Your search keyword '"NIEDERBERGER, M."' showing total 425 results

151. In situ investigations of structure–activity relationships of a Cu/ZrO2 catalyst for the steam reforming of methanol

Author

Szizybalski, A., Girgsdies, F., Rabis, A., Wang, Y., Niederberger, M., and Ressler, T.

Subjects

*ABSORPTION, *COPPER, *HYDROGEN, *METHANOL

Abstract

Abstract: Structure–activity relationships of a nanostructured Cu/ZrO2 catalyst for the steam reforming of methanol (MSR) were investigated under reaction conditions by in situ X-ray absorption spectroscopy (XAS) and X-ray diffraction (XRD) combined with on-line mass spectrometry (MS). Temperature-programmed activation by reduction in hydrogen or by reduction in a mixture of methanol and water (feed) was studied by time-resolved Cu K edge XANES and TG/DSC/MS measurements. Small and disordered CuO particles were identified as the main copper phase present in the precursors. After extended time on stream and treatment at 673 K in hydrogen, no significant sintering of the copper particles or deactivation of the reduced Cu/ZrO2 catalysts was detected, indicating a superior stability of the material. The initially low steam-reforming activity of the Cu/ZrO2 catalyst after reduction in hydrogen could be significantly increased by a temporary addition of oxygen to the feed. This increased activity after oxidative treatment is correlated with an increasing amount of oxygen in the copper particles. 63Cu NMR studies detected only a minor degree of microstrain in the active copper phase of the Cu/ZrO2 catalyst. The decreased reducibility of CuO/ZrO2, the low degree of microstrain, and the correlation between the amount of oxygen remaining in the copper particles and the catalytic activity indicate a different metal support interaction compared with Cu/ZnO catalysts. [Copyright &y& Elsevier]

Published

2005

152. Steam reforming of methanol over Cu/ZrO2/CeO2 catalysts: a kinetic study

Author

Mastalir, A., Frank, B., Szizybalski, A., Soerijanto, H., Deshpande, A., Niederberger, M., Schomäcker, R., Schlögl, R., and Ressler, T.

Subjects

*METHANOL, *CATALYSTS, *POLYMERS, *OPTICAL diffraction, *ALCOHOLS (Chemical class)

Abstract

Abstract: Steam reforming of methanol (SRM) was investigated over Cu/ZrO2/CeO2 (CZC) catalysts prepared via a novel synthetic method based on coprecipitation and polymer templating. Structural characterization of the samples was performed by N2 adsorption–desorption, N2O decomposition, and X-ray diffraction. The variation of the Cu loading resulted in an increased Cu crystallite size and a decreased specific surface area of the active particles. Catalytic investigations were carried out in a fixed-bed reactor at 105 Pa, with a CH3OH:H2O ratio of 1:1. The samples with Cu contents higher than 5% exhibited good long-term stabilities and low CO levels during continuous operation. The kinetic model suggested for the transformation involved the reverse water–gas shift (RWGS) and methanol decomposition (MD), in addition to the SRM reaction. Kinetic measurements were made in the temperature range of 503–573 K, and the experimental results could be well simulated. The highest methanol conversions and the lowest CO levels were observed in the temperature range of 523–543 K. The apparent activation energies for the individual reactions were found to depend on the Cu content of the catalyst. Since the influence of mass transport limitations on the kinetic data could be excluded, it was established that the variation of the Cu concentration in the precursor material altered the microstructure of the Cu particles and, accordingly, the active Cu surface, which resulted in the formation of significantly different catalysts. [Copyright &y& Elsevier]

Published

2005

153. The Bright X‐Ray Stimulated Luminescence of HfO 2 Nanocrystals Activated by Ti Ions

Author

Bodo Hattendorf, Christophe Dujardin, Mauro Fasoli, F. Moretti, I Villa, Antonella Rossi, Alessandro Lauria, Markus Niederberger, Anna Vedda, Dipartimento di Scienza dei Materiali = Department of Materials Science [Milano-Bicocca], Università degli Studi di Milano-Bicocca [Milano] (UNIMIB), Institut Lumière Matière [Villeurbanne] (ILM), Université Claude Bernard Lyon 1 (UCBL), Université de Lyon-Université de Lyon-Centre National de la Recherche Scientifique (CNRS), Universita degli Studi di Cagliari [Cagliari], Department of Materials [ETH Zürich] (D-MATL), Eidgenössische Technische Hochschule - Swiss Federal Institute of Technology [Zürich] (ETH Zürich), Laboratory of Inorganic Chemistry [ETH Zürich] (LAC), Department of Chemistry and Applied Biosciences [ETH Zürich] (D-CHAB), Eidgenössische Technische Hochschule - Swiss Federal Institute of Technology [Zürich] (ETH Zürich)- Eidgenössische Technische Hochschule - Swiss Federal Institute of Technology [Zürich] (ETH Zürich), Centre National de la Recherche Scientifique (CNRS)-Université Claude Bernard Lyon 1 (UCBL), Université de Lyon-Université de Lyon, Villa, I, Moretti, F, Fasoli, M, Rossi, A, Hattendorf, B, Dujardin, C, Niederberger, M, Vedda, A, and Lauria, A

Subjects

Materials science, Radioluminescence efficiency, chemistry.chemical_element, 02 engineering and technology, 010402 general chemistry, Photochemistry, 01 natural sciences, Ion, [SPI]Engineering Sciences [physics], [CHIM]Chemical Sciences, Scintillation, Decay time, Titanium, [PHYS]Physics [physics], X-ray, 021001 nanoscience & nanotechnology, Atomic and Molecular Physics, and Optics, Hafnium oxide nanoparticles, 0104 chemical sciences, Electronic, Optical and Magnetic Materials, FIS/01 - FISICA SPERIMENTALE, Nanocrystal, chemistry, 0210 nano-technology, Luminescence, hafnium oxide nanoparticle

Abstract

International audience; The recent trends in scintillator technologies stimulate research efforts toward the development of novel materials morphologies, such as nanoparticles, able to efficiently convert ionizing radiations into light. For example, scintillating nanoparticles attract great interest in medical oncological therapies. In this work, the structural and morphological properties of HfO2:Ti nanoparticles with Ti concentrations from 0.03 to 10 mol% and subjected to calcination up to 1000 °C are thoroughly characterized; moreover, X‐ray photoelectron spectroscopy reveals the incorporation of Ti in both Ti (III) and Ti (IV) chemical states in as prepared samples, while the exclusive presence of Ti(IV) is unambiguously identified in calcined nanoparticles. The optical emission under X‐ray excitation evidences an intense Ti (IV)‐related luminescence at 2.5 eV in high temperature calcined samples with a few microseconds scintillation lifetime, and efficiency comparable to that of Bi4Ge3O12 reference scintillator. Finally, the competitive role of defects in charge carriers capture is demonstrated by the monotonic increase of the 2.5 eV band during prolonged X‐ray irradiation, more evident for nanoparticles with titanium concentration below 1 mol%. HfO2:Ti may also find application in X‐ray triggered oncological therapies by using the Ti (IV)‐related bright radioluminescence to excite photosensitizer molecules for singlet oxygen generation.

Published

2019

154. Size-Dependent Luminescence in HfO2 Nanocrystals: Toward White Emission from Intrinsic Surface Defects

Author

Anna Vedda, Florian J. Heiligtag, I Villa, Roberto Lorenzi, Felix Rechberger, Mauro Fasoli, Niklaus Kränzlin, Bodo Hattendorf, Gabriele Ilari, Darinka Primc, Alessandro Lauria, Markus Niederberger, Villa, I, Vedda, A, Fasoli, M, Lorenzi, R, Kränzlin, N, Rechberger, F, Ilari, G, Primc, D, Hattendorf, B, Heiligtag, F, Niederberger, M, and Lauria, A

Subjects

Diffraction, Photoluminescence, Materials science, General Chemical Engineering, Crystal growth, 02 engineering and technology, General Chemistry, Atmospheric temperature range, 010402 general chemistry, 021001 nanoscience & nanotechnology, 01 natural sciences, 0104 chemical sciences, nanocrystal, Crystallography, Nanocrystal, Transmission electron microscopy, Chemical physics, luminescence, Materials Chemistry, Hafnia, 0210 nano-technology, Luminescence, Monoclinic crystal system

Abstract

Defect engineering operated on metal oxides by chemical and structural modifications may strongly affect properties suitable for various applications such as photoelectrochemical behavior, charge transport, and luminescence. In this work, we report the tunable optical features observed in undoped monoclinic HfO2 nanocrystals and their dependence on the structural properties of the material at the nanoscale. Transmission electron microscopy together with X-ray diffraction and surface area measurements were used to determine the fine structural modifications, in terms of crystal growth and coalescence of crystalline domains, occurring during a calcination process in the temperature range from 400 to 1000 °C. The fit of the broad optical emission into spectral components, together with time-resolved photoluminescence, allowed us to identify the dual nature of the emission at 2.5 eV, where an ultrafast defect-related intrinsic luminescence (with a decay time of a few nanoseconds) overlaps with a slower emission (decay of several microseconds) due to extrinsic Ti-impurity centers. Moreover, the evolution of intrinsic visible bands during the material transformation was monitored. The relationship between structural parameters uniquely occurring in nanosized materials and the optical properties was investigated and tentatively modeled. The blue emissions at 2.5 and 2.9 eV are clearly related to defects lying at crystal boundaries, while an unprecedented emission at 2.1 eV enables, at relatively low calcination temperatures, the white luminescence of HfO2 under near-UV excitation.

