Your search keyword '"Lüder J"' showing total 32 results

1. Laser Filament Induced Water Condensation

Author

Kasparian J., Webe K., Vogel A., Petit Y., Lüder J., Hao Z.Q., Rohwetter P., Petrarca M., Stelmaszczyk K., Henin S., Wöste L., and Wolf J.-P.

Subjects

Physics, QC1-999

Abstract

At relative humidities above 70%, femtosecond laser filaments generate aerosol particles and water droplets in the atmosphere. The water vapour condensation and droplet stabilization are assured by soluble species produced in the laser plasma.

Published

2013

2. Electronic structure investigation of biphenylene films.

Author

Totani, R., Grazioli, C., Zhang, T., Bidermane, I., Lüder, J., de Simone, M., Coreno, M., Brena, B., Lozzi, L., and Puglia, C.

Subjects

ELECTRONIC structure, BIPHENYLENE, DENSITY functional theory, THIN films analysis, ADSORPTION kinetics

Abstract

Photoelectron Spectroscopy (PS) and Near-Edge X-ray Absorption Fine Structure (NEXAFS) spectroscopy have been used to investigate the occupied and empty density of states of biphenylene films of different thicknesses, deposited onto a Cu(111) crystal. The obtained results have been compared to previous gas phase spectra and single molecule Density Functional Theory (DFT) calculations to get insights into the possible modification of the molecular electronic structure in the film induced by the adsorption on a surface. Furthermore, NEXAFS measurements allowed characterizing the variation of the molecular arrangement with the film thickness and helped to clarify the substrate-molecule interaction. [ABSTRACT FROM AUTHOR]

Published

2017

3. Experimental and theoretical study of electronic structure of lutetium bi-phthalocyanine.

Author

Bidermane, I., Lüder, J., Boudet, S., Zhang, T., Ahmadi, S., Grazioli, C., Bouvet, M., Rusz, J., Sanyal, B., Eriksson, O., Brena, B., Puglia, C., and Witkowski, N.

Subjects

*ELECTRONIC structure, *PHTHALOCYANINES, *LUTETIUM compounds, *X-ray spectroscopy, *THICKNESS measurement, *THIN films, *SURFACES (Physics), *DENSITY functional theory

Abstract

Using Near Edge X-Ray Absorption Fine Structure (NEXAFS) Spectroscopy, the thickness dependent formation of Lutetium Phthalocyanine (LuPc2) films on a stepped passivated Si(100)2×1 reconstructed surface was studied. Density functional theory (DFT) calculations were employed to gain detailed insights into the electronic structure. Photoelectron spectroscopy measurements have not revealed any noticeable interaction of LuPc2 with the H-passivated Si surface. The presented study can be considered to give a comprehensive description of the LuPc2 molecular electronic structure. The DFT calculations reveal the interaction of the two molecular rings with each other and with the metallic center forming new kinds of orbitals in between the phthalocyanine rings, which allows to better understand the experimentally obtained NEXAFS results. [ABSTRACT FROM AUTHOR]

Published

2013

4. Conclusively Addressing the CoPc Electronic Structure: A Joint Gas-Phase and Solid-State Photoemission and Absorption Spectroscopy Study

Author

Zhang, T., primary, Brumboiu, I. E., additional, Lanzilotto, V., additional, Lüder, J., additional, Grazioli, C., additional, Giangrisostomi, E., additional, Ovsyannikov, R., additional, Sassa, Y., additional, Bidermane, I., additional, Stupar, M., additional, de Simone, M., additional, Coreno, M., additional, Ressel, B., additional, Pedio, M., additional, Rudolf, P., additional, Brena, B., additional, and Puglia, C., additional

Published

2017

5. When the Grafting of Double Decker Phthalocyanines on Si(100)-2 × 1 Partly Affects the Molecular Electronic Structure

Author

Bidermane, I., primary, Lüder, J., additional, Ahmadi, S., additional, Grazioli, C., additional, Bouvet, M., additional, Brena, B., additional, Mårtensson, N., additional, Puglia, C., additional, and Witkowski, N., additional

Published

2016

6. Breakpoint Detection within the Time Series. Modeling Approach Upon Paleoclimatic Proxy Data

Author

Lüder, J., Achim Brauer, and Jurisch, R.

