PUMA publications for /tag/propertieshttps://puma.ub.uni-stuttgart.de/tag/propertiesPUMA RSS feed for /tag/properties2024-03-28T14:10:26+01:00Potential of origami-based shell elements as next-generation envelope componentshttps://puma.ub.uni-stuttgart.de/bibtex/20dfb045213232a2162921e36d01a9aa6/jmuellerjmueller2023-11-27T15:10:57+01:00adaptive based ceramics, control controllable crystal devices, direct electrochromic facade films, glass glazed glazing glazing, heat intelligent liquid materials, mechanism, optical optimisation, optimization, performance properties protection, self-adjusting smart sobek solar sunlight sunlight, survey, system system, systems, thermochromic transfer, units, visual windows, <span data-person-type="author" class="authorEditorList "><span><span itemtype="http://schema.org/Person" itemscope="itemscope" itemprop="author"><a title="Yves Klett" itemprop="url" href="/person/101f845c3c121cf815ea4a02f5fee1662/author/0"><span itemprop="name">Y. Klett</span></a></span>, </span><span><span itemtype="http://schema.org/Person" itemscope="itemscope" itemprop="author"><a title="Peter Middendorf" itemprop="url" href="/person/101f845c3c121cf815ea4a02f5fee1662/author/1"><span itemprop="name">P. Middendorf</span></a></span>, </span><span><span itemtype="http://schema.org/Person" itemscope="itemscope" itemprop="author"><a title="Werner Sobek" itemprop="url" href="/person/101f845c3c121cf815ea4a02f5fee1662/author/2"><span itemprop="name">W. Sobek</span></a></span>, </span><span><span itemtype="http://schema.org/Person" itemscope="itemscope" itemprop="author"><a title="Walter Haase" itemprop="url" href="/person/101f845c3c121cf815ea4a02f5fee1662/author/3"><span itemprop="name">W. Haase</span></a></span>, </span> und <span><span itemtype="http://schema.org/Person" itemscope="itemscope" itemprop="author"><a title="Michael Heidingsfeld" itemprop="url" href="/person/101f845c3c121cf815ea4a02f5fee1662/author/4"><span itemprop="name">M. Heidingsfeld</span></a></span></span>. </span><span class="additional-entrytype-information"><span itemtype="http://schema.org/Book" itemscope="itemscope" itemprop="isPartOf"><em><span itemprop="name">2017 IEEE International Conference on Advanced Intelligent Mechatronics (AIM), July 3-7, 2017, Munich</span>, </em></span><em>Seite <span itemprop="pagination">916--920</span>. </em>(<em><span>2017<meta content="2017" itemprop="datePublished"/></span></em>)</span>Mon Nov 27 15:10:57 CET 20232017 {IEEE} {International} {Conference} on {Advanced} {Intelligent} {Mechatronics} ({AIM}), {July} 3-7, 2017, {Munich}916--920Potential of origami-based shell elements as next-generation envelope components2017adaptive based ceramics, control controllable crystal devices, direct electrochromic facade films, glass glazed glazing glazing, heat intelligent liquid materials, mechanism, optical optimisation, optimization, performance properties protection, self-adjusting smart sobek solar sunlight sunlight, survey, system system, systems, thermochromic transfer, units, visual windows, Building envelopes manage several crucial functions,
including structural, thermal, hygric and aesthetic functions.
