomer 1 of BA 2 has a double T-shaped structure, which is also found in the benzene-acetylene 1:1 cocrystal [1] along the c-axis and might be the seed nucleus in the crystallization process of the cocrystal.…”

“…[20] Isomer 1 of BA 2 has a double T-shaped structure, which is also found in the benzene-acetylene 1:1 cocrystal [1] along the c-axis and might be the seed nucleus in the crystallization process of the cocrystal. [8,20] To follow the pathway of crystallization from the simplest seed up to the packing motif of a crystal and to learn more about the interplay between CH···p bonds and p···p interactions, we decided to investigate benzene-acetylene clusters containing two benzene moieties. Isomer 1 of BA 2 with its double T-shaped structure grows to the BA 3 structure by addition of a third acetylene molecule sideways to one acetylene unit and the benzene ring.…”

“…[20]). Following the above argument we can immediately conclude that 1) the acetylene molecule forms a CH···p bond with the absorbing chromophore in B 2 A and 2) the structure of B 2 A probably derives directly from B 2 by adding acetylene in a Tshaped arrangement, because the magnitude of the blue shift is almost the same as that between B and BA.…”

Towards a Spectroscopic and Theoretical Identification of the Isolated Building Blocks of the Benzene–Acetylene Cocrystal

“…The p-p stacking interactions play a fundamental role in many aspects of science, and these interactions are an interesting subject experimentally and theoretically because of the biological importance [1][2][3][4][5][6][7][8][9][10][11][12][13][14][15][16]. These interactions between nucleic acid bases govern information about chemistry of these biomolecules; for example, the final macromolecular structure such as nucleic acids [17][18][19][20][21][22], folding of proteins [23], enzyme-substrate recognition [17,18] crystal packing [24] and structures of carbon nanotube included these interactions [25].…”

Theoretical investigation of the nature and strength of simultaneous interactions of π–π stacking and halogen bond including NMR, SAPT, AIM and NBO analysis

Superbenzene–Porphyrin Gas‐Phase Architectures Derived from Intermolecular Dispersion Interactions