Published

2016

155. Radio-luminescence spectral features and fast emission in hafnium dioxide nanocrystals

Author

Christophe Dujardin, Markus Niederberger, Anna Vedda, I Villa, Alessandro Lauria, F. Moretti, Mauro Fasoli, Villa, I, Lauria, A, Moretti, F, Fasoli, M, Dujardin, C, Niederberger, M, Vedda, A, Dipartimento di Scienza dei Materiali = Department of Materials Science [Milano-Bicocca], Università degli Studi di Milano-Bicocca [Milano] (UNIMIB), Department of Materials [ETH Zürich] (D-MATL), Eidgenössische Technische Hochschule - Swiss Federal Institute of Technology [Zürich] (ETH Zürich), Institut Lumière Matière [Villeurbanne] (ILM), Centre National de la Recherche Scientifique (CNRS)-Université Claude Bernard Lyon 1 (UCBL), Université de Lyon-Université de Lyon, Université Claude Bernard Lyon 1 (UCBL), and Université de Lyon-Université de Lyon-Centre National de la Recherche Scientifique (CNRS)

Subjects

Materials science, General Physics and Astronomy, 02 engineering and technology, 010402 general chemistry, 01 natural sciences, Molecular physics, Crystal, chemistry.chemical_compound, [SPI]Engineering Sciences [physics], radioluminescence, decay time, Impurity, [CHIM]Chemical Sciences, Irradiation, Physical and Theoretical Chemistry, Hafnium dioxide, [PHYS]Physics [physics], Scintillation, Nanosecond, 021001 nanoscience & nanotechnology, 0104 chemical sciences, scintillator, FIS/01 - FISICA SPERIMENTALE, chemistry, hafnia, 0210 nano-technology, Luminescence, Excitation

Abstract

International audience; In this work, we investigate the optical properties of hafnium dioxide nanocrystals, upon X-ray irradiation, looking for spectral evolution following thermal treatments in air up to 1000 °C that modify the crystal size as well as their point defect concentrations. Radio-luminescence measurements from 10 K up to room temperature reveal a rich and evolving picture of the optical features. A complete spectral analysis of the broad luminescence spectra reveals the presence of several emission components in the visible and UV regions. The lower energy components peaking at 2.1, 2.5, and 2.9 eV are characterized by a thermal quenching energy of 0.08 eV, while the corresponding value for the UV bands at 4.1 and 4.7 eV is close to 0.23 eV. We tentatively assign the components ranging from 2 to 3 eV to the presence of optically active defects of an intrinsic nature, together with the occurrence of titanium impurities; conversely, the bands at higher energies are likely to be of an excitonic nature. The comparison with previous photo-luminescence studies allows evidencing characteristic differences between the features of luminescence emissions caused by intra-centre excitation and those occurring under ionizing irradiation. Finally, scintillation measurements in the visible range reveal the existence of a fast decay in the nanosecond time scale for the smallest hafnia nanocrystals. This study offers a clear description of HfO2 luminescence characteristics upon excitation by X-rays and can lead to a better comprehension of the structure–property relationship at the nanoscale in metal oxides.

Published

2018

156. Multifunctional Role of Rare Earth Doping in Optical Materials: Nonaqueous Sol–Gel Synthesis of Stabilized Cubic HfO2 Luminescent Nanoparticles

Author

Anna Vedda, Markus Niederberger, Alessandro Lauria, I Villa, Mauro Fasoli, Lauria, A, Villa, I, Fasoli, M, Niederberger, M, and Vedda, A

Subjects

Photoluminescence, Materials science, Dopant, Doping, Inorganic chemistry, General Engineering, General Physics and Astronomy, chemistry.chemical_element, Crystal structure, Crystal, symbols.namesake, chemistry, symbols, Physical chemistry, General Materials Science, hafnia, cubic lattice, lutetium,europium, luminescence, nonaqueous sol gel, nanoparticle, rare earth, Luminescence, Europium, Raman spectroscopy

Abstract

In this work a strategy for the control of structure and optical properties of inorganic luminescent oxide-based nanoparticles is presented. The nonaqueous sol-gel route is found to be suitable for the synthesis of hafnia nanoparticles and their doping with rare earths (RE) ions, which gives rise to their luminescence either under UV and X-ray irradiation. Moreover, we have revealed the capability of the technique to achieve the low-temperature stabilization of the cubic phase through the effective incorporation of trivalent RE ions into the crystal lattice. Particular attention has been paid to doping with europium, causing a red luminescence, and with lutetium. Structure and morphology characterization by XRD, TEM/SEM, elemental analysis, and Raman/IR vibrational spectroscopies have confirmed the occurrence of the HfO2 cubic polymorph for dopant concentrations exceeding a threshold value of nominal 5 mol %, for either Lu3+ or Eu3+. The optical properties of the nanopowders were investigated by room temperature radio- and photoluminescence experiments. Specific features of Eu3+ luminescence sensitive to the local crystal field were employed for probing the lattice modifications at the atomic scale. Moreover, we detected an intrinsic blue emission, allowing for a luminescence color switch depending on excitation wavelength in the UV region. We also demonstrate the possibility of changing the emission spectrum by multiple RE doping in minor concentration, while deputing the cubic phase stabilization to a larger concentration of optically inactive Lu3+ ions. The peculiar properties arising from the solvothermal nonaqueous synthesis here used are described through the comparison with thermally treated powders. © 2013 American Chemical Society.

Published

2013

157. Polymer Derived Ceramics Process in Biomedical Applications: Pacemaker Electrode

Author

Dalcanale, Federico, Niederberger M., Graule, Thomas, Studart, André R., and Sorarù, Gian

Subjects

Polymer derived ceramics, Carbon nanotube (CNT), Electrical conductivity, Hydrosilylation, Chemical engineering, Technology (applied sciences), ddc:660, ddc:600, FOS: Chemical engineering

Abstract

Current biomedical material research involves the use of a large variety of materials depending on the specific functions and characteristics required. The high mechanical performances and the relatively easy forming techniques allowed metals to be the most widely used material for implantations. Nevertheless, the development of new high performances ceramics is an established trend in this field because their superior biocompatibility (e.g. alumina and zirconia) and corrosion resistance. Despite these improvements the replacement of metal with ceramics is limited, due to the complex shapes or the specific properties required, e.g. electrical conductivity. An alternative is represented from polymer-derived-ceramics (PDCs) technology. Starting from a liquid organosilicon polymer, ceramics with free shapes can be produced using polymer and micro-electrical-mechanical-systems (MEMS) fabrication techniques such as micromoulding and photolithography. Depending from the selected application, material properties can be tuned using different starting polymer precursors, varying the process parameters or adding suitable fillers. This dissertation is part of the Swiss National Science Foundation (SNSF) research project CERAMED developed at Empa High Performance Ceramics Laboratory in collaboration with EPFL Microsystems Laboratory and Bern Inselspital Clinic for Cardiovascular Surgery. The project aims to combine recent findings in the field of conductive ceramic materials with advanced micromoulding methods to study novel 3D implantable electrodes for low-power, long-term pacemaker applications. The scientific work presented here involves the development of a suitable material that possess all the main requirement, from process to physical and biocompatibility properties, to replace metals in pacemaker electrodes. In the first chapter an overview is given of the pacing device, its different components and biocompatibility of metal electrodes compared to state-of-the-art ceramic ones. Current advancement in commercial pacemakers and an outlook on research challenges are also presented. Fundamentals of PDCs technology such as precursors, fillers and processing are introduced in chapter one. Specific topics regarding electric conductivity, filler suspensions and carbon nanotube (CNTs) composites are presented in more details at the beginning of each following chapter. The second chapter contains a detailed description of the technical approach to obtain a crack-free and electrically conductive ceramic from commercial polycarbosilane SMP10. The proposed fabrication method is based on the addition of divinylbenzene as liquid carbon precursor. When an optimum divinylbenzene amount is added, hydrosilylation is promoted and ceramic crack-free disc samples up to 10 mm in diameter can be produced. The advantages of the developed method are the use of a liquid-fabrication route, where the precursor can replicate any mould shape without limitations, and a pressureless curing step. The process is also demonstrated suitable also for production of microsized samples. A further advantage in the addition of divinylbenzene to polycarbosilane SMP10 is the development of a carbon percolative network after pyrolysis that raise the electrical conductivity up to 1 S/cm. Due to these favorable characteristics the material is used as a matrix for the development of novel ceramic composites described in the following chapters. Chapter three presents a novel and efficient method for CNTs dispersion. The polycarbosilane SMP10 and the polysilazane Ceraset are shown to be able to cover the nanotube wall if hydrosilylation is induced with a Pt(0) catalyst. The result is the stable suspension of CNTs in several organic solvents. Process parameters such as catalyst amount and sonication time are investigated and optimized. This work shows that the developed method is comparable with traditional ones based on surfactants and it also has several advantages: it is simple, can be completed in few minutes, and an up to 0.50 mg/ml of CNTs are suspended, which is a sufficient concentration for many applications.Chapters four analyze the preparation of a CNTs-ceramic composite. Despite the filler presence, the process maintains all the peculiarity of the original matrix with a pressureless fabrication method suitable for the production of micro and macro samples. However the effects of nanotubes introduction do not significantly improves the electrical properties of the ceramic due to the already high carbon content of the matrix. In addition the more complex process leads to a higher cracking probability during pyrolysis. All the results are critically discussed and compared with existing methods in PDC technology. Chapter five analyzes the cytotoxicity of the ceramic developed in chapter two. The test, conducted in comparison with standard biocompatible materials such as alumina and biograde-stainless-steel, demonstrates the non-cytotoxicity of the developed material and its potential use in medical applications.

Published

2017

158. Non-aqueous sol-gel synthesis of hybrid rare-earth-doped γ-Ga2O3 nanoparticles with multiple organic-inorganic-ionic light-emission features

Author

Markus Niederberger, Nikita V. Golubev, Alberto Paleari, Roberto Lorenzi, Alessandro Lauria, Vladimir N. Sigaev, E. S. Ignat’eva, Lorenzi, R, Paleari, A, Golubev, N, Ignat'Eva, E, Sigaev, V, Niederberger, M, and Lauria, A

Subjects

CHIM/03 - CHIMICA GENERALE E INORGANICA, Photoluminescence, Materials science, Aqueous solution, Stereochemistry, Nanoparticle, Ionic bonding, General Chemistry, Photochemistry, chemistry.chemical_compound, FIS/01 - FISICA SPERIMENTALE, chemistry, Benzyl alcohol, Materials Chemistry, gallium oxide, nanoparticles, time resolved photoluminescence, non acqueous solgel synthesis, Europium, Light emission, Spectroscopy, FIS/03 - FISICA DELLA MATERIA, Sol-gel

Abstract

We present a novel strategy for the synthesis of pure and Eu-doped γ-Ga2O3 nanoparticles with an in situ organic capping resulting from a non-aqueous solution-based benzyl alcohol synthesis route. Photoluminescence spectroscopy highlights the concomitant benzoate-related and γ-Ga2O3 exciton-like Eu3+ excitations in the UV, and a blue emission superimposed onto γ-Ga2O3 donor–acceptor recombination, ascribable to organic moieties different from benzoate.