Classic fac¸ade concepts usually work with static elements like glass, metal or composite panels that primarily provide protection against the elements, and an additional layer of active systems that manage dynamic tasks like light protection or thermal regulation. Kinematic shell elements offer new ways to incorporate multiple dynamic functionalities into cladding
elements, and thus can help to generate new active, efficient and
aesthetic envelopes. We will introduce the concept of origami-inspired
multifunctional shell elements and discuss potential
applications.Adaptive glazing systems - survey of systemshttps://puma.ub.uni-stuttgart.de/bibtex/2b0808e52c918c386f81806471438cd84/jmuellerjmueller2023-11-27T15:10:57+01:00adaptive based ceramics, control controllable crystal devices, direct electrochromic facade films, glass glazed glazing glazing, heat intelligent liquid materials, mechanism, optical optimisation, optimization, performance properties protection, self-adjusting smart sobek solar sunlight sunlight, survey, system system, systems, thermochromic transfer, units, visual windows, <span data-person-type="author" class="authorEditorList "><span><span itemtype="http://schema.org/Person" itemscope="itemscope" itemprop="author"><a title="Walter Haase" itemprop="url" href="/person/18dfb7a35148f9e27aa8e8d039406f7f2/author/0"><span itemprop="name">W. Haase</span></a></span>, </span><span><span itemtype="http://schema.org/Person" itemscope="itemscope" itemprop="author"><a title="Marzena Husser" itemprop="url" href="/person/18dfb7a35148f9e27aa8e8d039406f7f2/author/1"><span itemprop="name">M. Husser</span></a></span>, </span> und <span><span itemtype="http://schema.org/Person" itemscope="itemscope" itemprop="author"><a title="Werner Sobek" itemprop="url" href="/person/18dfb7a35148f9e27aa8e8d039406f7f2/author/2"><span itemprop="name">W. Sobek</span></a></span></span>. </span><span class="additional-entrytype-information"><span itemtype="http://schema.org/Book" itemscope="itemscope" itemprop="isPartOf"><em><span itemprop="name">2017 IEEE International Conference on Advanced Intelligent Mechatronics (AIM), July 3-7, 2017, Munich</span>, </em></span><em>Seite <span itemprop="pagination">929--933</span>. </em>(<em><span>2017<meta content="2017" itemprop="datePublished"/></span></em>)</span>Mon Nov 27 15:10:57 CET 20232017 {IEEE} {International} {Conference} on {Advanced} {Intelligent} {Mechatronics} ({AIM}), {July} 3-7, 2017, {Munich}929--933Adaptive glazing systems - survey of systems2017adaptive based ceramics, control controllable crystal devices, direct electrochromic facade films, glass glazed glazing glazing, heat intelligent liquid materials, mechanism, optical optimisation, optimization, performance properties protection, self-adjusting smart sobek solar sunlight sunlight, survey, system system, systems, thermochromic transfer, units, visual windows, Glazed facade units must satisfy numerous criteria. In addition to allowing an unobstructed view of the exterior they should also provide protection from direct sunlight and the associated heat transfer. In order to optimize the performance of glazed facades under varying conditions, much effort has been directed towards the development of adaptive glazing systems based on smart materials or smart mechanism. This article will outline the functional principles and visual properties of one self-adjusting, thermochromic glazing, two controllable electrochromic systems and one liquid crystal based system.Manufacturing of Hybrid Al-Cu-Heatsinks by Combining Powder Pressing with Thixoforminghttps://puma.ub.uni-stuttgart.de/bibtex/2fc079c77e1819460a59191308fe0150b/roberta.toscanoroberta.toscano2023-09-04T11:41:55+02:00Al-Cu Bodies,Infiltration,Semi-Solid Forming,Thixoforming,abstract,al-cu Heat Metal Sinks,Green allow,infiltration,meet and attention be,semi-solid between bodies,hybrid combined composite forming,single,thixoforming,when functional heat high hybrid,zones in manufacturing material metal metallic must one,component properties requirements,paid sinks,be structures such the thus to to,components,different to,green transition,particular <span data-person-type="author" class="authorEditorList "><span><span itemtype="http://schema.org/Person" itemscope="itemscope" itemprop="author"><a title="Marco Speth" itemprop="url" href="/person/1611d08b634f20eb1f0ccaea848ba8240/author/0"><span itemprop="name">M. Speth</span></a></span>, </span><span><span