Subjects

historical analysis, Science, 550 - Earth sciences, Naturwissenschaften, Federal Republic of Germany, Modell, Forschungsarten der Sozialforschung, Strategie, basic research, Trend, Zeitreihe, Social sciences, sociology, anthropology, Natural Science and Engineering, Applied Sciences, Klimawandel, Sozialwissenschaften, Soziologie, model, estimation, Bundesrepublik Deutschland, Berlin, Naturwissenschaften, Technik(wissenschaften), angewandte Wissenschaften, climate change, development of methods, Research Design, Methodenentwicklung, model construction, ddc:300, ddc:500, Modellentwicklung, time series, strategy, historische Analyse, Schätzung, Grundlagenforschung

Abstract

»Bruchpunktdetektion im Prozess der Zeitreihenmodellierung anhand paläoklimatologischer Proxydaten«. A large portion of research in time series analysis addresses questioning specific components like trend, cycle or seasonal behavior. Although there is a vast number of publications, only a small amount focuses on the research of irregularities, which are supposed to be within time series – especially in long-term data. Thus this paper focuses on detection of those irregularities and to illustrate the importance of breakpoint estimation. The underlying research theme is given by the discipline of Paleoclimatology. The investigation has been realized upon varved lake sediments as one of common proxydata in paleoclimatics. As the discipline provides insights in climate variability, questioning climate changes implies crucial information about mechanisms of rapid climate shifts. The paper shall also outline the importance of such information, since conducting time series modeling without interdisciplinary research constitutes an almost impossible task. Consequently time series analysis turns out in a procedure of modeling supposed components – like trend, cycles or irregularities – of the underlying datagenerating process and to image those in an appropriate degree.

Published

2012

7. Treatment Results in Pulmonary Metastasized Germ Cell Tumors of the Testis

Author

Niederle, N., primary, Lüder, J., additional, and Walz, M., additional

Published

1988

8. Laser filament-induced aerosol formation

Author

Saathoff, H., primary, Henin, S., additional, Stelmaszczyk, K., additional, Petrarca, M., additional, Delagrange, R., additional, Hao, Z., additional, Lüder, J., additional, Möhler, O., additional, Petit, Y., additional, Rohwetter, P., additional, Schnaiter, M., additional, Kasparian, J., additional, Leisner, T., additional, Wolf, J.-P., additional, and Wöste, L., additional

Published

2013

9. Modelling and Experimental Validation of the Eccentric Collision with Friction of a Planar Bar on a Rigid Plane

Author

Lüder, J., Kecskeméthy, Andrés, and Hiller, Manfred

Subjects

Maschinenbau

Published

1997

10. Laser Filament Induced Water Condensation

Author

Henin, S., primary, Stelmaszczyk, K., additional, Petrarca, M., additional, Rohwetter, P., additional, Hao, Z.Q., additional, Lüder, J., additional, Petit, Y., additional, Vogel, A., additional, Webe, K., additional, Kasparian, J., additional, Wöste, L., additional, and Wolf, J.-P., additional

Published

2013

11. Laser filament-induced aerosol formation

Author

Saathoff, H., primary, Henin, S., additional, Stelmaszczyk, K., additional, Petrarca, M., additional, Delagrange, R., additional, Hao, Z., additional, Lüder, J., additional, Möhler, O., additional, Petit, Y., additional, Rohwetter, P., additional, Schnaiter, M., additional, Kasparian, J., additional, Leisner, T., additional, Wolf, J.-P., additional, and Wöste, L., additional

Published

2012

12. Akute Gastrointestinalblutung bei ausgeprägter Dünndarmdivertikulose

Author

Friebe, M, primary, Allerödder, H, additional, Lüder, J, additional, and Kindler, U, additional

Published

2001

13. Laser filament-induced aerosol formation.

Author

Saathoff, H., Henin, S., Stelmaszczyk, K., Petrarca, M., Delagrange, R., Hao, Z., Lüder, J., Möhler, O., Petit, Y., Rohwetter, P., Schnaiter, M., Kasparian, J., Leisner, T., Wolf, J.-P., and Wöste, L.

