@article{59842,
author = {{Kothe, Linda and Kloß, Marvin and Wagner, Tobias and Wengenroth, Marc and Poeplau, Michael and Ester, Stephan and Tiemann, Michael}},
issn = {{1932-7447}},
journal = {{The Journal of Physical Chemistry C}},
number = {{19}},
pages = {{9239--9245}},
publisher = {{American Chemical Society (ACS)}},
title = {{{Temperature Studies of Zinc Tin Oxide Photoluminescence for Optical O2 Sensing}}},
doi = {{10.1021/acs.jpcc.5c01678}},
volume = {{129}},
year = {{2025}},
}
@article{52534,
author = {{Bauch, Fabian and Dong, Chuan-Ding and Schumacher, Stefan}},
issn = {{1932-7447}},
journal = {{The Journal of Physical Chemistry C}},
keywords = {{Surfaces, Coatings and Films, Physical and Theoretical Chemistry, General Energy, Electronic, Optical and Magnetic Materials}},
number = {{8}},
pages = {{3525--3532}},
publisher = {{American Chemical Society (ACS)}},
title = {{{Dynamics of Electron–Hole Coulomb Attractive Energy and Dipole Moment of Hot Excitons in Donor–Acceptor Polymers}}},
doi = {{10.1021/acs.jpcc.3c07513}},
volume = {{128}},
year = {{2024}},
}
@article{61259,
author = {{Bauch, Fabian and Dong, Chuan-Ding and Schumacher, Stefan}},
issn = {{1932-7447}},
journal = {{The Journal of Physical Chemistry C}},
number = {{8}},
pages = {{3525--3532}},
publisher = {{American Chemical Society (ACS)}},
title = {{{Dynamics of Electron–Hole Coulomb Attractive Energy and Dipole Moment of Hot Excitons in Donor–Acceptor Polymers}}},
doi = {{10.1021/acs.jpcc.3c07513}},
volume = {{128}},
year = {{2024}},
}
@article{61357,
author = {{Krenz, Marvin and Sanna, Simone and Gerstmann, Uwe and Schmidt, Wolf Gero}},
issn = {{1932-7447}},
journal = {{The Journal of Physical Chemistry C}},
number = {{41}},
pages = {{17774--17778}},
publisher = {{American Chemical Society (ACS)}},
title = {{{Understanding and Improving Triplet Exciton Transfer in Sensitized Silicon Solar Cells}}},
doi = {{10.1021/acs.jpcc.4c05446}},
volume = {{128}},
year = {{2024}},
}
@article{49356,
author = {{Moffitt, Stephanie L. and Cao, Chuntian and Van Hest, Maikel F. A. M. and Schelhas, Laura T. and Steinrück, Hans-Georg and Toney, Michael F.}},
issn = {{1932-7447}},
journal = {{The Journal of Physical Chemistry C}},
keywords = {{Surfaces, Coatings and Films, Physical and Theoretical Chemistry, General Energy, Electronic, Optical and Magnetic Materials}},
number = {{47}},
pages = {{23099–23108}},
publisher = {{American Chemical Society (ACS)}},
title = {{{Heterogeneous Structural Evolution of In–Zn–O Thin Films during Annealing}}},
doi = {{10.1021/acs.jpcc.3c06410}},
volume = {{127}},
year = {{2023}},
}
@article{54850,
author = {{Meier, Lukas and Schmidt, Wolf Gero}},
issn = {{1932-7447}},
journal = {{The Journal of Physical Chemistry C}},
number = {{4}},
pages = {{1973--1980}},
publisher = {{American Chemical Society (ACS)}},
title = {{{Adsorption of Cyclic (Alkyl) (Amino) Carbenes on Monohydride Si(001) Surfaces: Interface Bonding and Electronic Properties}}},
doi = {{10.1021/acs.jpcc.2c07316}},
volume = {{127}},
year = {{2023}},
}
@article{33690,
author = {{Ibaceta-Jaña, Josefa and Chugh, Manjusha and Novikov, Alexander S. and Mirhosseini, Hossein and Kühne, Thomas and Szyszka, Bernd and Wagner, Markus R. and Muydinov, Ruslan}},
issn = {{1932-7447}},
journal = {{The Journal of Physical Chemistry C}},
keywords = {{Surfaces, Coatings and Films, Physical and Theoretical Chemistry, General Energy, Electronic, Optical and Magnetic Materials}},
number = {{38}},
pages = {{16215--16226}},
publisher = {{American Chemical Society (ACS)}},
title = {{{Do Lead Halide Hybrid Perovskites Have Hydrogen Bonds?}}},
doi = {{10.1021/acs.jpcc.2c02984}},
volume = {{126}},
year = {{2022}},
}