itemtype="http://schema.org/Person" itemscope="itemscope" itemprop="author"><a title="Mathias Liewald" itemprop="url" href="/person/1611d08b634f20eb1f0ccaea848ba8240/author/1"><span itemprop="name">M. Liewald</span></a></span>, </span><span><span itemtype="http://schema.org/Person" itemscope="itemscope" itemprop="author"><a title="Kim Rouven Riedmüller" itemprop="url" href="/person/1611d08b634f20eb1f0ccaea848ba8240/author/2"><span itemprop="name">K. Riedmüller</span></a></span>, </span> und <span><span itemtype="http://schema.org/Person" itemscope="itemscope" itemprop="author"><a title="Laura Schomer" itemprop="url" href="/person/1611d08b634f20eb1f0ccaea848ba8240/author/3"><span itemprop="name">L. Schomer</span></a></span></span>. </span><span class="additional-entrytype-information"><span itemtype="http://schema.org/PublicationIssue" itemscope="itemscope" itemprop="isPartOf"><em><span itemprop="journal">Solid State Phenomena</span>, </em> </span>(<em><span>Januar 2022<meta content="Januar 2022" itemprop="datePublished"/></span></em>)</span>Mon Sep 04 11:41:55 CEST 2023Solid State Phenomenajan231--237{Manufacturing of Hybrid Al-Cu-Heatsinks by Combining Powder Pressing with Thixoforming}3272022Al-Cu Bodies,Infiltration,Semi-Solid Forming,Thixoforming,abstract,al-cu Heat Metal Sinks,Green allow,infiltration,meet and attention be,semi-solid between bodies,hybrid combined composite forming,single,thixoforming,when functional heat high hybrid,zones in manufacturing material metal metallic must one,component properties requirements,paid sinks,be structures such the thus to to,components,different to,green transition,particular Hybrid material structures allow different material properties to be combined in one single component and thus to meet high functional requirements. When manufacturing such hybrid components, particular attention must be paid to the transition zones between metallic composite partners. These transition zones need to show largely homogeneous and materially bonded structures in order to ensure ideal transmission of the material properties and to prevent component failure due to material defects. In this respect, this paper focuses on a newly developed process in which a powder metallurgical route is combined with semi-solid forming technology. Here, porous copper green bodies are inserted into a forming die and subsequently forged together with a semi-solid aluminium alloy. In this way, it was tried to combine both metal materials into a material locking or at least into a form locking manner in order to achieve ideal material properties in the final hybrid component. The aim of this paper is to find suitable process parameters to infiltrate the porous copper inlay with the semi-solid aluminium alloy during thixoforming. Therefore, different process parameters such as varying liquid fraction of the aluminium alloy and different densities of the green bodies were examined during the production of simply shaped hybrid Al-Cu-components. Afterwards the infiltration depth and produced microstructure of the components was analysed. In the future, this process allows for producing aluminium-copper hybrid heat sinks with improved heat transfer properties compared to conventional produced heat sinks.Modifying Mechanical Properties of Sheet Metal Materials by Work Hardening Mechanisms Induced via Selective Embossinghttps://puma.ub.uni-stuttgart.de/bibtex/2dc2e72620c7aed93e1afc7bd99c77625/roxyfoxy2211roxyfoxy22112023-08-01T10:28:49+02:00embossing mechanical metal properties selective sheet <span data-person-type="author" class="authorEditorList "><span><span itemtype="http://schema.org/Person" itemscope="itemscope" itemprop="author"><a title="P. Heinzelmann" itemprop="url" href="/person/1aa1a038ff0078aaa0c1ab09bb427b2d8/author/0"><span itemprop="name">P. Heinzelmann</span></a></span>, </span><span><span itemtype="http://schema.org/Person" itemscope="itemscope" itemprop="author"><a title="D. Briesenick" itemprop="url" href="/person/1aa1a038ff0078aaa0c1ab09bb427b2d8/author/1"><span itemprop="name">D. Briesenick</span></a></span>, </span> und <span><span itemtype="http://schema.org/Person" itemscope="itemscope" itemprop="author"><a title="M. Liewald" itemprop="url" href="/person/1aa1a038ff0078aaa0c1ab09bb427b2d8/author/2"><span itemprop="name">M. Liewald</span></a></span></span>. </span><span class="additional-entrytype-information"><span