Abstract

Using the aerosol and cloud simulation chamber AIDA we investigated the laser filament induced particle formation in ambient air, humid synthetic air, humid nitrogen, argon-oxygen mixture, and pure argon in order to simulate the particle formation under realistic atmospheric conditions as well as to investigate the influence of typical gas-phase atmospheric constituents on the particle formation. Terawatt laser plasma filaments generated new particles in the size range 3 to 130nm with particle production rates ranging from 1 x 107 to 5 x 109 cm-3 plasmas-1. In all cases the particle formation rates increased exponentially with the water content of the gas mixture. Furthermore, the presence of a few ppb of trace gases like SO2 and a-pinene clearly enhanced the particle yield by number, the latter also by mass. Our findings suggest that new particle formation is efficiently supported by acids generated by the photo-ionization of both major and minor components of the air, including N2, NH3, SO2 and organics. [ABSTRACT FROM AUTHOR]

Published

2012

14. Iron phthalocyanine on copper nitride: geometry, spin state, and modification by pyridine adsorption

Author

Snezhkova, O., Lüder, J., Chaudhary, S., Coman, C., Knudsen, J., Schulte, K., Brena, B., Schnadt, J., Snezhkova, O., Lüder, J., Chaudhary, S., Coman, C., Knudsen, J., Schulte, K., Brena, B., and Schnadt, J.

Abstract

Using a monolayer of iron phthalocyanine adsorbed on the Au(111) surface and on a Cu(111)-supported two-dimensional copper nitride layer, we show how the modification of the support can influence the electronic and magnetic properties of an adsorbed transition metal complex. The two systems have been studied by a combination of electron spectroscopy and first principles theoretical calculations, which included modelling of the van der Waals interactions. For adsorption of iron phthalocyanine on the Cu(100)c(2x2)-2N/Cu(111) surface we find several different adsorbate structures at different surface sites, which all have very similar energies. Depending on the adsorption site - above a support nitrogen or a support copper atom - the spin magnetic moment of the molecular iron ion assumes different values. Although pyridine adsorption on the iron phthalocyanine monolayer reduces the spin magnetic moments for all phthalocyanine adsorption sites, the difference between the different sites persists: only for the iron phthalocyanine adsorbates with the central iron ion above a support nitrogen atom the spin is quenched completely, while a residual spin magnetic moment is found for the adsorption structures with the iron ion above a copper atom. The results illustrate clearly the relevance of the support as a ligand to the central ion.

15. Theory of X-ray spectroscopy of strongly correlated systems

Author

Lüder, J., Brena, B., Haverkort, M. W., Eriksson, O., Sanyal, B., Di Marco, I., Kvashnin, Y. O., Lüder, J., Brena, B., Haverkort, M. W., Eriksson, O., Sanyal, B., Di Marco, I., and Kvashnin, Y. O.

Abstract

X-ray absorption spectroscopy measured at the L-edge of transition metals (TMs) is a powerful element-selective tool providing direct information about the correlation effects in the 3d states. The theoretical modelling of the 2p to 3d excitation processes remains a challenge for contemporary ab initio electronic structure techniques, due to strong core-hole and multiplet effects influencing the spectra. In this work we present a realisation of the method combining the density functional theory with multiplet ligand field theory, proposed in Phys. Rev. B 85, 165113 (2012). The core of this approach is the solution of the single-impurity Anderson model (SIAM), parameterised from first principles.In our implementation, we adopt the dynamical mean-field theory and utilize the local Hamiltonian and the hybridisation function, projected onto TM 3d states, in order to construct the SIAM. We show that the current method can be used as an alternative to the construction of the Wannier functions. The developed computational scheme is applied to calculate the L-edge spectra for several TM monoxides. An excellent agreement between the theory and experiment is found for all studied systems. The possible extensions of the method as well as its limitations are discussed.

16. Electronic correlations revealed by hybrid functional and GW calculations in the anti-aromatic biphenylene molecule

Author

Lüder, J., Sanyal, B., Eriksson, O., Brena, B., Lüder, J., Sanyal, B., Eriksson, O., and Brena, B.