Published

2015

159. A novel non-aqueous sol-gel route for the in situ synthesis of high loaded silica-rubber nanocomposites

Author

Markus Niederberger, Raffaella Donetti, Luciano Tadiello, Laura Wahba, Nadia Santo, Massimiliano D’Arienzo, T Hanel, Sandra Dirè, Franca Morazzoni, Roberto Scotti, Wahba, L, D'Arienzo, M, Dirè, S, Donetti, R, Hanel, T, Morazzoni, F, Niederberger, M, Santo, N, Tadiello, L, and Scotti, R

Subjects

CHIM/03 - CHIMICA GENERALE E INORGANICA, chemistry.chemical_classification, Aqueous solution, Nanocomposite, Materials science, nanocomposite, Formic acid, filler, rubber, General Chemistry, Polymer, Condensed Matter Physics, chemistry.chemical_compound, chemistry, Natural rubber, Chemical engineering, silica, visual_art, visual_art.visual_art_medium, Particle, dynamical mechanical properties, Dispersion (chemistry), sol gel, Sol-gel

Abstract

Silica–natural rubber nanocomposites were obtained through a novel non-aqueous in situ sol–gel synthesis, producing the amount of water necessary to induce the hydrolysis and condensation of a tetraethoxysilane precursor by esterification of formic acid with ethanol. The method allows the synthesis of low hydrophilic silica nanoparticles with ethoxy groups linked to the silica surface which enable the filler to be more dispersible in the hydrophobic rubber. Thus, high loaded silica composites (75 phr, parts per hundred rubber) were obtained without using any coupling agent. Transmission Electron Microscopy (TEM) showed that the silica nanoparticles are surrounded by rubber layers, which lower the direct interparticle contact in the filler–filler interaction. At the lowest silica loading (up to 30 phr) silica particles are isolated in rubber and only at a large amount of filler (>60 phr) the interparticle distances decrease and a continuous percolative network, connected by thin polymer films, forms throughout the matrix. The dynamic-mechanical properties confirm that the strong reinforcement of the rubber composites is related to the network formation at high loading. Both the improvement of the particle dispersion and the enhancement of the silica loading are peculiar to the non-aqueous synthesis approach, making the method potentially interesting for the production of high-loaded silica–polymer nanocomposites.

Published

2014

160. Double role of polyethylene glycol in the microwaves-assisted non-hydrolytic synthesis of nanometric TiO2: Oxygen source and stabilizing agent

Author

Idalia Bilecka, Davide Morselli, Federica Bondioli, Markus Niederberger, Morselli D., Niederberger M., Bilecka I., and Bondioli F.

Subjects

Reaction mechanism, Anatase, Materials science, Dispersibility, Inorganic chemistry, chemistry.chemical_element, Bioengineering, Polyethylene glycol, chemistry.chemical_compound, Dynamic light scattering, PEG ratio, General Materials Science, Microwaves, Functionalization, Non-aqueous sol-gel, Non-aqueous sol–gel, General Chemistry, Condensed Matter Physics, PEG, Atomic and Molecular Physics, and Optics, chemistry, Chemical engineering, Modeling and Simulation, Titanium dioxide, Surface modification, Mechanism, Microwave, Titanium

Abstract

The microwaves-assisted reaction between titanium(IV) tetrachloride and polyethylene glycol (PEG) represents a novel non-aqueous sol-gel route for synthesizing surface-stabilized titanium dioxide nanoparticles. X-ray powder diffraction measurements showed the exclusive presence of anatase phase. Transmission electron microscopy investigations revealed that the particles are nearly uniform in shape with sizes ranging from 4 to 8 nm and a low degree of agglomeration. The presence of covalently bonded PEG chains on the particles surface has been shown by Fourier transform infrared (FT-IR) spectroscopy. This surface functionalization greatly enhances the dispersibility of the particles in water, as observed by dynamic light scattering and zeta-potential analyses. Furthermore, the investigation of the reaction by-products by a combination of FT-IR and high-performance liquid chromatography (HPLC-Mass) techniques allowed a deeper insight into the reaction mechanism suggesting a double role of PEG as a stabilizing agent and an oxygen source. Graphical Abstract: [Figure not available: see fulltext.]

Published

2014

161. Delphi studies in social and health sciences-Recommendations for an interdisciplinary standardized reporting (DELPHISTAR). Results of a Delphi study.

Author

Niederberger M, Schifano J, Deckert S, Hirt J, Homberg A, Köberich S, Kuhn R, Rommel A, and Sonnberger M

Subjects

Humans, Social Sciences, Guidelines as Topic, Consensus, Surveys and Questionnaires, Research Design standards, Female, Delphi Technique

Abstract

Background: While different proposals exist for a guideline on reporting Delphi studies, none of them has yet established itself in the health and social sciences and across the range of Delphi variants. This seems critical because empirical studies demonstrate a diversity of modifications in the conduction of Delphi studies and sometimes even errors in the reporting. The aim of the present study is to close this gap and formulate a general reporting guideline., Method: In an international Delphi procedure, Delphi experts were surveyed online in three rounds to find consensus on a reporting guideline for Delphi studies in the health and social sciences. The respondents were selected via publications of Delphi studies. The preliminary reporting guideline, containing 65 items on five topics and presented for evaluation, had been developed based on a systematic review of the practice of Delphi studies and a systematic review of existing reporting guidelines for Delphi studies. Starting in the second Delphi round, the experts received feedback in the form of mean values, measures of dispersion, a summary of the open-ended responses and their own response in the previous round. The final draft of the reporting guideline contains the items on which at least 75% of the respondents agreed by assigning scale points 6 and 7 on a 7-point Likert scale., Results: 1,072 experts were invited to participate. A total of 91 experts completed the first Delphi round, 69 experts the second round, and 56 experts the third round. Of the 65 items in the first draft of the reporting guideline, consensus was ultimately reached for 38 items addressing the five topics: Title and Abstract (n = 3), Context (n = 7), Method (n = 20), Results (n = 4) and Discussion (n = 4). Items focusing on theoretical research and on dissemination were either rejected or remained subjects of dissent., Discussion: We assume a high level of acceptance and interdisciplinary suitability regarding the reporting guideline presented here and referred to as the "Delphi studies in social and health sciences-recommendations for an interdisciplinary standardized reporting" (DELPHISTAR). Use of this reporting guideline can substantially improve the ability to compare and evaluate Delphi studies., Competing Interests: The authors have declared that no competing interests exist., (Copyright: © 2024 Niederberger et al. This is an open access article distributed under the terms of the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original author and source are credited.)

Published

2024

162. Development of a Global Physical Literacy (GloPL) Action Framework: Study protocol for a consensus process.

Author

Carl J, Mazzoli E, Mouton A, Sum RK, Singh A, Niederberger M, Martins J, Kriellaars D, Green N, Elsborg P, Dudley DA, Cairney J, Barratt J, and Barnett LM

Subjects

Humans, Health Literacy, Delphi Technique, Global Health, Physical Education and Training methods, Exercise physiology, Consensus

Abstract

Background: The holistic concept of physical literacy (PL) has gained growing attention in recent research, policy, and practice. Many important policy documents of the physical activity and educational fields (e.g., Global Action Plan on Physical Activity 2018-2030 by the World Health Organization, UNESCO's Quality Physical Education guidelines for policymakers) have specified PL. However, a clear framework for action is needed, as most initiatives across the world are fragmented, lack a prospective orientation, can benefit from conceptual clarification, and are not linked to effective translation into practice. Therefore, we aim to consensually develop a Global Physical Literacy (GloPL) Action Framework to define goals and principles (asking what is needed) as well as actions and ways (asking how these can be achieved) to move PL forward., Materials and Methods: We apply a three-stage group Delphi technique involving three representation groups: (a) geographical representatives to achieve global coverage of perspectives; (b) representatives of special thematic interest reflecting prominent gaps of current PL activities; and (c) representatives of societies from the broad field of physical activity and health to facilitate dissemination. The process will begin with an individual pre-Delphi exercise, in which experts generate initial ideas for the framework, followed by a four-eye document analysis to derive themes for the discussion. Subsequently, the experts will meet face-to-face in three online rounds to discuss and prioritize the themes. Interspersed formal voting with pre-defined agreement thresholds (via descriptive statistics) will inform the inclusion of themes within the final framework., Conclusions: A global consensus on goals, principles, actions, and ways for the development of PL has the potential to provide a largely accepted roadmap for future activities in research, policy, and practice. The co-production approach will help disseminate the GloPL Action Framework and benefit work in relevant application fields of physical activity and health worldwide., Competing Interests: The authors have declared that no competing interests exist., (Copyright: © 2024 Carl et al. This is an open access article distributed under the terms of the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original author and source are credited.)

Published

2024

163. Self-Assembled Preparation of Porous Nickel Phosphide Superparticles with Tunable Phase and Porosity for Efficient Hydrogen Evolution.

Author

Xu W, Chen Y, Niederberger M, Tervoort E, Mei J, and Peng DL

Abstract

Self-assembly of colloidal nanoparticles enables the easy building of assembly units into higher-order structures and the bottom-up preparation of functional materials. Nickel phosphides represent an important group of catalysts for hydrogen evolution reaction (HER) from water splitting. In this paper, the preparation of porous nickel phosphide superparticles and their HER efficiencies are reported. Ni and Ni 2 P nanoparticles are self-assembled into binary superparticles via an oil-in-water emulsion method. After annealing and acid etching, the as-prepared Ni-Ni 2 P binary superparticles change into porous nickel phosphide superparticles. The porosity and crystalline phase of the superparticles can be tuned by adjusting the ratio of Ni and Ni 2 P nanoparticles. The resulting porous superparticles are effective in driving HER under acidic conditions, and the modulation of porosity and phase further optimize the electrochemical performance. The prepared Ni 3 P porous superparticles not only possess a significantly enhanced specific surface area compared to solid Ni-Ni 2 P superparticles but also exhibit an excellent HER efficiency. The calculations based on the density functional theories show that the (110) crystal facet exhibits a relatively lower Gibbs free energy of hydrogen adsorption. This work provides a self-assembly approach for the construction of porous metal phosphide nanomaterials with tunable crystalline phase and porosity., (© 2024 Wiley‐VCH GmbH.)

Published

2024

164. Synthesis of Soluble High Molar Mass Poly(Phenylene Methylene)-Based Polymers.

Author

D'Elia MF, Yu Y, Renggli M, Ehweiner MA, Vidovic C, Mösch-Zanetti NC, Niederberger M, and Caseri W

Abstract

Poly(phenylene methylene) (PPM) is a multifunctional polymer that is also active as an anticorrosion fluorescent coating material. Although this polymer was synthesized already more than 100 years ago, a versatile synthetic route to obtain soluble high molar mass polymers based on PPM has yet to be achieved. In this article, the influence of bifunctional bis-chloromethyl durene (BCMD) as a branching agent in the synthesis of PPM is reported. The progress of the reaction was followed by gel permeation chromatography (GPC) and NMR analysis. PPM-based copolymers with the highest molar mass reported so far for this class of materials (up to M n of 205,300 g mol -1 ) were isolated. The versatile approach of using BCMD was confirmed by employing different catalysts. Interestingly, thermal and optical characterization established that the branching process does not affect the thermoplastic behavior and the fluorescence of the material, thus opening up PPM-based compounds with high molar mass for applications.