itemtype="http://schema.org/Book" itemscope="itemscope" itemprop="isPartOf"></span>(<em><span>2023<meta content="2023" itemprop="datePublished"/></span></em>)</span>Tue Aug 01 10:28:49 CEST 2023Modifying Mechanical Properties of Sheet Metal Materials by Work Hardening Mechanisms Induced via Selective Embossing2023embossing mechanical metal properties selective sheet Muscle preflex response to perturbations in locomotion: In vitro experiments and simulations with realistic boundary conditionshttps://puma.ub.uni-stuttgart.de/bibtex/20b8a2822ba7baaca10669289c107bd9c/inspo5inspo52023-05-16T10:24:04+02:00damping dynamics intrinsic mechanical muscle properties stiffness work <span data-person-type="editor" class="authorEditorList "><span><span itemtype="http://schema.org/Person" itemscope="itemscope" itemprop="editor"><a title="Tobias Siebert" itemprop="url" href="/person/1a826d07e2f8c83bb1b8a903cbbcccde6/editor/0"><span itemprop="name">T. Siebert</span></a></span></span> (Hrsg.) </span><span class="additional-entrytype-information"><span itemtype="http://schema.org/PublicationIssue" itemscope="itemscope" itemprop="isPartOf"><em><span itemprop="journal">Frontiers in Bioengineering and Biotechnology</span>, </em> </span>(<em><span>April 2023<meta content="April 2023" itemprop="datePublished"/></span></em>)</span>Tue May 16 10:24:04 CEST 2023Frontiers in Bioengineering and BiotechnologyAprilMuscle preflex response to perturbations in locomotion: In vitro experiments and simulations with realistic boundary conditions112023damping dynamics intrinsic mechanical muscle properties stiffness work Musculoskeletal disorders (MSD) are a widespread problem, often regarding the lumbar region. Exoskeletons designed to support the lower back could be used in physically demanding professions with the intention of reducing the strain on the musculoskeletal system, e.g., by lowering task-related muscle activation. The present study aims to investigate the effect of an active exoskeleton on back muscle activity when lifting weights. Within the framework of the study, 14 subjects were asked to lift a 15 kg box with and without an active exoskeleton which allows the adjustment of different levels of support, while the activity of their M. erector spinae (MES) was measured using surface electromyography. Additionally, the subjects were asked about their overall rating of perceived exertion (RPE) during lifting under various conditions. Using the exoskeleton with the maximum level of support, the muscle activity was significantly lower than without exoskeleton. A significant correlation was found between the exoskeleton’s support level and the reduction of MES activity. The higher the support level, the lower the observed muscle activity. Furthermore, when lifting with the maximum level of support, RPE was found to be significantly lower than without exoskeleton too. A reduction in the MES activity indicates actual support for the movement task and might indicate lower compression forces in the lumbar region. It is concluded that the active exoskeleton supports people noticeably when lifting heavy weights. Exoskeletons seem to be a powerful tool for reducing load during physically demanding jobs and thus, their use might be helpful in lowering the risk of MSD.On qualitative properties of solutions to microelectromechanical systems with general permittivityhttps://puma.ub.uni-stuttgart.de/bibtex/2529e2a96561412f7c16f2c7875622058/elkepeterelkepeter2023-03-27T11:14:19+02:00IADM Lienstromberg microelectromechanical of properties qualitative solutions systems to <span data-person-type="author" class="authorEditorList "><span><span itemtype="http://schema.org/Person" itemscope="itemscope" itemprop="author"><a title="Christina Lienstromberg" itemprop="url" href="/person/1462824bdb76c7d72e72898a1d2d0dc02/author/0"><span itemprop="name">C. Lienstromberg</span></a></span></span>. </span><span class="additional-entrytype-information"><span itemtype="http://schema.org/PublicationIssue" itemscope="itemscope" itemprop="isPartOf"><em><span itemprop="journal">Monatsh. Math.</span>, </em> <em><span itemtype="http://schema.org/PublicationVolume" itemscope="itemscope" itemprop="isPartOf"><span itemprop="volumeNumber">179 </span></span>(<span itemprop="issueNumber">4</span>):