Abstract

The biphenylene molecule is an interesting new candidate as a building block for advanced 2D materials. In this study, the molecular properties of biphenylene, like ionization potential and electron affinity, as well as the HOMO-LUMO gap were computed with the GW approach and with hybrid functional Density Functional Theory. B3LYP, HSE and HSE06 were compared as well as with the OT-RSH approach. The electronic structure of the valence states obtained by GW calculations and hybrid functionals was compared to experimental valence photoelectron spectroscopy data.

17. Core levels, valence band structures and unoccupied states of biphenylene films

Author

Totani, R., Grazioli, C., Zhang, T., Lüder, J., Bidermane, I., Lanzilotto, V., de Simone, M., Coreno, M., Brena, B., Lozzi, L., Puglia, C., Totani, R., Grazioli, C., Zhang, T., Lüder, J., Bidermane, I., Lanzilotto, V., de Simone, M., Coreno, M., Brena, B., Lozzi, L., and Puglia, C.

Abstract

Biphenylene is a cyclic hydrocarbon made of two benzene rings connected by a cyclobutadiene ring. We performed a photoemission and near-edge absorption (PES and NEXAFS) spectroscopy investigation on biphenylene films of different thicknesses, deposited onto a Cu(111) crystal. By PES we studied the occupied core and valence levels, while NEXAFS gave us information on the unoccupied states. The obtained results have been compared to previous gas phase spectra and density functional theory (DFT) calculations on single biphenylene molecule to get insights in the film electronic structure and possible modification induces by the adsorption. Furthermore, NEXAFS results of biphenylene films of different thicknesses allowed the characterization of the molecular arrangement in the overlayer on the Cu surface and helped to clarify the substrate-molecule interactions.

18. Covalent-Organic-Framework-Modified Quartz Crystal Microbalance Sensor for Selective Detection of Hazardous Formic Acid.

Author

Ahmed LR, Lüder J, Chuang CH, and El-Mahdy AFM

Abstract

Covalent organic frameworks (COFs) are a novel family of porous crystalline materials utilized in various advanced applications. However, applying COFs as a hazardous organic acid gas sensor is substantial but still challenging. Herein, a phenylenediamine-based covalent organic framework (TPDA-TPB COF) featuring excellent crystallinity, ultrastable thermal stability, and high surface area was successfully constructed. Then, the TPDA-TPB COF-modified quartz crystal microbalance (QCM) sensor is fabricated by immobilizing the TPDA-TPB COF thin film on the gold-QCM chip. The fabricated TPDA-TPB COF-modified QCM sensor demonstrates a rapid response, excellent reproducibility, high selectivity, and sensitivity to formic gas, arising from hydrogen-bonding interactions between formic acid and the outermost layer of the TPDA-TPB COF, as determined by extensive analysis and density functional theory calculations. The basic sites of the TPDA-TPB COF, which are numerous due to its high nitrogen content, and the carboxylic acid groups present in formic acid exhibit efficient interactions. The sensitivity of the TPDA-TPB COF-modified QCM sensor was found to be 7.75 Hz ppm -1 at standard room temperature and pressure conditions, with a limit of detection (LOD) of formic acid down to 1.18 ppm, which is significantly below the workplace olfactory threshold limit of 5.0 ppm established by the Occupational Safety and Health Administration. The TPDA-TPB COF-modified QCM sensor exhibits remarkable detecting capabilities, making it highly attractive for detecting organic acid vapors in diverse applications that require superior performance.

Published

2024

19. Machine learning of kinetic energy densities with target and feature smoothing: Better results with fewer training data.

Author

Manzhos S, Lüder J, and Ihara M

Abstract

Machine learning (ML) of kinetic energy functionals (KEFs), in particular kinetic energy density (KED) functionals, is a promising way to construct KEFs for orbital-free density functional theory (DFT). Neural networks and kernel methods including Gaussian process regression (GPR) have been used to learn Kohn-Sham (KS) KED from density-based descriptors derived from KS DFT calculations. The descriptors are typically expressed as functions of different powers and derivatives of the electron density. This can generate large and extremely unevenly distributed datasets, which complicates effective application of ML techniques. Very uneven data distributions require many training datapoints, can cause overfitting, and can ultimately lower the quality of an ML KED model. We show that one can produce more accurate ML models from fewer data by working with smoothed density-dependent variables and KED. Smoothing palliates the issue of very uneven data distributions and associated difficulties of sampling while retaining enough spatial structure necessary for working within the paradigm of KEDF. We use GPR as a function of smoothed terms of the fourth order gradient expansion and KS effective potential and obtain accurate and stable (with respect to different random choices of training points) kinetic energy models for Al, Mg, and Si simultaneously from as few as 2000 samples (about 0.3% of the total KS DFT data). In particular, accuracies on the order of 1% in a measure of the quality of energy-volume dependence B'=EV0-ΔV-2EV0+E(V0+ΔV)ΔV/V02 (where V0 is the equilibrium volume and ΔV is a deviation from it) are obtained simultaneously for all three materials., (© 2023 Author(s). Published under an exclusive license by AIP Publishing.)

