The vibrational coupling in the ground and excited states of positively charged naphthalene, anthracene, tetracene, and pentacene molecules is studied on the basis of a joint experimental and theoretical study of ionization spectra using high-resolution gas-phase photoelectron spectroscopy and first-principles correlated quantum-mechanical calculations. Our theoretical and experimental results reveal that, while the main contribution to relaxation energy in the ground state of oligoacene systems comes from high-energy vibrations, the excited-state relaxation energies show a significant redistribution toward lower-frequency vibrations. A direct correlation is found between the nature of the vibronic interaction and the pattern of the electronic state structure.
Neurogenesis occurs constitutively within the periventricular region (PVR) of the lateral ventricles (LV) of the adult mammalian brain. The occurrence of adult neurogenesis within the PVR outside the neurogenic niche of the LV remains controversial, but neural stem cells can be isolated from PVR of the whole ventricular system. The histological basis of this phenomenon including the regional differences of cellular phenotypes within the PVRs is still enigmatic. The occurrence of neurogenesis or manipulable progenitor cells in caudal parts of the adult brain is however one prerequisite for orthotopic regenerative approaches in Parkinson's disease (PD) and other disorders of the midbrain/brainstem. Using quantitative immunohistochemical techniques and electron microscopy, we found a rostro-caudal gradual loss of cellular diversity within the PVR throughout the whole ventricular axis with loss of transit amplifying epidermal growth factorreceptor 1 type C cells in all parts caudal to the LV, a gradual reduction from rostral to caudal of both stem cells (type B cells or astrocytes) without signs of proliferation outside the PVR of the LV as well as neuroblasts-like cells (polysialylated neural cell adhesion molecule [PSA-NCAM] 1 , but doublecortin negative cells) with a different morphology compared with neuroblasts of the PVR of the LV. Electron microscopy confirmed these immunohistochemical data. The proportion of Nestin 1 /CD24 1 cells and Nestin 1 /S100b 1 ependymal cells were consecutively increased in the PVR from rostral to caudal, and ultrastructural analysis showed a region-specific morphology with darker cytoplasm with occasional large lipid droplets as well as indented nuclei within the caudal PVRs. The strong correlation of neuroblast-like cells with the number of neurosphere-forming cells suggests that a quiescent subtype of PSA-NCAM 1 cells might be a source of neurosphere-forming cells. We did not find any evidence for neurogenesis or the occurrence of neuroprogenitors within the substantia nigra or other parts of the midbrain/brainstem outside the PVR. Our data provide the histological framework for future studies on orthotopic regenerative approaches in PD by recruiting endogenous predopaminergic progenitors from the midbrain PVR. STEM CELLS 2009;27:928-941 Disclosure of potential conflicts of interest is found at the end of this article.
High-resolution x-ray photoelectron emission (XPS) and near-edge x-ray absorption fine structure (NEXAFS) spectra of naphthalene are analyzed in terms of the initial state chemical shifts and the vibrational fine structure of the excitations. Carbon atoms located at peripheral sites experience only a small chemical shift and exhibit rather similar charge-vibrational coupling, while the atoms in the bridging positions differ substantially. In the XPS spectra, C-H stretching modes provide important contributions to the overall shape of the spectrum. In contrast, the NEXAFS spectrum contains only vibrational progressions from particular C-C stretching modes. The accuracy of ab initio calculations of absolute electronic transition energies is discussed in the context of minute chemical shifts, the vibrational fine structure, and the state multiplicity.
We report on the morphological aspects of thin films prepared from a blue–green light‐emitting conjugated polymer, (methyl‐substituted ladder‐type poly(p‐phenylene, mLPPP)), blended with a solid‐state electrolyte composed either by a crown ether, dicyclohexano‐18‐crown‐6 (DCH18C6), or a high‐molecular‐weight poly(ethylene oxide) (HMWPEO), and a Li salt, lithium trifluoromethanesulfonate (LiCF3SO3, Li triflate (LiTf)), as they have been successfully applied in light‐emitting electrochemical cells (LECs). The surface morphologies of the blend layers were investigated using atomic force microscopy (AFM) in tapping mode, and the ion distribution was probed using X‐ray analysis by means of energy‐dispersive X‐ray spectrometry (EDXS) in the scanning electron microscope (SEM). We show that the two different phase‐separation processes, the complexation tendencies of the ionic species as well as the ionic transport numbers, have tremendous influence on the performances of the corresponding LECs, revealing either rectifying or symmetric optoelectronic characteristics in forward and reverse bias directions. This opens up new possibilities for tuning the optoelectronic properties of ion‐supported organic electronic devices.
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