<span itemprop="pagination">581--602</span></em> </span>(<em><span>2016<meta content="2016" itemprop="datePublished"/></span></em>)</span>Mon Mar 27 11:14:19 CEST 2023Monatsh. Math.4581--602On qualitative properties of solutions to microelectromechanical systems with general permittivity1792016IADM Lienstromberg microelectromechanical of properties qualitative solutions systems to "Qualitative properties of solutions to the evolution problem modelling microelectromechanical systems with general permittivity profile are investigated. The system couples a parabolic evolution problem for the displacement of a membrane with an elliptic free boundary value problem for the electric potential in the region between the membrane and a rigid ground plate. We briefly allude to results concerning local and global well-posedness and the small-apect ratio limit. However, the focus is here on proving non-positivity of the membrane displacement for the full moving boundary problem under certain boundary conditions on the potential, as well as the existence of finite-time singularities assuming to have a non-positive solution.''On qualitative properties of solutions to
microelectromechanical systems with general permittivityhttps://puma.ub.uni-stuttgart.de/bibtex/2529e2a96561412f7c16f2c7875622058/mathematikmathematik2023-03-27T11:14:19+02:00IADM microelectromechanical solutions Lienstromberg systems qualitative from:elkepeter of to properties <span data-person-type="author" class="authorEditorList "><span><span itemtype="http://schema.org/Person" itemscope="itemscope" itemprop="author"><a title="Christina Lienstromberg" itemprop="url" href="/person/1462824bdb76c7d72e72898a1d2d0dc02/author/0"><span itemprop="name">C. Lienstromberg</span></a></span></span>. </span><span class="additional-entrytype-information"><span itemtype="http://schema.org/PublicationIssue" itemscope="itemscope" itemprop="isPartOf"><em><span itemprop="journal">Monatsh. Math.</span>, </em> <em><span itemtype="http://schema.org/PublicationVolume" itemscope="itemscope" itemprop="isPartOf"><span itemprop="volumeNumber">179 </span></span>(<span itemprop="issueNumber">4</span>):
<span itemprop="pagination">581--602</span></em> </span>(<em><span>2016<meta content="2016" itemprop="datePublished"/></span></em>)</span>Mon Mar 27 11:14:19 CEST 2023Monatsh. Math.4581--602On qualitative properties of solutions to
microelectromechanical systems with general permittivity1792016IADM microelectromechanical solutions Lienstromberg systems qualitative from:elkepeter of to properties "Qualitative properties of solutions to the evolution problem modelling microelectromechanical systems with general permittivity profile are investigated. The system couples a parabolic evolution problem for the displacement of a membrane with an elliptic free boundary value problem for the electric potential in the region between the membrane and a rigid ground plate. We briefly allude to results concerning local and global well-posedness and the small-apect ratio limit. However, the focus is here on proving non-positivity of the membrane displacement for the full moving boundary problem under certain boundary conditions on the potential, as well as the existence of finite-time singularities assuming to have a non-positive solution.''Tuning the Hardness of Produced Parts by Adjusting the Cooling Rate during Laser-Based Powder Bed Fusion of AlSi10Mg by Adapting the Process Parametershttps://puma.ub.uni-stuttgart.de/bibtex/2471e161c0c8a113b483881e2008cbb3e/ifswifsw2022-11-23T08:37:45+01:00myown IFSW hardness laser lpbf peer additivemanufacturing AlSi10Mg from:arturleis properties <span data-person-type="author" class="authorEditorList "><span><span itemtype="http://schema.org/Person" itemscope="itemscope" itemprop="author"><a title="Artur Leis" itemprop="url" href="/person/17c9774d7187fbc90a13c7ca5ece956bd/author/0"><span itemprop="name">A. Leis</span></a></span>, </span><span><span itemtype="http://schema.org/Person" itemscope="itemscope" itemprop="author"><a title="David Traunecker" itemprop="url" href="/person/17c9774d7187fbc90a13c7ca5ece956bd/author/1"><span itemprop="name">D. Traunecker</span></a></span>, </span><span><span itemtype="http://schema.org/Person" itemscope="itemscope" itemprop="author"><a title="Rudolf Weber" itemprop="url" href="/person/17c9774d7187fbc90a13c7ca5ece956bd/author/2"><span itemprop="name">R. Weber</span></a></span>, </span> und <span><span itemtype="http://schema.org/Person" itemscope="itemscope" itemprop="author"><a title="Thomas Graf" itemprop="url" href="/person/17c9774d7187fbc90a13c7ca5ece956bd/author/3"><span