Published

2023

20. Materials Design and Optimization for Next-Generation Solar Cell and Light-Emitting Technologies.

Author

Manzhos S, Chueh CC, Giorgi G, Kubo T, Saianand G, Lüder J, Sonar P, and Ihara M

Abstract

We review some of the most potent directions in the design of materials for next-generation solar cell and light-emitting technologies that go beyond traditional solid-state inorganic semiconductor-based devices, from both the experimental and computational standpoints. We focus on selected recent conceptual advances in tackling issues which are expected to significantly impact applied literature in the coming years. Specifically, we consider solution processability, design of dopant-free charge transport materials, two-dimensional conjugated polymeric semiconductors, and colloidal quantum dot assemblies in the fields of experimental synthesis, characterization, and device fabrication. Key modeling issues that we consider are calculations of optical properties and of effects of aggregation, including recent advances in methods beyond linear-response time-dependent density functional theory and recent insights into the effects of correlation when going beyond the single-particle ansatz as well as in the context of modeling of thermally activated fluorescence.

Published

2021

21. A Tröger's Base-Derived Covalent Organic Polymer Containing Carbazole Units as a High-Performance Supercapacitor.

Author

El-Mahdy AFM, Lüder J, Kotp MG, and Kuo SW

Abstract

Porous organic polymers have been received considerable attention due to their heteroatom-containing structures and high surface areas, which can offer high electrochemical performance in energy applications. The majority of reported Tröger's base-functionalized porous organic polymers have been applied as effective candidates for sensing and gas separation/adsorption, while their use as electrode materials in supercapacitors is rare. Here, a novel covalent microporous organic polymer containing carbazole and Tröger's base CzT-CMOP has been successfully synthesized through the one-pot polycondensation of 9-(4-aminophenyl)-carbazole-3,6-diamine (Cz-3NH 2 ) with dimethoxymethane. The polycondensation reaction's regioselectivity was studied using spectroscopic analyses and electronic structure calculations that confirmed the polycondensation occurred through the second and seventh positions of the carbazole unit rather than the fourth and fifth positions confirmed by first-principles calculations. Our CzT-CMOP exhibited high thermal stability of approximately 463.5 °C and a relatively high Brunauer-Emmett-Teller surface area of 615 m 2 g -1 with a nonlocal density functional theory's pore size and volume of 0.48 cm 3 g -1 and 1.66 nm, respectively. In addition, the synthesized CzT-CMOP displayed redox activity due to the existence of a redox-active carbazole in the polymer skeleton. CzT-CMOP revealed high electrochemical performance when used as active-electrode material in a three-electrode supercapacitor with an aqueous electrolyte of 6 M KOH, and it showed specific capacitance of 240 F g -1 at a current density of 0.5 A g -1 with excellent stability after 2000 cycles of 97% capacitance retention. Accordingly, such porous organic polymer appears to have a variety of uses in energy-related applications.

Published

2021

22. Nonparametric Local Pseudopotentials with Machine Learning: A Tin Pseudopotential Built Using Gaussian Process Regression.

Author

Lüder J and Manzhos S

Abstract

We present novel nonparametric representation math for local pseudopotentials (PP) based on Gaussian Process Regression (GPR). Local pseudopotentials are needed for materials simulations using Orbital-Free Density Functional Theory (OF-DFT) to reduce computational cost and to allow kinetic energy functional (KEF) application only to the valence density. Moreover, local PPs are important for the development of accurate KEFs for OF-DFT, but they are only available for a limited number of elements. We optimize local PPs of tin (Sn) represented with GPR to reproduce the experimental lattice constants of α- and β-Sn and the energy difference between these two phases as well as their electronic structure and charge density distributions which are obtained with Kohn-Sham Density Functional Theory employing semilocal PPs. The use of a nonparametric GPR-based PP representation avoids difficulties associated with the use of parametrized functions and has the potential to construct an optimal local PP independent of prior assumptions. The GPR-based Sn local PP results in well-reproduced bulk properties of α- and β-tin and electronic valence densities similar to those obtained with semilocal PP.