@article{33651,
author = {{Sahoo, Sudhir K. and Teixeira, Ivo F. and Naik, Aakash and Heske, Julian Joachim and Cruz, Daniel and Antonietti, Markus and Savateev, Aleksandr and Kühne, Thomas}},
issn = {{1932-7447}},
journal = {{The Journal of Physical Chemistry C}},
keywords = {{Surfaces, Coatings and Films, Physical and Theoretical Chemistry, General Energy, Electronic, Optical and Magnetic Materials}},
number = {{25}},
pages = {{13749--13758}},
publisher = {{American Chemical Society (ACS)}},
title = {{{Photocatalytic Water Splitting Reaction Catalyzed by Ion-Exchanged Salts of Potassium Poly(heptazine imide) 2D Materials}}},
doi = {{10.1021/acs.jpcc.1c03947}},
volume = {{125}},
year = {{2021}},
}
@article{41002,
abstract = {{Homogeneous catalysts immobilized on metal oxides often have different catalytic properties than in homogeneous solution. This can be either activating or deactivating and is often attributed to interactions of catalyst species with the metal oxide surface. However, few studies have ever demonstrated the effect that close associations of active sites with surfaces have on the catalytic activity. In this paper, we immobilize H2Ru(PPh3)2(Ph2P)2N–C3H6–Si(OEt)3 (3) on SiO2, Al2O3, and ZnO and interrogate the relationship to the surface using IR, MAS NMR, 1H–31P HETCOR, and XAS spectroscopies. We found that while there are close contacts between the P atoms of the complex and all three metal oxide surfaces, the Ru–H bond only reacts with oxygen bridges on SiO2 and Al2O3, forming new Ru–O bonds. In contrast, complex 3 stays intact on ZnO. Comparison of the catalytic activities of our immobilized species for CO2 hydrogenation to ethyl formate showed that Lewis acidic metal oxides activate, rather than deactivate, complex 3 in the order Al2O3 > ZnO > SiO2. The Lewis acidic sites on the metal oxide surfaces most likely increase the productivity by increasing the rate of esterification of formate intermediates.}},
author = {{Nguyen, Hoang-Huy and Li, Zheng and Enenkel, Toni and Hildebrand, Joachim and Bauer, Matthias and Dyballa, Michael and Estes, Deven P.}},
issn = {{1932-7447}},
journal = {{The Journal of Physical Chemistry C}},
keywords = {{Surfaces, Coatings and Films, Physical and Theoretical Chemistry, General Energy, Electronic, Optical and Magnetic Materials}},
number = {{27}},
pages = {{14627--14635}},
publisher = {{American Chemical Society (ACS)}},
title = {{{Probing the Interactions of Immobilized Ruthenium Dihydride Complexes with Metal Oxide Surfaces by MAS NMR: Effects on CO2 Hydrogenation}}},
doi = {{10.1021/acs.jpcc.1c02074}},
volume = {{125}},
year = {{2021}},
}
@article{29748,
author = {{Slawig, Diana and Gruschwitz, Markus and Gerstmann, Uwe and Rauls, Eva and Tegenkamp, Christoph}},
issn = {{1932-7447}},
journal = {{The Journal of Physical Chemistry C}},
keywords = {{Surfaces, Coatings and Films, Physical and Theoretical Chemistry, General Energy, Electronic, Optical and Magnetic Materials}},
number = {{36}},
pages = {{20087--20093}},
publisher = {{American Chemical Society (ACS)}},
title = {{{Adsorption and Reaction of PbPc on Hydrogenated Epitaxial Graphene}}},
doi = {{10.1021/acs.jpcc.1c06320}},
volume = {{125}},
year = {{2021}},
}
@article{40433,
author = {{Dong, Chuan-Ding and Schumacher, Stefan}},
issn = {{1932-7447}},
journal = {{The Journal of Physical Chemistry C}},
keywords = {{Surfaces, Coatings and Films, Physical and Theoretical Chemistry, General Energy, Electronic, Optical and Magnetic Materials}},
number = {{40}},
pages = {{21824--21830}},
publisher = {{American Chemical Society (ACS)}},
title = {{{Microscopic Insights into Charge Formation and Energetics in n-Doped Organic Semiconductors}}},