Published

2024

165. How can outdoor sports protect themselves against climate change-related health risks? - A prevention model based on an expert Delphi study.

Author

Schneider S, Niederberger M, Kurowski L, and Bade L

Subjects

Humans, Delphi Technique, Climate Change, Athletes, Sports, Sports Medicine methods

Abstract

Objectives: To systematically develop an adaptation model to reduce climate change-related health risks for outdoor athletes., Design: Delphi Method study., Methods: A classic asynchronous Delphi study was conducted with a total of three survey rounds. 24 experts from the eight largest outdoor sport associations by membership in the German Olympic Sports Confederation were included as well as 24 medical experts with expertise in sport medicine, internal medicine, allergology, dermatology, infectiology, or toxicology. Based on open-ended questions, panelists were asked to consider prevention measures for sport organizations and clubs. Free text responses were analyzed by qualitative content analysis according to Mayring., Results: Experts recommended establishing the following eight fields of prevention measures: technical and structural measures; organizational measures; personalized measures; basic, advanced, and continuing education; concepts of action, warning concepts, and financial concepts; cooperation and coordination; campaigns; and evaluation measures., Conclusions: The pyramid model presented in this study systematizes possible sport-specific adaptation measures on climate change by empirical aggregation of knowledge from scientists, sport organizations, clubs, trainers, and professional athletes. To assess the effectiveness of these prevention measures, sport organizations may incorporate them not only into broader operations but also everyday training routines., Competing Interests: Declaration of interest statement The authors declare no conflict of interest., (Copyright © 2023 The Authors. Published by Elsevier Ltd.. All rights reserved.)

Published

2024

166. The Role of Zn Ions in the Structural, Surface, and Gas-Sensing Properties of SnO 2 :Zn Nanocrystals Synthesized via a Microwave-Assisted Route.

Author

da Silva LF, Lucchini MA, Catto AC, Avansi W Jr, Bernardini S, Aguir K, Niederberger M, and Longo E

Abstract

Although semiconducting metal oxide (SMOx) nanoparticles (NPs) have attracted attention as sensing materials, the methodologies available to synthesize them with desirable properties are quite limited and/or often require relatively high energy consumption. Thus, we report herein the processing of Zn-doped SnO 2 NPs via a microwave-assisted nonaqueous route at a relatively low temperature (160 °C) and with a short treatment time (20 min). In addition, the effects of adding Zn in the structural, electronic, and gas-sensing properties of SnO 2 NPs were investigated. X-ray diffraction and high-resolution transmission electron microscopy analyses revealed the single-phase of rutile SnO 2 , with an average crystal size of 7 nm. X-ray absorption near edge spectroscopy measurements revealed the homogenous incorporation of Zn ions into the SnO 2 network. Gas sensing tests showed that Zn-doped SnO 2 NPs were highly sensitive to sub-ppm levels of NO 2 gas at 150 °C, with good recovery and stability even under ambient moisture. We observed an increase in the response of the Zn-doped sample of up to 100 times compared to the pristine one. This enhancement in the gas-sensing performance was linked to the Zn ions that provided more surface oxygen defects acting as active sites for the NO 2 adsorption on the sensing material.

Published

2023

167. [What is a public health intervention? Results of a Delphi process in German-speaking countries].

Author

Dieudonné J, Jantzen L, Sanwald M, Trompke M, Pieper D, Stegbauer C, Willms G, Buchberger B, Brian Büchter R, Bühn S, Fischer F, Klein K, Kuhn J, Messer M, Wegewitz U, and Niederberger M

Subjects

Humans, Delphi Technique, Germany, Consensus, Public Health

Abstract

Background: Internationally, a variety of definitions for public health interventions (PHI) exist. In the German-speaking countries, however, a definition is still outstanding. Therefore, the aim of this study was to derive consensus criteria for the definition of PHI from the expert perspective of science and practice., Methods: A Delphi survey with two online rounds was conducted from December 2022 to February 2023. Six criteria were formulated by a working group and posed for consensus: 1) the intention of the intervention, 2) potential conflicts of interest of the initiators of the intervention, 3) primary vs. secondary/tertiary prevention, 4) costs, 5) targeting, and 6) the reach of the intervention. In both Delphi rounds, experts from academia and practice were recruited through relevant networks and associations throughout the German-speaking world. The judgments were asked about standardized rating scales with the possibility of open justification., Results: In the first Delphi round, n = 52 and in the second round n = 43 experts from research, care and administration/management in health care participated. Consensus was reached on four of the six criteria after the second Delphi round: the intention of the intervention, possible conflicts of interest of the initiators of the intervention, primary vs. secondary/tertiary prevention, and the scope of the intervention. From the perspective of the experts interviewed, these are the criteria that distinguish PHI., Discussion and Conclusion: Based on the consensus criteria, PHI can be defined more concretely. Thus, the results contribute to a better inter- and transdisciplinary understanding. Ideally, the criteria will make it easier to assign interventions to the public health sector in the future, even if a precise examination will be necessary in individual cases, among other things because the experts disagreed on the criteria of costs and how to address the target group., (Copyright © 2023. Published by Elsevier GmbH.)

Published

2023

168. Superelastic Cobalt Silicate@Resorcinol Formaldehyde Resin Core-Shell Nanobelt Aerogel Monoliths with Outstanding Fire Retardant and Thermal Insulating Capability.

Author

Li F, Song J, Niu Y, Zhang H, Niederberger M, and Cheng W

Abstract

The practical applications of resorcinol formaldehyde resin (RFR) aerogels are prevented by their poor mechanical properties. Herein, a facile template-directed method is reported to produce macroscopic free-standing cobalt silicate (CS)@RFR core-shell nanobelt aerogels that display superelastic behavior and outstanding thermal insulating and fire-resistant capability. The synthesis relies on the polymerization of RFR on pre-formed CS nanobelts which leads to in situ formation of hydrogel monoliths that can be transformed to corresponding aerogels by a freeze-drying method. The composite nanobelt aerogel can withstand a compressive load of more than 4000 times of its own weight and fully recover after the removal of the weight. It can also sustain 1000 compressive cycles with 6.9% plastic deformation and 91.8% of the maximum stress remaining, with a constant energy loss coefficient as low as 0.16, at the set strain of 30%. The extraordinary mechanical properties are believed to be associated with the structural flexibility of the nanobelts and the RFR-reinforced joints between the crosslinked nanobelts. These inorganic-organic composite aerogels also show good thermal insulation and excellent fire-proof capability. This work provides an effective strategy for fabricating superelastic RFR-based aerogels which show promising applications in fields such as thermal insulation, energy storage, and catalyst support., (© 2023 Wiley-VCH GmbH.)

Published

2023

169. Definition and terminology of developmental language disorders-Interdisciplinary consensus across German-speaking countries.

Author

Lüke C, Kauschke C, Dohmen A, Haid A, Leitinger C, Männel C, Penz T, Sachse S, Scharff Rethfeldt W, Spranger J, Vogt S, Niederberger M, and Neumann K

Subjects

Child, Humans, Consensus, Delphi Technique, Language Development, Language, Language Development Disorders diagnosis

Abstract

In recent years, there have been intense international discussions about the definition and terminology of language disorders in childhood, such as those sparked by the publications of the CATALISE consortium. To address this ongoing debate, a Delphi study was conducted in German-speaking countries. This study consisted of three survey waves and involved over 400 experts from relevant disciplines. As a result, a far-reaching consensus was achieved on essential definition criteria and terminology, presented in 23 statements. The German term 'Sprachentwicklungsstörung' was endorsed to refer to children with significant deviations from typical language development that can negatively impact social interactions, educational progress, and/or social participation and do not occur together with a potentially contributing impairment. A significant deviation from typical language development was defined as a child's scores in standardized test procedures being ≥ 1.5 SD below the mean for children of the same age. The results of this Delphi study provide a proposal for a uniform use of terminology for language disorders in childhood in German-speaking countries., Competing Interests: The authors have declared that no competing interests exist., (Copyright: © 2023 Lüke et al. This is an open access article distributed under the terms of the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original author and source are credited.)

Published

2023

170. Metal Phosphorous Chalcogenide: A Promising Material for Advanced Energy Storage Systems.

Author

Zhang H, Meng G, Liu Q, Luo Y, Niederberger M, Feng L, Luo J, and Liu X

Abstract

The development of efficient and affordable electrode materials is crucial for clean energy storage systems, which are considered a promising strategy for addressing energy crises and environmental issues. Metal phosphorous chalcogenides (MPX 3 ) are a fascinating class of two-dimensional materials with a tunable layered structure and high ion conductivity, making them particularly attractive for energy storage applications. This review article aims to comprehensively summarize the latest research progress on MPX 3 materials, with a focus on their preparation methods and modulation strategies. Additionally, the diverse applications of these novel materials in alkali metal ion batteries, metal-air batteries, and all-solid-state batteries are highlighted. Finally, the challenges and opportunities of MPX 3 materials are presented to inspire their better potential in energy storage applications. This review provides valuable insights into the promising future of MPX 3 materials in clean energy storage systems., (© 2023 Wiley-VCH GmbH.)

Published

2023

171. Chitin Nanofibrils from Fungi for Hierarchical Gel Polymer Electrolytes for Transient Zinc-Ion Batteries with Stable Zn Electrodeposition.