Published

2020

23. First-Principle Insights Into Molecular Design for High-Voltage Organic Electrode Materials for Mg Based Batteries.

Author

Lüder J and Manzhos S

Abstract

Low cost, scalability, potentially high energy density, and sustainability make organic magnesium (ion) battery (OMB) technologies a promising alternative to other rechargeable metal-ion battery solutions such as secondary lithium ion batteries (LIB). However, most reported OMB cathode materials have limited performance due to, in particular, low voltages often smaller than 2 V vs. Mg 2+ /Mg and/or low specific capacities compared to other competing battery technologies, e.g., LIB or sodium ion batteries. While the structural diversity of organic compounds and the large amount of possible chemical modifications potentially allow designing high voltage/capacity OMB electrode materials, the large search space requires efficient exploration of potential molecular-based electrode materials by rational design strategies on an atomistic scale. By means of density functional theory (DFT) calculations, we provide insights into possible strategies to increase the voltage by changes in electronic states via functionalization, by strain, and by coordination environment of Mg cations. A systematic analysis of these effects is performed on explanatory systems derived from selected prototypical building blocks: five- and six-membered rings with redox-active groups. We demonstrate that voltage increase by direct bandstructure modulation is limited, that strain on the molecular scale can in principle be used to modulate the voltage curve and that the coordination/chemical environment can play an important role to increase the voltage in OMB. We propose molecular structures that could provide voltages for Mg insertion in excess of 3 V., (Copyright © 2020 Lüder and Manzhos.)

Published

2020

24. Ligand Effects on the Linear Response Hubbard U: The Case of Transition Metal Phthalocyanines.

Author

Brumboiu IE, Haldar S, Lüder J, Eriksson O, Herper HC, Brena B, and Sanyal B

Abstract

It is established that density functional theory (DFT) + U is a better choice compared to DFT for describing the correlated electron metal center in organometallics. The value of the Hubbard U parameter may be determined from linear response, either by considering the response of the metal site alone or by additionally considering the response of other sites in the compound. We analyze here in detail the influence of ligand shells of increasing size on the U parameter calculated from the linear response for five transition metal phthalocyanines. We show that the calculated multiple-site U is larger than the single-site U by as much as 1 eV and the ligand atoms that are mainly responsible for this difference are the isoindole nitrogen atoms directly bonded to the central metal atom. This suggests that a different U value may be required for computations of chemisorbed molecules compared to physisorbed and gas-phase cases.

Published

2019

25. Polyaniline and CN-functionalized polyaniline as organic cathodes for lithium and sodium ion batteries: a combined molecular dynamics and density functional tight binding study in solid state.

Author

Chen Y, Lüder J, Ng MF, Sullivan M, and Manzhos S

Abstract

We present the first atomistic-scale simulation of the discharge process of polymeric cathode materials for electrochemical batteries in solid state. The oxidation of polyaniline (PANI) and of cyano groups (CN) functionalized PANI induced by coordination to the electrolyte anions is computed and voltage curves are estimated. To deal with the large required numbers of atoms and structures, a combination of molecular dynamics and density functional tight binding (DFTB) is used. The DFTB is benchmarked to density functional theory (DFT) calculations using different functionals to confirm its accuracy. The voltages computed with the solid state model are in good agreement with available experimental data and ab initio models based on oligomers. The solid state model also predicts substantially increased voltage with PANI functionalized with cyano groups.

Published

2017

26. Understanding doping strategies in the design of organic electrode materials for Li and Na ion batteries: an electronic structure perspective.

