Primary optical excitations and excited-state interaction energies in sexithiophene

Abstract: Based on a unique combination of angle-resolved transmission spectroscopy and transmission data at high pressure, we identify the primary photoexcitations and the relevant excited-state interaction energies in a sexithiophene crystal. Optical excitations include charge-transfer excitons and Davydov polaritons. By extrapolation, we predict that in sexithiophene at hydrostatic pressures above 180 kbar, intermolecular excitations are lower in energy than intramolecular ones. The results are representative for a w… Show more

“…[6] Recent experiments of Loi et. al [7] interpret peak A 2 as a charge transfer transition, in conflict with our Frenkel exciton interpretation. Moller et al [26] also argue against a charge transfer origin based on an analysis of their electro-absorption measurements.…”

“…The interaction sums can be partitioned as J(k) + 4pm(l´k à ) 2 /e ¥ m 0 , where m is the number of molecules per unit cell of volume m 0 , and k à is a unit vector along k. [21] Hence, in the long wavelength limit the energy of the longitudinal exciton (l´k à = l) exceeds that of the transverse exciton (l´k à = 0) by 4pm(l´k à ) 2 /e ¥ m 0 which is » 0.8 eV for aT6. [7] An orientationally dependent DS has recently been measured in aT6 crystals [7] as well as highly ordered sexiphenyl films, [23] in both cases slightly exceeding 1 eV when k is close to parallel with the long molecular axis. A direct measurement of the strong H-peak in the crystal limit is difficult in transmission experiments because of the large extinction coefficient.…”

“…Many methods for the synthesis of inorganic nanotubes have been based on high-temperature processes. These include chemical vapor transport, [4] sol±gel process, [5] arc-discharge, [6] solvothermal treatment, [7] and oxide nanowhisker growth. [8] Low-temperature routes such as templated synthesis have also been attempted, [9,10] but it has proved difficult to form single-crystalline nanotubes.…”

Absorption and Emission in Quaterthienyl Thin Films

“…[6] Recent experiments of Loi et. al [7] interpret peak A 2 as a charge transfer transition, in conflict with our Frenkel exciton interpretation. Moller et al [26] also argue against a charge transfer origin based on an analysis of their electro-absorption measurements.…”

“…The interaction sums can be partitioned as J(k) + 4pm(l´k à ) 2 /e ¥ m 0 , where m is the number of molecules per unit cell of volume m 0 , and k à is a unit vector along k. [21] Hence, in the long wavelength limit the energy of the longitudinal exciton (l´k à = l) exceeds that of the transverse exciton (l´k à = 0) by 4pm(l´k à ) 2 /e ¥ m 0 which is » 0.8 eV for aT6. [7] An orientationally dependent DS has recently been measured in aT6 crystals [7] as well as highly ordered sexiphenyl films, [23] in both cases slightly exceeding 1 eV when k is close to parallel with the long molecular axis. A direct measurement of the strong H-peak in the crystal limit is difficult in transmission experiments because of the large extinction coefficient.…”

“…Many methods for the synthesis of inorganic nanotubes have been based on high-temperature processes. These include chemical vapor transport, [4] sol±gel process, [5] arc-discharge, [6] solvothermal treatment, [7] and oxide nanowhisker growth. [8] Low-temperature routes such as templated synthesis have also been attempted, [9,10] but it has proved difficult to form single-crystalline nanotubes.…”

Absorption and Emission in Quaterthienyl Thin Films

“…These include chemical vapor transport, [4] sol±gel process, [5] arc-discharge, [6] solvothermal treatment, [7] and oxide nanowhisker growth. [8] Low-temperature routes such as templated synthesis have also been attempted, [9,10] but it has proved difficult to form single-crystalline nanotubes.…”

Single‐Crystalline Scroll‐Type Nanotube Arrays of Copper Hydroxide Synthesized at Room Temperature

“…This situation has changed recently because of the current interest in the physics of oligothiophene crystals, where the lowest electronic transition is very intense. Polaritons were invoked to explain some features of the absorption and electroabsorption spectra of α-sexithiophene [5,6]. A detailed investigation based on classical electrodynamics falsified the newly introduced interpretational paradigm for electroabsorption spectroscopy [7,8], rooted in an erroneous understanding of polariton properties.…”

Polariton Effects in Molecular Crystals Studied by Classical and Quantum-Electrodynamic Approaches