doi = {{10.1021/acs.jpcc.1c05666}},
volume = {{125}},
year = {{2021}},
}
@article{20496,
author = {{Streiter, Martin and Fischer, Tillmann G. and Wiebeler, Christian and Reichert, Sebastian and Langenickel, Jörn and Zeitler, Kirsten and Deibel, Carsten}},
issn = {{1932-7447}},
journal = {{The Journal of Physical Chemistry C}},
keywords = {{pc2-ressources}},
pages = {{15007--15014}},
title = {{{Impact of Chlorine on the Internal Transition Rates and Excited States of the Thermally Delayed Activated Fluorescence Molecule 3CzClIPN}}},
doi = {{10.1021/acs.jpcc.0c03341}},
year = {{2020}},
}
@article{17066,
author = {{Aldahhak, Hazem and Powroźnik, Paulina and Pander, Piotr and Jakubik, Wiesław and Dias, Fernando B. and Schmidt, Wolf Gero and Gerstmann, Uwe and Krzywiecki, Maciej}},
issn = {{1932-7447}},
journal = {{The Journal of Physical Chemistry C}},
number = {{124}},
pages = {{6090--6102}},
title = {{{Toward Efficient Toxic-Gas Detectors: Exploring Molecular Interactions of Sarin and Dimethyl Methylphosphonate with Metal-Centered Phthalocyanine Structures}}},
doi = {{10.1021/acs.jpcc.9b11116}},
year = {{2020}},
}
@article{63042,
author = {{Sistani, Masiar and Bartmann, Maximilian G. and Güsken, Nicholas Alexander and Oulton, Rupert F. and Keshmiri, Hamid and Luong, Minh Anh and Robin, Eric and den Hertog, Martien I. and Lugstein, Alois}},
issn = {{1932-7447}},
journal = {{The Journal of Physical Chemistry C}},
number = {{25}},
pages = {{13872--13877}},
publisher = {{American Chemical Society (ACS)}},
title = {{{Stimulated Raman Scattering in Ge Nanowires}}},
doi = {{10.1021/acs.jpcc.0c02602}},
volume = {{124}},
year = {{2020}},
}
@article{19504,
author = {{Dong, Chuan-Ding and Schumacher, Stefan}},
issn = {{1932-7447}},
journal = {{The Journal of Physical Chemistry C}},
keywords = {{pc2-ressources}},
pages = {{30863--30870}},
title = {{{Molecular Doping of PCPDT–BT Copolymers: Comparison of Molecular Complexes with and without Integer Charge Transfer}}},
doi = {{10.1021/acs.jpcc.9b09970}},
year = {{2019}},
}
@article{16960,
author = {{Mennicken, Max and Peter, Sophia Katharina and Kaulen, Corinna and Simon, Ulrich and Karthäuser, Silvia}},
issn = {{1932-7447}},
journal = {{The Journal of Physical Chemistry C}},
keywords = {{pc2-ressources}},
pages = {{21367--21375}},
title = {{{Controlling the Electronic Contact at the Terpyridine/Metal Interface}}},
doi = {{10.1021/acs.jpcc.9b05865}},
year = {{2019}},
}
@article{15740,
author = {{Guc, Maxim and Kodalle, Tim and Kormath Madam Raghupathy, Ramya and Mirhosseini, Hossein and Kühne, Thomas D. and Becerril-Romero, Ignacio and Pérez-Rodríguez, Alejandro and Kaufmann, Christian A. and Izquierdo-Roca, Victor}},
issn = {{1932-7447}},
journal = {{The Journal of Physical Chemistry C}},
pages = {{1285--1291}},
title = {{{Vibrational Properties of RbInSe2: Raman Scattering Spectroscopy and First-Principle Calculations}}},
doi = {{10.1021/acs.jpcc.9b08781}},
volume = {{124}},
year = {{2019}},
}
@article{14021,
author = {{Peter, Sophia Katharina and Kaulen, Corinna and Hoffmann, Alexander and Ogieglo, Wojciech and Karthäuser, Silvia and Homberger, Melanie and Herres-Pawlis, Sonja and Simon, Ulrich}},
issn = {{1932-7447}},
journal = {{The Journal of Physical Chemistry C}},
number = {{11}},
pages = {{6537--6548}},
title = {{{Stepwise Growth of Ruthenium Terpyridine Complexes on Au Surfaces}}},
doi = {{10.1021/acs.jpcc.8b12039}},
volume = {{123}},
year = {{2019}},
}
@article{15723,