Author

Lüder J, Cheow MH, and Manzhos S

Abstract

In this paper, we present a systematic study of the effects of p- and n-doping in small molecules on the voltage and capacity of organic electrode materials for electrochemical batteries. In particular, coronene, phenalene derivatives as well as disodium terephthalate and related fused ring derivatives, representing often used building blocks in organic electrode materials, are chosen as model systems. We show that p-doping can drastically increase the binding strength to Li or Na and is therefore an effective strategy to design organic electrode materials for both lithium and sodium ion batteries. It could also be used to increase the theoretical capacity. On the other hand, n-doping generally has a much smaller effect on the voltage. The effects of n- and p-doping are rationalized based on the analysis of changes they induce in the band structure as well as in the molecular structure.

Published

2017

27. Influence of Electron Correlation on the Electronic Structure and Magnetism of Transition-Metal Phthalocyanines.

Author

Brumboiu IE, Haldar S, Lüder J, Eriksson O, Herper HC, Brena B, and Sanyal B

Abstract

There exists an extensive literature on the electronic structure of transition-metal phthalocyanines (TMPcs), either as single molecules or adsorbed on surfaces, where explicit intra-atomic Coulomb interactions of the strongly correlated orbitals are included in the form of a Hubbard U term. The choice of U is, to a large extent, based solely on previous values reported in the literature for similar systems. Here, we provide a systematic analysis of the influence of electron correlation on the electronic structure and magnetism of several TMPcs (MnPc, FePc, CoPc, NiPc, and CuPc). By comparing calculated results to valence-band photoelectron spectroscopy measurements, and by determining the Hubbard term from linear response, we show that the choice of U is not as straightforward and can be different for each different TMPc. This, in turn, highlights the importance of individually estimating the value of U for each system before performing any further analysis and shows how this value can influence the final results.

Published

2016

28. Many-body effects and excitonic features in 2D biphenylene carbon.

Author

Lüder J, Puglia C, Ottosson H, Eriksson O, Sanyal B, and Brena B

Abstract

The remarkable excitonic effects in low dimensional materials in connection to large binding energies of excitons are of great importance for research and technological applications such as in solar energy and quantum information processing as well as for fundamental investigations. In this study, the unique electronic and excitonic properties of the two dimensional carbon network biphenylene carbon were investigated with GW approach and the Bethe-Salpeter equation accounting for electron correlation effects and electron-hole interactions, respectively. Biphenylene carbon exhibits characteristic features including bright and dark excitons populating the optical gap of 0.52 eV and exciton binding energies of 530 meV as well as a technologically relevant intrinsic band gap of 1.05 eV. Biphenylene carbon's excitonic features, possibly tuned, suggest possible applications in the field of solar energy and quantum information technology in the future.

Published

2016

29. The electronic characterization of biphenylene--experimental and theoretical insights from core and valence level spectroscopy.

Author

Lüder J, de Simone M, Totani R, Coreno M, Grazioli C, Sanyal B, Eriksson O, Brena B, and Puglia C

Subjects

Carbon chemistry, Computer Simulation, Models, Chemical, Molecular Structure, Naphthalenes chemistry, Photoelectron Spectroscopy, X-Ray Absorption Spectroscopy, Biphenyl Compounds chemistry, Gases chemistry

Abstract

In this paper, we provide detailed insights into the electronic structure of the gas phase biphenylene molecule through core and valence spectroscopy. By comparing results of X-ray Photoelectron Spectroscopy (XPS) measurements with ΔSCF core-hole calculations in the framework of Density Functional Theory (DFT), we could decompose the characteristic contributions to the total spectra and assign them to non-equivalent carbon atoms. As a difference with similar molecules like biphenyl and naphthalene, an influence of the localized orbitals on the relative XPS shifts was found. The valence spectrum probed by photoelectron spectroscopy at a photon energy of 50 eV in conjunction with hybrid DFT calculations revealed the effects of the localization on the electronic states. Using the transition potential approach to simulate the X-ray absorption spectroscopy measurements, similar contributions from the non-equivalent carbon atoms were determined from the total spectrum, for which the slightly shifted individual components can explain the observed asymmetric features.