Author

Ruiz D, Michel VF, Niederberger M, and Lizundia E

Abstract

Rechargeable batteries play an integral role toward carbon neutrality. Environmentally sustainable batteries should consider the trade-offs between material renewability, processability, thermo-mechanical and electrochemical performance, as well as transiency. To address this dilemma, we follow circular economy principles to fabricate fungal chitin nanofibril (ChNF) gel polymer electrolytes (GPEs) for zinc-ion batteries. These biocolloids are physically entangled into hierarchical hydrogels with specific surface areas of 49.5 m 2 ·g -1 . Ionic conductivities of 54.1 mS·cm -1 and a Zn 2+ transference number of 0.468 are reached, outperforming conventional non-renewable/non-biodegradable glass microfibre separator-liquid electrolyte pairs. Enabled by its mechanically elastic properties and large water uptake, a stable Zn electrodeposition in symmetric Zn|Zn configuration with a lifespan above 600 h at 9.5 mA·cm -2 is obtained. At 100 mA·g -1 , the discharge capacity of Zn/α-MnO 2 full cells increases above 500 cycles when replacing glass microfiber separators with ChNF GPEs, while the rate performance remains comparable to glass microfiber separators. To make the battery completely transient, the metallic current collectors are replaced by biodegradable polyester/carbon black composites undergoing degradation in water at 70 °C. This work demonstrates the applicability of bio-based materials to fabricate green and electrochemically competitive batteries with potential applications in sustainable portable electronics, or biomedicine., (© 2023 The Authors. Small published by Wiley-VCH GmbH.)

Published

2023

172. Optimization of Mass and Light Transport in Nanoparticle-Based Titania Aerogels.

Author

Matter F and Niederberger M

Abstract

Aerogels composed of preformed titania nanocrystals exhibit a large surface area, open porosity, and high crystallinity, making these materials appealing for applications in gas-phase photocatalysis. Recent studies on nanoparticle-based titania aerogels have mainly focused on optimizing their composition to improve photocatalytic performance. Little attention has been paid to modification at the microstructural level to control fundamental properties such as gas permeability and light transmittance, although these features are of fundamental importance, especially for photocatalysts of macroscopic size. In this study, we systematically control the porosity and transparency of titania gels and aerogels by adjusting the particle loading and nonsolvent fraction during the gelation step. Mass transport and light transport were assessed by gas permeability and light attenuation measurements, and the results were related to the microstructure determined by gas sorption analysis and scanning electron microscopy. Mass transport through the aerogel network was found to proceed primarily via Knudsen diffusion leading to relatively low permeabilities in the range of 10 -5 -10 -6 m 2 /s, despite very high porosities of 96-99%. While permeability was found to depend mainly on particle loading, the optical properties are predominantly affected by the amount of nonsolvent during gelation, allowing independent tuning of mass and light transport., Competing Interests: The authors declare no competing financial interest., (© 2023 The Authors. Published by American Chemical Society.)

Published

2023

173. Oriented Porous NASICON 3D Framework via Freeze-Casting for Sodium-Metal Batteries.

Author

Edison E, Parrilli A, Tervoort E, Eliasson H, and Niederberger M

Abstract

Sodium-metal batteries are promising candidates for low-cost, large-format energy storage systems. However, sodium-metal batteries suffer from high interfacial resistance between the electrodes and the solid electrolyte, leading to poor electrochemical performance. We demonstrate a sodium superionic conductor (NASICON) with an oriented porous framework of sodium aluminum titanium phosphate (NATP) fabricated by the freeze-casting technique, which shows excellent properties as a solid electrolyte. Using X-ray computed tomography, we confirm the uniform low-tortuosity channels present along the thickness of the scaffold. We infiltrated the porous NATP scaffolds with sodium vanadium phosphate (NVP) cathode nanoparticles achieving mass loadings of ∼3-4 mg cm -2 , which enables short sodium ion diffusion path lengths. For the resulting hybrid cell, we achieved a capacity of ∼90 mAh g -1 at a specific current of 50 mA g -1 (∼300 Wh kg -1 ) for over 100 cycles with ∼94% capacity retention. Our study offers valuable insights for the design of hybrid solid electrolyte-cathode active material structures to achieve improved electrochemical performance through low-tortuosity ion transport networks.

Published

2023

174. Proxying economic activity with daytime satellite imagery: Filling data gaps across time and space.

Author

Lehnert P, Niederberger M, Backes-Gellner U, and Bettinger E

Abstract

This paper develops a novel procedure for proxying economic activity with daytime satellite imagery across time periods and spatial units, for which reliable data on economic activity are otherwise not available. In developing this unique proxy, we apply machine-learning techniques to a historical time series of daytime satellite imagery dating back to 1984. Compared to satellite data on night light intensity, another common economic proxy, our proxy more precisely predicts economic activity at smaller regional levels and over longer time horizons. We demonstrate our measure's usefulness for the example of Germany, where East German data on economic activity are unavailable for detailed regional levels and historical time series. Our procedure is generalizable to any region in the world, and it has great potential for analyzing historical economic developments, evaluating local policy reforms, and controlling for economic activity at highly disaggregated regional levels in econometric applications., (© The Author(s) 2023. Published by Oxford University Press on behalf of National Academy of Sciences.)

Published

2023

175. Conducting ITO Nanoparticle-Based Aerogels-Nonaqueous One-Pot Synthesis vs. Particle Assembly Routes.

Author

Sang Bastian S, Rechberger F, Zellmer S, Niederberger M, and Garnweitner G

Abstract

Indium tin oxide (ITO) aerogels offer a combination of high surface area, porosity and conductive properties and could therefore be a promising material for electrodes in the fields of batteries, solar cells and fuel cells, as well as for optoelectronic applications. In this study, ITO aerogels were synthesized via two different approaches, followed by critical point drying (CPD) with liquid CO 2 . During the nonaqueous one-pot sol-gel synthesis in benzylamine (BnNH 2 ), the ITO nanoparticles arranged to form a gel, which could be directly processed into an aerogel via solvent exchange, followed by CPD. Alternatively, for the analogous nonaqueous sol-gel synthesis in benzyl alcohol (BnOH), ITO nanoparticles were obtained and assembled into macroscopic aerogels with centimeter dimensions by controlled destabilization of a concentrated dispersion and CPD. As-synthesized ITO aerogels showed low electrical conductivities, but an improvement of two to three orders of magnitude was achieved by annealing, resulting in an electrical resistivity of 64.5-1.6 kΩ·cm. Annealing in a N 2 atmosphere led to an even lower resistivity of 0.2-0.6 kΩ·cm. Concurrently, the BET surface area decreased from 106.2 to 55.6 m 2 /g with increasing annealing temperature. In essence, both synthesis strategies resulted in aerogels with attractive properties, showing great potential for many applications in energy storage and for optoelectronic devices.

Published

2023

176. Argument-based QUalitative Analysis strategy (AQUA) for analyzing free-text responses in health sciences Delphi studies.

Author

Niederberger M and Homberg A

Abstract

Delphi methods are mostly used in the health sciences to reach agreement among experts on unclear issues. Generally, consensus is reached after several rounds of Delphi using standardized items. Additional open-ended questions offer respondents the opportunity to provide reasons for judgments. Although these free-text responses contribute substantially to the steering and result generation of the Delphi process, so far no analytical strategy has been established which takes into account the context and methodological principles of the Delphi procedure. Moreover, in already published Delphi studies the analysis of qualitative data is often not sufficiently disclosed.•We provide an overview of analytical strategies for free-text responses. We critically reflect on them with regard to their use and suitability in the context of Delphi procedures.•Following established qualitative methods of qualitative content analysis according to Mayring and thematic analysis according to Braun & Clarke, we developed the A rgument-based QU alitative A nalysis strategy (AQUA) for Delphi studies in the health sciences and presented it using a concrete project example.•This newly developed strategy can significantly support the rule-governed and intersubjective evaluation of free-text responses in Delphi processes, the integration of the results into the feedback design, and thereby also the quality of the results., Competing Interests: The authors declare that they have no known competing financial interests or personal relationships that could have appeared to influence the work reported in this paper., (© 2023 The Authors. Published by Elsevier B.V.)

Published

2023

177. Bottom-Up Design of a Green and Transient Zinc-Ion Battery with Ultralong Lifespan.

Author

Mittal N, Ojanguren A, Kundu D, Lizundia E, and Niederberger M

Abstract

Transient batteries are expected to lessen the inherent environmental impact of traditional batteries that rely on toxic and critical raw materials. This work presents the bottom-up design of a fully transient Zn-ion battery (ZIB) made of nontoxic and earth-abundant elements, including a novel hydrogel electrolyte prepared by cross-linking agarose and carboxymethyl cellulose. Facilitated by a high ionic conductivity and a high positive zinc-ion species transference number, the optimized hydrogel electrolyte enables stable cycling of the Zn anode with a lifespan extending over 8500 h for 0.25 mA cm -2 - 0.25 mAh cm -2 . On pairing with a biocompatible organic polydopamine-based cathode, the full cell ZIB delivers a capacity of 196 mAh g -1 after 1000 cycles at a current density of 0.5 A g -1 and a capacity of 110 mAh g -1 after 10 000 cycles at a current density of 1 A g -1 . A transient ZIB with a biodegradable agarose casing displays an open circuit voltage of 1.123 V and provides a specific capacity of 157 mAh g -1 after 200 cycles at a current density of 50 mA g -1 . After completing its service life, the battery can disintegrate under composting conditions., (© 2022 The Authors. Small published by Wiley-VCH GmbH.)

Published

2023

178. Improving the Corrosion Protection of Poly(phenylene methylene) Coatings by Side Chain Engineering: The Case of Methoxy-Substituted Copolymers.

Author

D'Elia MF, Magni M, Trasatti SPM, Niederberger M, and Caseri WR

Subjects

Corrosion, Alloys chemistry, Polymers, Aluminum, Coated Materials, Biocompatible chemistry

Abstract

This work aims to improve the corrosion protection features of poly(phenylene methylene) (PPM) by sidechain engineering inserting methoxy units along the polymer backbone. The influence of side methoxy groups at different concentrations (4.6% mol/mol and 9% mol/mol) on the final polymer properties was investigated by structural and thermal characterization of the resulting copolymers: co-PPM 4.6% and co-PPM 9%, respectively. Then, coatings were processed by hot pressing the polymers powder on aluminum alloy AA2024 and corrosion protection properties were evaluated exposing samples to a 3.5% w/v NaCl aqueous solution. Anodic polarization tests evidenced the enhanced corrosion protection ability (i.e., lower current density) by increasing the percentage of the co-monomer. Coatings made with co-PPM 9% showed the best protection performance with respect to both PPM blend and PPM co-polymers reported so far. Electrochemical response of aluminum alloy coated with co-PPM 9% was monitored over time under two "artificially-aged" conditions, that are: (i) a pristine coating subjected to potentiostatic anodic polarization cycles, and (ii) an artificially damaged coating at resting condition. The first scenario points to accelerating the corrosion process, the second one models damage of the coating potentially occurring either due to natural deterioration or due to any accidental scratching of the polymer layer. In both cases, an intrinsic self-healing phenomenon was indirectly argued by the time evolution of the impedance and of the current density of the coated systems. The degree of restoring to the "factory conditions" by co-polymer coatings after self-healing events is eventually discussed., Competing Interests: The authors declare no conflict of interest.