itemprop="name">T. Graf</span></a></span></span>. </span><span class="additional-entrytype-information"><span itemtype="http://schema.org/PublicationIssue" itemscope="itemscope" itemprop="isPartOf"><em><span itemprop="journal">Metals</span>, </em> </span>(<em><span>2022<meta content="2022" itemprop="datePublished"/></span></em>)</span>Wed Nov 23 08:37:45 CET 2022Metals12Tuning the Hardness of Produced Parts by Adjusting the Cooling Rate during Laser-Based Powder Bed Fusion of AlSi10Mg by Adapting the Process Parameters122022myown IFSW hardness laser lpbf peer additivemanufacturing AlSi10Mg from:arturleis properties The mechanical properties of parts produced by laser-based powder bed fusion (LPBF) are mainly determined by the grain structure in the material, which is governed by the cooling rate during solidification. This cooling rate strongly depends on the scan velocity and the absorbed laser power. Experiments with varying process parameters were performed to develop and validate an analytical model that predicts the hardness of printed AlSi10Mg parts. It was found that it is possible to tune the hardness of additively manufactured parts of AlSi10Mg in a range between 60 ± 9 HV0.5 and 100 ± 10 HV0.5 by adjusting the cooling rate during solidification with adapted process parameters.Tuning the Hardness of Produced Parts by Adjusting the Cooling Rate during Laser-Based Powder Bed Fusion of AlSi10Mg by Adapting the Process Parametershttps://puma.ub.uni-stuttgart.de/bibtex/2471e161c0c8a113b483881e2008cbb3e/arturleisarturleis2022-11-23T08:35:24+01:00AlSi10Mg IFSW additivemanufacturing hardness laser lpbf myown peer properties <span data-person-type="author" class="authorEditorList "><span><span itemtype="http://schema.org/Person" itemscope="itemscope" itemprop="author"><a title="Artur Leis" itemprop="url" href="/person/17c9774d7187fbc90a13c7ca5ece956bd/author/0"><span itemprop="name">A. Leis</span></a></span>, </span><span><span itemtype="http://schema.org/Person" itemscope="itemscope" itemprop="author"><a title="David Traunecker" itemprop="url" href="/person/17c9774d7187fbc90a13c7ca5ece956bd/author/1"><span itemprop="name">D. Traunecker</span></a></span>, </span><span><span itemtype="http://schema.org/Person" itemscope="itemscope" itemprop="author"><a title="Rudolf Weber" itemprop="url" href="/person/17c9774d7187fbc90a13c7ca5ece956bd/author/2"><span itemprop="name">R. Weber</span></a></span>, </span> und <span><span itemtype="http://schema.org/Person" itemscope="itemscope" itemprop="author"><a title="Thomas Graf" itemprop="url" href="/person/17c9774d7187fbc90a13c7ca5ece956bd/author/3"><span itemprop="name">T. Graf</span></a></span></span>. </span><span class="additional-entrytype-information"><span itemtype="http://schema.org/PublicationIssue" itemscope="itemscope" itemprop="isPartOf"><em><span itemprop="journal">Metals</span>, </em> </span>(<em><span>2022<meta content="2022" itemprop="datePublished"/></span></em>)</span>Wed Nov 23 08:35:24 CET 2022Metals12Tuning the Hardness of Produced Parts by Adjusting the Cooling Rate during Laser-Based Powder Bed Fusion of AlSi10Mg by Adapting the Process Parameters122022AlSi10Mg IFSW additivemanufacturing hardness laser lpbf myown peer properties The mechanical properties of parts produced by laser-based powder bed fusion (LPBF) are mainly determined by the grain structure in the material, which is governed by the cooling rate during solidification. This cooling rate strongly depends on the scan velocity and the absorbed laser power. Experiments with varying process parameters were performed to develop and validate an analytical model that predicts the hardness of printed AlSi10Mg parts. It was found that it is possible to tune the hardness of additively manufactured parts of AlSi10Mg in a range between 60 ± 9 HV0.5 and 100 ± 10 HV0.5 by adjusting the cooling rate during solidification with adapted process parameters.Porcine Stomach Smooth Muscle Force Depends on History-Effectshttps://puma.ub.uni-stuttgart.de/bibtex/2c5478835f2cd88ec490ace0e656a5b8f/inspo5inspo52022-07-19T11:10:29+02:00contraction-behavior depression enhancement force force-length force-velocity gastric motility muscle properties relation smooth tissue <span data-person-type="author" class="authorEditorList "><span><span itemtype="http://schema.org/Person" itemscope="itemscope" itemprop="author"><a title="A. Tomalka" itemprop="url" href="/person/1a5eeda529640c3525644d1772eb0cba6/author/0"><span