Published

2015

30. Revisiting the adsorption of copper-phthalocyanine on Au(111) including van der Waals corrections.

Author

Lüder J, Eriksson O, Sanyal B, and Brena B

Abstract

We have studied the adsorption of copper-phthalocyanine on Au(111) by means of van der Waals corrected density functional theory using the Tkatchenko-Scheffler method. We have compared the element and site resolved adsorption distances to recent experimental normal-incident X-ray standing wave measurements. The measured adsorption distances could be reproduced within a deviation of 1% for the Cu atom, 1% for the C atoms, and 2% for the N atoms. The molecule was found to have a magnetic moment of 1 μB distributed over the Cu and the N atoms of the pyrrole ring. Simulated scanning tunnel microscopy images based on the total and on the spin-resolved differential charge densities are provided for bias voltages of -1.45 and 1.45 eV.

Published

2014

31. Laser-induced plasma cloud interaction and ice multiplication under cirrus cloud conditions.

Author

Leisner T, Duft D, Möhler O, Saathoff H, Schnaiter M, Henin S, Stelmaszczyk K, Petrarca M, Delagrange R, Hao Z, Lüder J, Petit Y, Rohwetter P, Kasparian J, Wolf JP, and Wöste L

Subjects

Aerosols chemistry, Atmosphere Exposure Chambers, Humidity, Lasers, Models, Theoretical, Nonlinear Dynamics, Optics and Photonics instrumentation, Remote Sensing Technology methods, Temperature, Atmosphere chemistry, Climate, Ice analysis, Lightning, Steam analysis

Abstract

Potential impacts of lightning-induced plasma on cloud ice formation and precipitation have been a subject of debate for decades. Here, we report on the interaction of laser-generated plasma channels with water and ice clouds observed in a large cloud simulation chamber. Under the conditions of a typical storm cloud, in which ice and supercooled water coexist, no direct influence of the plasma channels on ice formation or precipitation processes could be detected. Under conditions typical for thin cirrus ice clouds, however, the plasma channels induced a surprisingly strong effect of ice multiplication. Within a few minutes, the laser action led to a strong enhancement of the total ice particle number density in the chamber by up to a factor of 100, even though only a 10(-9) fraction of the chamber volume was exposed to the plasma channels. The newly formed ice particles quickly reduced the water vapor pressure to ice saturation, thereby increasing the cloud optical thickness by up to three orders of magnitude. A model relying on the complete vaporization of ice particles in the laser filament and the condensation of the resulting water vapor on plasma ions reproduces our experimental findings. This surprising effect might open new perspectives for remote sensing of water vapor and ice in the upper troposphere.

Published

2013

32. [Acute gastrointestinal bleeding caused by distinct small intestinal diverticulosis].

Author

Friebe M, Allerödder HP, Lüder J, and Kindler U

Subjects

Diverticulum diagnosis, Diverticulum therapy, Duodenal Diseases diagnosis, Duodenal Diseases therapy, Humans, Jejunal Diseases diagnosis, Jejunal Diseases therapy, Male, Middle Aged, Recurrence, Diverticulum complications, Duodenal Diseases complications, Gastrointestinal Hemorrhage etiology, Jejunal Diseases complications

Abstract

History and Clinical Findings: A 58-year-old man was admitted to our hospital after an acute onset of rectal bleeding. He was known to have had recurrent duodenal ulcerative disease, once with upper gastrointestinal haemorrhage. Clinical examination was remarkable only for rectal bleeding., Investigations: After application of a nasogastric tube cherry-red blood was evacuated. Upper endoscopy showed only very small mucosal erosion in the stomach and coloscopy demonstrated several non-bleeding diverticula. Small bowel enteroclysis showed severe diverticulosis of the duodenum and jejunum., Diagnosis, Treatment and Course: We assumed that the extensive duodenojejunal diverticulosis was the most probable cause of this episode of gastrointestinal bleeding because of simultaneous signs of upper and lower gastrointestinal haemorrhage. Because this was the first such episode we preferred a conservative approach. At nineteen months follow-up there was no recurrence of bleeding., Conclusion: Gastrointestinal hemorrhage is a common cause of hospitalization. After exclusion of the more common bleeding sources small bowel diverticula should be considered as a possible rare cause. Surgical resection of the bleeding bowel part is the procedure of choice, but one of the major problems in such cases is to locate exactly the bleeding site. If the location is uncertain, a more conservative approach may be preferable, especially in haemodynamically stable patients with first-time diverticular bleeding.

Published

2001