Published

2022

179. [The Delphi technique: Methodology, variants and usage examples].

Author

Niederberger M and Deckert S

Subjects

Humans, Delphi Technique, Germany, Consensus, Research Design, Communication

Abstract

In the field of medicine and health sciences, Delphi methods are applied mainly in the exploratory or evaluative phases of a research process. Explicit and implicit knowledge of respected experts from research and practice is systematically synthesized. Originally developed as a method for structuring a group communication process, Delphi techniques have been established in the health sector as a consensus method. The findings are used to improve the evidence and acceptance of planned interventions or necessary standards or guidelines and to increase the probability of successful implementation in practice. However, different variants of Delphi methods have been developed in recent years, which are systematically contrasted and reflected in this paper with regard to key epistemological and methodological research activities. Based on this overview, researchers should be enabled to select the most suitable Delphi technique for their own research questions and research endeavors., (Copyright © 2022. Published by Elsevier GmbH.)

Published

2022

180. Robust Antibacterial Activity of Xanthan-Gum-Stabilized and Patterned CeO 2- x -TiO 2 Antifog Films.

Author

Guo F, Pan F, Zhang W, Liu T, Zuber F, Zhang X, Yu Y, Zhang R, Niederberger M, and Ren Q

Subjects

Anti-Bacterial Agents chemistry, Anti-Bacterial Agents pharmacology, Escherichia coli, Humans, Hyaluronic Acid, Ions, Phosphates, Polysaccharides, Bacterial, Reactive Oxygen Species, Titanium, Anti-Infective Agents chemistry, Staphylococcus aureus

Abstract

Increased occurrence of antimicrobial resistance leads to a huge burden on patients, the healthcare system, and society worldwide. Developing antimicrobial materials through doping rare-earth elements is a new strategy to overcome this challenge. To this end, we design antibacterial films containing CeO 2- x -TiO 2 , xanthan gum, poly(acrylic acid), and hyaluronic acid. CeO 2- x -TiO 2 inks are additionally integrated into a hexagonal grid for prominent transparency. Such design yields not only an antibacterial efficacy of ∼100% toward Staphylococcus aureus and Escherichia coli but also excellent antifog performance for 72 h in a 100% humidity atmosphere. Moreover, FluidFM is employed to understand the interaction in-depth between bacteria and materials. We further reveal that reactive oxygen species (ROS) are crucial for the bactericidal activity of E. coli through fluorescent spectroscopic analysis and SEM imaging. We meanwhile confirm that Ce 3+ ions are involved in the stripping phosphate groups, damaging the cell membrane of S. aureus . Therefore, the hexagonal mesh and xanthan-gum cross-linking chains act as a reservoir for ROS and Ce 3+ ions, realizing a long-lasting antibacterial function. We hence develop an antibacterial and antifog dual-functional material that has the potential for a broad application in display devices, medical devices, food packaging, and wearable electronics.

Published

2022

181. Hierarchical Nanocellulose-Based Gel Polymer Electrolytes for Stable Na Electrodeposition in Sodium Ion Batteries.

Author

Mittal N, Tien S, Lizundia E, and Niederberger M

Subjects

Polymers, Electroplating, Electrolytes chemistry, Ions, Cellulose chemistry, Lithium chemistry, Sodium chemistry

Abstract

Sodium ion batteries (NIBs) based on earth-abundant materials offer efficient, safe, and environmentally sustainable solutions for a decarbonized society. However, to compete with mature energy storage technologies such as lithium ion batteries, further progress is needed, particularly regarding the energy density and operational lifetime. Considering these aspects as well as a circular economy perspective, the authors use biodegradable cellulose nanoparticles for the preparation of a gel polymer electrolyte that offers a high liquid electrolyte uptake of 2985%, an ionic conductivity of 2.32 mS cm -1 , and a Na + transference number of 0.637. A balanced ratio of mechanically rigid cellulose nanocrystals and flexible cellulose nanofibers results in a mesoporous hierarchical structure that ensures close contact with metallic Na. This architecture offers stable Na plating/stripping at current densities up to ±500 µA cm -2 , outperforming conventional fossil-based NIBs containing separator-liquid electrolytes. Paired with an environmentally sustainable and economically attractive Na 2 Fe 2 (SO 4 ) 3 cathode, the battery reaches an energy density of 240 Wh kg -1 , delivering 69.7 mAh g -1 after 50 cycles at a rate of 1C. In comparison, Celgard in liquid electrolyte delivers only 0.6 mAh g -1 at C/4. Such gel polymer electrolytes may open up new opportunities for sustainable energy storage systems beyond lithium ion batteries., (© 2022 The Authors. Small published by Wiley-VCH GmbH.)

Published

2022

182. Studies on the Interaction of Poly(phenylene methylene) with Silver(I) and Hexacarbonylchromium(0).

Author

Guichard XH, Braendle A, Niederberger M, and Caseri W

Abstract

Complexes of poly(phenylene methylene) (PPM) with silver(I) ions and tricarbonylchromium(0) moieties, respectively, were synthesized. 13 C NMR spectra indicate interaction of phenylene groups with silver(I) and chromium(0), and peak broadening implies dynamic behavior of the silver(I) complexes, with all phenylene groups temporarily involved in coordination, in contrast to the chromium complexes. About 5-10% of the phenylene groups are coordinated to metal atoms. 1 H NMR and IR spectra, in the case of chromium(0), and the solubility of silver salts in the presence of PPM provide further evidence of coordination. The complexes are soluble in chloroform, but the silver complexes decay in tetrahydrofuran (second-order kinetics were observed in an example). The photoluminescence (fluorescence) of PPM is maintained upon complexation, although coordination of silver(I) seems to favor the so-called blue phase of PPM relative to the green phase by a factor of approximately two in PL spectra. The pronounced absorption of the tricarbonylchromium(0) units interferes with the blue phase, which almost disappears at a concentration of 50 mg/mL in PLE spectra, whereas the emission maximum of the green phase is hardly affected. This leads to a confinement of the emitted wavelength range of PPM. Thus, the perceived optical emission of PPM can be modified by coordinated entities.

Published

2022

183. Smart Anticorrosion Coatings Based on Poly(phenylene methylene): An Assessment of the Intrinsic Self-Healing Behavior of the Copolymer.

Author

D'Elia MF, Magni M, Romanò T, Trasatti SPM, Niederberger M, and Caseri WR

Abstract

Poly(phenylene methylene) (PPM) is a multifunctional polymer featuring hydrophobicity, high thermal stability, fluorescence and thermoplastic processability. Accordingly, smart corrosion resistant PPM-based coatings (blend and copolymer) were prepared and applied by hot pressing on aluminum alloy AA2024. The corrosion protection properties of the coatings and their dependence on coating thickness were evaluated for both strategies employed. The accelerated cyclic electrochemical technique (ACET), based on a combination of electrochemical impedance spectroscopy (EIS), cathodic polarizations and relaxation steps, was used as the main investigating technique. At the coating thickness of about 50 µm, both blend and copolymer PPM showed effective corrosion protection, as reflected by |Z| 0.01Hz of about 10 8 Ω cm 2 over all the ACET cycles. In contrast, when the coating thickness was reduced to 30 µm, PPM copolymer showed neatly better corrosion resistance than blended PPM, maintaining |Z| 0.01Hz above 10 8 Ω cm 2 with respect to values below 10 6 Ω cm 2 of the latter. Furthermore, the analysis of many electrochemical key features, in combination with the optical investigation of the coating surface under 254 nm UV light, confirms the intrinsic self-healing ability of the coatings made by PPM copolymer, contrary to the reference specimen (i.e., blend PPM).

Published

2022

184. Reporting guidelines for Delphi techniques in health sciences: A methodological review.

Author

Spranger J, Homberg A, Sonnberger M, and Niederberger M

Subjects

Consensus, Delphi Technique, Germany, Humans, Research Design, Research Report

Abstract

Background: Delphi techniques are conducted across different subfields in the health sciences. The reporting practices of studies using Delphi techniques vary, and current reporting guidelines for Delphi techniques focus on individual subfields of the health sciences or on different aspects of research and are therefore of limited applicability. The aim of this article was to identify similarities, differences, and possible shortcomings of existing Delphi reporting guidelines and to draft an initial proposal for a comprehensively applicable reporting guideline., Methods: A systematic literature search for reporting guidelines on Delphi studies was performed in existing data resources based on databases in the health sciences (Scopus, MEDLINE, CINAHL, Epistemonikos) including publications from 2016 to 2021. In June 2021, we conducted an additional search in PubMed and included further studies by contacting experts of the scientific Delphi expert network (DeWiss). Title and abstract screening of articles was performed, followed by a full-text screening of the articles included. We qualitatively and quantitatively evaluated, compared and contrasted the reporting guidelines identified using content analysis and discussed the results among the members of the Delphi expert network., Results: We retrieved ten health science articles with reporting guidelines for Delphi studies. In analyzing them, we identified nine main categories (Justification, Expert panel, Questionnaire, Survey design, Process regulation, Analyses, Results, Discussion, Methods reflection & Ethics). The current reporting guidelines vary significantly, with only the aspect of consensus appearing in all of them. Frequency distributions show that most of the subcategories are only addressed in individual articles (e.g., meeting of participants, proceeding with the survey method, transfer of the results, validation, prevention of bias) and that epistemological foundations of the Delphi technique are rarely mentioned or reflected on. We drafted an initial proposal for Delphi reporting guidelines for the health science sector., Discussion: A well-justified position concerning epistemological foundations of Delphi studies is necessary to make the quality of the process assessable and, along with the reporting of the process, to classify and compare study results. This will increase the acceptance of both the method in the health science sector and the results in medical practice. A Delphi reporting guideline must, above all, take into account the diversity of variants, subfield-related objectives and application areas, and their modifications of the Delphi technique in order to be comprehensively applicable in the health sciences., Conclusion: The results of our methodological review do not provide a final reporting guideline. The newly developed proposal is intended to encourage discussion and agreement in further analyses., (Copyright © 2022. Published by Elsevier GmbH.)