abstract = {{RbInSe2 is attracting growing interest as a secondary semiconductor compound in Cu(In,Ga)Se2-based solar cells by virtue of the recent investigations on absorber post-deposition treatments with alkali metal salts that have resulted in significant efficiency improvements. However, the detection of the RbInSe2 phase on the surface of chalcopyrite absorbers is very challenging due to its nanometric thickness and the limited information available about its fundamental properties. In this context, this work expounds a detailed analysis of the vibrational properties of RbInSe2 that combines first-principle calculations with multiwavelength Raman scattering spectroscopy and provides a methodology for the detection and identification of very thin layers of this material employing solely optical measurements. As a result, here, we present the classification of the different vibrational modes together with the fingerprint Raman spectra of RbInSe2 thin films measured under five different excitations (close to and far from resonance). The employment of a 442 nm excitation wavelength is found to be the most adequate strategy for the detection and characterization of the RbInSe2 phase in view of its resonance with the band gap of the material and its low penetration depth. Additionally, the purity of the deposited thin films as well as the possible influence of the subjacent layers on the Raman spectra of the compound are also investigated by analyzing the presence of secondary phases and by measuring RbInSe2 thin films deposited onto Mo-coated soda-lime glass, respectively. These results set the basis for the future evaluation of the suitability of Raman spectroscopy as a fast and nondestructive characterization technique for the reliable identification and characterization of the nanometric layers of RbInSe2 in Cu(In,Ga)Se2-based solar cells.}},
author = {{Guc, Maxim and Kodalle, Tim and Kormath Madam Raghupathy, Ramya and Mirhosseini, Hossein and Kühne, Thomas and Becerril-Romero, Ignacio and Pérez-Rodríguez, Alejandro and Kaufmann, Christian A. and Izquierdo-Roca, Victor}},
issn = {{1932-7447}},
journal = {{The Journal of Physical Chemistry C}},
pages = {{1285--1291}},
title = {{{Vibrational Properties of RbInSe2: Raman Scattering Spectroscopy and First-Principle Calculations}}},
doi = {{10.1021/acs.jpcc.9b08781}},
year = {{2019}},
}
@article{25904,
abstract = {{We examined the effect of CaCl2 and LiCl on ice melting in mesoporous silica (MCM-41 and SBA-15 silica). For that purpose, we determined the ice melting temperature in pores of various size (pore radii between 1.9 and 11.1 nm) in water and aqueous solutions up to high total solute molality (up to about 12 mol kg–1) using differential scanning calorimetry. We found that both electrolytes reduce the ice melting temperature within the pores. An exception is the melting of ice in the smallest pores, which does not seem to be affected by the presence of solutes, most likely owing to an exclusion of the ions from entering the pores. For all other pores, we observed that the ice melting temperature decreases as a function of pore size and electrolyte concentration. Using thermodynamic considerations as well as additional experimental data we developed a parametrization that can be used to predict the ice melting point as a function of pore size and total solute molality. For that purpose, we extended a formulation of the effective water activity of aqueous solutions under mechanical pressure toward its application in confinement and tested this new parametrization on literature data.}},
author = {{Jantsch, Evelyn and Weinberger, Christian and Tiemann, Michael and Koop, Thomas}},
issn = {{1932-7447}},
journal = {{The Journal of Physical Chemistry C}},
pages = {{24566--24574}},
title = {{{Phase Transitions of Ice in Aqueous Salt Solutions within Nanometer-Sized Pores}}},
doi = {{10.1021/acs.jpcc.9b06527}},
year = {{2019}},
}