Published

2022

185. The Importance of the Macroscopic Geometry in Gas-Phase Photocatalysis.

Author

Matter F and Niederberger M

Abstract

Photocatalysis has the potential to make a major technological contribution to solving pressing environmental and energy problems. There are many strategies for improving photocatalysts, such as tuning the composition to optimize visible light absorption, charge separation, and surface chemistry, ensuring high crystallinity, and controlling particle size and shape to increase overall surface area and exploit the reactivity of individual crystal facets. These processes mainly affect the nanoscale and are therefore summarized as nanostructuring. In comparison, microstructuring is performed on a larger size scale and is mainly concerned with particle assembly and thin film preparation. Interestingly, most structuring efforts stop at this point, and there are very few examples of geometry optimization on a millimeter or even centimeter scale. However, the recent work on nanoparticle-based aerogel monoliths has shown that this size range also offers great potential for improving the photocatalytic performance of materials, especially when the macroscopic geometry of the monolith is matched to the design of the photoreactor. This review article is dedicated to this aspect and addresses some issues and open questions that arise when working with macroscopically large photocatalysts. Guidelines are provided that could help develop novel and efficient photocatalysts with a truly 3D architecture., (© 2022 The Authors. Advanced Science published by Wiley-VCH GmbH.)

Published

2022

186. Transient Batteries: A Promising Step Towards Powering Green Electronics.

Author

Mittal N and Niederberger M

Abstract

Transient electronics is an emerging class of innovative technology wherein electronic devices undergo controlled degradation processes after a period of stable operation, leaving no toxic products behind. This technology offers exciting opportunities in research areas of green electronics, temporary biomedical implants, data-secure hardware systems, and many others. However, one major challenge with these devices is their rigid and bulky batteries that contain toxic chemicals and are not at all degradable. So, to realize autonomous and self-sufficient transient electronics, the development of transient batteries is a pre-requisite. This review provides an overview of the advancements in the field of transient batteries, their materials, output performance, transience behaviour, and a few potential applications., (Copyright 2022 Neeru Mittal, Markus Niederberger. License: This work is licensed under a Creative Commons Attribution 4.0 International License.)

Published

2022

187. 3D Printed Scaffolds for Monolithic Aerogel Photocatalysts with Complex Geometries.

Author

Schreck M, Kleger N, Matter F, Kwon J, Tervoort E, Masania K, Studart AR, and Niederberger M

Subjects

Printing, Three-Dimensional, Nanoparticles

Abstract

Monolithic aerogels composed of crystalline nanoparticles enable photocatalysis in three dimensions, but they suffer from low mechanical stability and it is difficult to produce them with complex geometries. Here, an approach to control the geometry of the photocatalysts to optimize their photocatalytic performance by introducing carefully designed 3D printed polymeric scaffolds into the aerogel monoliths is reported. This allows to systematically study and improve fundamental parameters in gas phase photocatalysis, such as the gas flow through and the ultraviolet light penetration into the aerogel and to customize its geometric shape to a continuous gas flow reactor. Using photocatalytic methanol reforming as a model reaction, it is shown that the optimization of these parameters leads to an increase of the hydrogen production rate by a factor of three from 400 to 1200 µmol g -1 h -1 . The rigid scaffolds also enhance the mechanical stability of the aerogels, lowering the number of rejects during synthesis and facilitating handling during operation. The combination of nanoparticle-based aerogels with 3D printed polymeric scaffolds opens up new opportunities to tailor the geometry of the photocatalysts for the photocatalytic reaction and for the reactor to maximize overall performance without necessarily changing the material composition., (© 2021 The Authors. Small published by Wiley-VCH GmbH.)

Published

2021

188. Gas-Phase Nitrogen Doping of Monolithic TiO 2 Nanoparticle-Based Aerogels for Efficient Visible Light-Driven Photocatalytic H 2 Production.

Author

Kwon J, Choi K, Schreck M, Liu T, Tervoort E, and Niederberger M

Abstract

The development of visible light-active photocatalysts is essential for increasing the conversion efficiency of solar energy into hydrogen (H 2 ). Here, we present a facile method for nitrogen doping of monolithic titanium dioxide (TiO 2 ) nanoparticle-based aerogels to activate them for visible light. Plasma-enhanced chemical vapor deposition at low temperature enables efficient incorporation of nitrogen into preformed TiO 2 aerogels without compromising their advantageous intrinsic characteristics such as large surface area, extensive porosity, and nanoscale properties of the semiconducting building blocks. By balancing the dopant concentration and the defects, the nitridation improves optical absorption and charge separation efficiency. The nitrogen-doped TiO 2 nanoparticle-based aerogels loaded with palladium (Pd) nanoparticles show a significant enhancement in visible light-driven photocatalytic H 2 production (3.1 mmol h -1 g -1 ) with excellent stability over 5 days. With this method, we introduce a powerful tool to tune the properties of nanoparticle-based aerogels after synthesis for a specific application, as exemplified by visible light-driven H 2 production.

Published

2021

189. Synthesis of Cu 3 N and Cu 3 N-Cu 2 O multicomponent mesocrystals: non-classical crystallization and nanoscale Kirkendall effect.

Author

Primc D, Indrizzi L, Tervoort E, Xie F, and Niederberger M

Abstract

Mesocrystals are superstructures of crystallographically aligned nanoparticles and are a rapidly emerging class of crystalline materials displaying sophisticated morphologies and properties, beyond those originating from size and shape of nanoparticles alone. This study reports the first synthesis of Cu 3 N mesocrystals employing structure-directing agents with a subtle tuning of the reaction parameters. Detailed structural characterizations carried out with a combination of transmission electron microscopy techniques (HRTEM, HAADF-STEM-EXDS) reveal that Cu 3 N mesocrystals form by non-classical crystallization, and variations in their sizes and morphologies are traced back to distinct attachment scenarios of corresponding mesocrystal subunits. In the presence of oleylamine, the mesocrystal subunits in the early reaction stages prealign in a crystallographic fashion and afterwards grow into the final mesocrystals, while in the presence of hexadecylamine the subunits come into contact through misaligned attachment, and subsequently, to some degree, realign in crystallographic register. Upon prolonged heating both types of mesocrystals undergo chemical conversion processes resulting in structural and morphological changes. A two-step mechanism of chemical conversion is proposed, involving Cu 3 N decomposition and anion exchange driven by the nanoscale Kirkendall effect, resulting first in multicomponent/heterostructured Cu 3 N-Cu 2 O mesocrystals, which subsequently convert into Cu 2 O nanocages. It is anticipated that combining nanostructured Cu 3 N and Cu 2 O in a mesocrystalline and hollow morphology will provide a platform to expand their application potential.

Published

2021

190. Coming to consensus: the Delphi technique.

Author

Niederberger M and Köberich S

Subjects

Consensus, Humans, Delphi Technique

Abstract

Delphi techniques are used in health care and nursing to systematically bring together explicit and implicit knowledge from experts with a research or practical background, often with the goal of reaching a group consensus. Consensus standards and findings are important for promoting the exchange of information and ideas on an interdisciplinary and transdisciplinary basis, and for guaranteeing comparable procedures in diagnostic and therapeutic approaches. Yet, the development of consensus standards using Delphi techniques is challenging because it is dependent on the willingness of experts to participate and the statistical definition of consensus., (Published on behalf of the European Society of Cardiology. All rights reserved. © The Author(s) 2021. For permissions, please email: journals.permissions@oup.com.)

Published

2021

191. Colloidal Nanocrystals: A Toolbox for Materials Chemistry.

Author

Matter F, Niederberger M, and Putz F

Abstract

Colloidal nanocrystals are the ideal building blocks for the fabrication of functional materials. Using various assembly, patterning or processing techniques, the nanocrystals can be arranged with unprecedented flexibility in 1-, 2- or 3-dimensional architectures over several orders of length scales, providing access to ordered or disordered, porous or non-porous, and simple as well as hierarchical structures. Careful selection of colloidal nanocrystals allows the properties of the final materials to be predefined. Moreover, by combining different nanocrystals, these properties can be fine-tuned for a specific application, opening up fascinating opportunities to create new materials for energy storage and conversion, catalysis, photocatalysis, biomedicine or optics. Indeed, functional materials made of preformed nanoparticles have been realized for metals, polymers, semiconductors, and ceramics, as well as for composites and organic-inorganic hybrids. In this review article, we introduce some concepts for the fabrication of colloidal nanocrystals and their assembly into dense and porous 3-dimensional structures. Porosity is a particularly important material property that strongly influences its application potential. Therefore, we pay special attention to this aspect and compare porous materials synthesized from nanoparticles with those from molecular routes. An additional focus is set on the degree of structural order that can be achieved on different length scales.

Published

2021

192. Stable Na Electrodeposition Enabled by Agarose-Based Water-Soluble Sodium Ion Battery Separators.

Author

Ojanguren A, Mittal N, Lizundia E, and Niederberger M

Abstract

Developing efficient energy storage technologies is at the core of current strategies toward a decarbonized society. Energy storage systems based on renewable, nontoxic, and degradable materials represent a circular economy approach to address the environmental pollution issues associated with conventional batteries, that is, resource depletion and inadequate disposal. Here we tap into that prospect using a marine biopolymer together with a water-soluble polymer to develop sodium ion battery (NIB) separators. Mesoporous membranes comprising agarose, an algae-derived polysaccharide, and poly(vinyl alcohol) are synthesized via nonsolvent-induced phase separation. Obtained membranes outperform conventional nondegradable NIB separators in terms of thermal stability, electrolyte wettability, and Na + conductivity. Thanks to the good interfacial adhesion with metallic Na promoted by the hydroxyl and ether functional groups of agarose, the separators enable a stable and homogeneous Na deposition with limited dendrite growth. As a result, membranes can operate at 200 μA cm -2 , in contrast with Celgard and glass microfiber, which short circuit at 50 and 100 μA cm -2 , respectively. When evaluated in Na 3 V 2 (PO 4 ) 3 /Na half-cells, agarose-based separators deliver 108 mA h g -1 after 50 cycles at C/10, together with a remarkable rate capability. This work opens up new possibilities for the use of water-degradable separators, reducing the environmental burdens arising from the uncontrolled accumulation of electronic waste in marine or land environments.

Published

2021

193. Degradation Behavior, Biocompatibility, Electrochemical Performance, and Circularity Potential of Transient Batteries.

Author

Mittal N, Ojanguren A, Niederberger M, and Lizundia E

Abstract

Transient technology seeks the development of materials, devices, or systems that undergo controlled degradation processes after a stable operation period, leaving behind harmless residues. To enable externally powered fully transient devices operating for longer periods compared to passive devices, transient batteries are needed. Albeit transient batteries are initially intended for biomedical applications, they represent an effective solution to circumvent the current contaminant leakage into the environment. Transient technology enables a more efficient recycling as it enhances material retrieval rates, limiting both human and environmental exposures to the hazardous pollutants present in conventional batteries. Little efforts are focused to catalog and understand the degradation characteristics of transient batteries. As the energy field is a property-driven science, not only electrochemical performance but also their degradation behavior plays a pivotal role in defining the specific end-use applications. The state-of-the-art transient batteries are critically reviewed with special emphasis on the degradation mechanisms, transiency time, and biocompatibility of the released degradation products. The potential of transient batteries to change the current paradigm that considers batteries as harmful waste is highlighted. Overall, transient batteries are ready for takeoff and hold a promising future to be a frontrunner in the uptake of circular economy concepts., Competing Interests: The authors declare no conflict of interest., (© 2021 The Authors. Advanced Science published by Wiley‐VCH GmbH.)

Published

2021

194. Multifunctional Batteries: Flexible, Transient, and Transparent.

Author

Wehner LA, Mittal N, Liu T, and Niederberger M

Abstract

The primary task of a battery is to store energy and to power electronic devices. This has hardly changed over the years despite all the progress made in improving their electrochemical performance. In comparison to batteries, electronic devices are continuously equipped with new functions, and they also change their physical appearance, becoming flexible, rollable, stretchable, or maybe transparent or even transient or degradable. Mechanical flexibility makes them attractive for wearable electronics or for electronic paper; transparency is desired for transparent screens or smart windows, and degradability or transient properties have the potential to reduce electronic waste. For fully integrated and self-sufficient systems, these devices have to be powered by batteries with similar physical characteristics. To make the currently used rigid and heavy batteries flexible, transparent, and degradable, the whole battery architecture including active materials, current collectors, electrolyte/separator, and packaging has to be redesigned. This requires a fundamental paradigm change in battery research, moving away from exclusively addressing the electrochemical aspects toward an interdisciplinary approach involving chemists, materials scientists, and engineers. This Outlook provides an overview of the different activities in the field of flexible, transient, and transparent batteries with a focus on the challenges that have to be faced toward the development of such multifunctional energy storage devices., Competing Interests: The authors declare no competing financial interest., (© 2021 The Authors. Published by American Chemical Society.)

Published

2021

195. Porous Silica Microspheres with Immobilized Titania Nanoparticles for In-Flow Solar-Driven Purification of Wastewater.

Author

Marques AC, Vale M, Vicente D, Schreck M, Tervoort E, and Niederberger M

Abstract

In this paper, inorganic silica microspheres with interconnected macroporosity are tested as a platform for designing robust and efficient photocatalytic systems for a continuous flow reactor, enabling a low cost and straightforward purification of wastewater through solar-driven photocatalysis. The photocatalytically active microspheres are prepared by wet impregnation of porous silica scaffolds with Trizma-functionalized anatase titania (TiO 2 ) nanoparticles (NPs). NPs loading of 22 wt% is obtained in the form of a thin and well-attached layer, covering the external surface of the microspheres as well as the internal surface of the pores. The TiO 2 loading leads to an increase of the specific surface area by 26%, without impacting the typically interconnected macroporosity ( ≈ 60%) of the microspheres, which is essential for an efficient flow of the pollutant solution during the photocatalytic tests. These are carried out in a liquid medium for the decomposition of methyl orange and paracetamol. In addition to photocatalytic activity under continuous flow, the microspheres offer the advantage that they can be easily removed from the reaction medium, which is an appealing aspect for industrial applications. In this work, the typical issues of TiO 2 NPs photocatalysts are circumvented, without the need for elaborate chemistries, and for low availability and expensive raw materials., Competing Interests: The authors declare no conflict of interest., (© 2021 The Authors. Global Challenges published by Wiley‐VCH GmbH.)

Published

2021

196. Delphi Technique in Health Sciences: A Map.

Author

Niederberger M and Spranger J

Subjects

Consensus, Delphi Technique, Medicine

Abstract

Objectives: In health sciences, the Delphi technique is primarily used by researchers when the available knowledge is incomplete or subject to uncertainty and other methods that provide higher levels of evidence cannot be used. The aim is to collect expert-based judgments and often to use them to identify consensus. In this map, we provide an overview of the fields of application for Delphi techniques in health sciences in this map and discuss the processes used and the quality of the findings. We use systematic reviews of Delphi techniques for the map, summarize their findings and examine them from a methodological perspective. Methods: Twelve systematic reviews of Delphi techniques from different sectors of the health sciences were identified and systematically analyzed. Results: The 12 systematic reviews show, that Delphi studies are typically carried out in two to three rounds with a deliberately selected panel of experts. A large number of modifications to the Delphi technique have now been developed. Significant weaknesses exist in the quality of the reporting. Conclusion: Based on the results, there is a need for clarification with regard to the methodological approaches of Delphi techniques, also with respect to any modification. Criteria for evaluating the quality of their execution and reporting also appear to be necessary. However, it should be noted that we cannot make any statements about the quality of execution of the Delphi studies but rather our results are exclusively based on the reported findings of the systematic reviews., (Copyright © 2020 Niederberger and Spranger.)

Published

2020

197. [Mixed-methods studies in the field of health promotion. Results of a systematic review of German publications].

Author

Schneider P and Niederberger M

Subjects

Germany, Qualitative Research, Health Promotion, Research Design

Abstract

Research in the field of health promotion generates evidence-based knowledge and has the potential to increase the acceptance, impact and long-term effectiveness of interventions. Typically, a distinction is made between qualitative and quantitative approaches. Yet, with complex and multidimensional re-search questions in the field of health promotion a combination of the two approaches has proven useful. Using mixed-methods designs promises, among other things, to compensate for weaknesses of the individual methods, to improve the scope of the results, and to provide a comprehensive insight into the topic. In this systematic review of two German journals we examine the role of the mixed-methods approach in the field of health promotion and how it can be translated into specific research projects. The review's results show that mixed-methods designs are implemented in various contexts. In most studies, the quantitative research strand plays the central role. The use of the mixed-methods designs in health promotion can be further discussed, especially taking into account technical innovations in the field of data collection or with regard to the interpretative potential of qualitative research. The presentation of the review is based on PRISMA (Preferred Reporting Items for Systematic Reviews and Meta-Analyses) by the Equator Network., (Copyright © 2020. Published by Elsevier GmbH.)

Published

2020

198. A Sodium-Ion Battery Separator with Reversible Voltage Response Based on Water-Soluble Cellulose Derivatives.

Author

Casas X, Niederberger M, and Lizundia E

Abstract

The development of efficient, safe, and environmentally friendly energy storage systems plays a pivotal role in moving toward a more sustainable society. Sodium-ion batteries (NIBs) have garnered considerable interest in grid energy storage applications because of the abundance of sodium, low cost, and suitable redox potential. However, NIB technology is still in its infancy, especially with regard to separators. Here we develop a novel separator based on renewable water-soluble cellulose derivatives. Carboxymethyl cellulose (CMC) and hydroxyethyl cellulose (HEC) are cross-linked to afford large-specific-surface-area membranes upon nonsolvent-induced phase separation (NIPS). Long-term galvanostatic cycling in a symmetric Na/Na cell configuration shows an impressive reversible voltage response with a square wave shape of the polarization even after 250 h of cycling, indicating remarkably stable Na plating and stripping with Na dendrite growth suppression. This novel membrane is evaluated as a separator in Na 3 V 2 (PO 4 ) 3 /Na half-cells. After 10 cycles at C/10, the cellulosic separator delivers a capacity of 74 mA·h·g -1 with a 100% Coulombic efficiency compared to that of 61 mA·h·g -1 and 96% obtained for Whatman GF/D as a commercially available separator. Our work provides novel cues for the development of biomass-derived porous membranes to function as battery separators, surpassing the performance of commercially available separators based on fossil resources in terms of capacity retention, Coulombic efficiency, homogeneous plating/stripping of Na, and dendrite growth suppression. These separators, which may be extended to other battery systems, are expected to play a significant role in developing sustainable energy storage systems.

Published

2020

199. Towards fast-charging technologies in Li + /Na + storage: from the perspectives of pseudocapacitive materials and non-aqueous hybrid capacitors.

Author

Huang H and Niederberger M

Abstract

Since the discovery of the pseudocapacitive behavior in RuO 2 by Sergio Trasatti and Giovanni Buzzanca in 1971, materials with pseudocapacitance have been regarded as promising candidates for high-power energy storage. Pseudocapacitance-involving energy storage is predominantly based on faradaic redox reactions, but at the same time the charge storage is not limited by solid-state ion diffusion. Besides the search for pseudocapacitive materials, their implementation into non-aqueous hybrid capacitors stands for the strategy to increase power density by a rational design of the battery structure. Composed of a battery-type anode and a capacitor-type cathode, such devices show great promise to integrate the merits of both batteries and capacitors. Today, the availability of fast-charging technologies is of fundamental importance for establishing electric vehicles on a mass scale. Therefore, from the perspective of materials and battery design, understanding the basics and the recent developments of pseudocapacitive materials and non-aqueous hybrid capacitors is of great importance. With this goal in mind, we introduce here the fundamentals of pseudocapacitance and non-aqueous hybrid capacitors. In addition, we provide an overview of the latest developments in this fast growing research field.

Published

2019

200. Fully Integrated Design of a Stretchable Solid-State Lithium-Ion Full Battery.

Author

Chen X, Huang H, Pan L, Liu T, and Niederberger M

Abstract

A solid-state lithium-ion battery, in which all components (current collector, anode and cathode, electrolyte, and packaging) are stretchable, is introduced, giving rise to a battery design with mechanical properties that are compliant with flexible electronic devices and elastic wearable systems. By depositing Ag microflakes as a conductive layer on a stretchable carbon-polymer composite, a current collector with a low sheet resistance of ≈2.7 Ω □ -1 at 100% strain is obtained. Stretchable electrodes are fabricated by integrating active materials with the elastic current collector. A polyacrylamide-"water-in-salt" electrolyte is developed, offering high ionic conductivity of 10 -3 to 10 -2 S cm -1 at room temperature and outstanding stretchability up to ≈300% of its original length. Finally, all these components are assembled into a solid-state lithium-ion full cell in thin-film configuration. Thanks to the deformable individual components, the full cell functions when stretched, bent, or even twisted. For example, after stretching the battery to 50%, a reversible capacity of 28 mAh g -1 and an average energy density of 20 Wh kg -1 can still be obtained after 50 cycles at 120 mA g -1 , confirming the functionality of the battery under extreme mechanical stress., (© 2019 WILEY-VCH Verlag GmbH & Co. KGaA, Weinheim.)

Published

2019