itemprop="name">A. Tomalka</span></a></span>, </span><span><span itemtype="http://schema.org/Person" itemscope="itemscope" itemprop="author"><a title="M. Borsdorf" itemprop="url" href="/person/1a5eeda529640c3525644d1772eb0cba6/author/1"><span itemprop="name">M. Borsdorf</span></a></span>, </span><span><span itemtype="http://schema.org/Person" itemscope="itemscope" itemprop="author"><a title="M. Böl" itemprop="url" href="/person/1a5eeda529640c3525644d1772eb0cba6/author/2"><span itemprop="name">M. Böl</span></a></span>, </span> und <span><span itemtype="http://schema.org/Person" itemscope="itemscope" itemprop="author"><a title="T. Siebert" itemprop="url" href="/person/1a5eeda529640c3525644d1772eb0cba6/author/3"><span itemprop="name">T. Siebert</span></a></span></span>. </span><span class="additional-entrytype-information"><span itemtype="http://schema.org/PublicationIssue" itemscope="itemscope" itemprop="isPartOf"><em><span itemprop="journal">Front Physiol</span>, </em> </span>(<em><span>2017<meta content="2017" itemprop="datePublished"/></span></em>)</span>Tue Jul 19 11:10:29 CEST 2022Front Physiol802Porcine Stomach Smooth Muscle Force Depends on History-EffectsJournal Article82017contraction-behavior depression enhancement force force-length force-velocity gastric motility muscle properties relation smooth tissue The stomach serves as food reservoir, mixing organ and absorption area for certain substances, while continually varying its position and size. Large dimensional changes during ingestion and gastric emptying of the stomach are associated with large changes in smooth muscle length. These length changes might induce history-effects, namely force depression (FD) following active muscle shortening and force enhancement (FE) following active muscle stretch. Both effects have impact on the force generating capacity of the stomach, and thus functional relevance. However, less is known about history-effects and active smooth muscle properties of stomach smooth muscle. Thus, the aim of this study was to investigate biomechanical muscle properties as force-length and force-velocity relations (FVR) of porcine stomach smooth muscle strips, extended by the analysis of history-effects on smooth muscle force. Therefore, in total n = 54 tissue strips were dissected in longitudinal direction from the ventral fundus of porcine stomachs. Different isometric, isotonic, and isokinetic contraction protocols were performed during electrical muscle stimulation. Cross-sectional areas (CSA) of smooth muscles were determined from cryo-histological sections stained with Picrosirius Red. Results revealed that maximum smooth muscle tension was 10.4 ± 2.6 N/cm2. Maximum shortening velocity (Vmax ) and curvature factor (curv) of the FVR were 0.04 ± 0.01 [optimum muscle length/s] and 0.36 ± 0.15, respectively. The findings of the present study demonstrated significant (P < 0.05) FD [up to 32% maximum muscle force (Fim )] and FE (up to 16% Fim ) of gastric muscle tissue, respectively. The FE- and FD-values increased with increasing ramp amplitude. This outstanding muscle behavior is not accounted for in existing models so far and strongly supports the idea of a holistic reflection of distinct stomach structure and function. For the first time this study provides a comprehensive set of stomach smooth muscle parameters including classic biomechanical muscle properties and history-dependent effects, offering the possibility for the development and validation of computational stomach models. Furthermore, this data set facilitates novel insights in gastric motility and contraction behavior based on the re-evaluation of existing contractile mechanisms. That will likely help to understand physiological functions or dysfunctions in terms of gastric accommodation and emptying.Age-dependent mechanical and microstructural properties of the rabbit soleus musclehttps://puma.ub.uni-stuttgart.de/bibtex/20e9dbe076502380e2b8e70a80da95818/inspo5inspo52022-07-19T11:10:29+02:00Age-dependent Axial Inspo Microstructural Morphometry Oryctolagus Semi-confined Siebert Soleus characteristics compression cuniculus muscle properties tests tissue <span data-person-type="author" class="authorEditorList "><span><span itemtype="http://schema.org/Person" itemscope="itemscope" itemprop="author"><a title="Kay Leichsenring" itemprop="url" href="/person/16afbb85807dbc73f3599b68ac7ec0018/author/0"><span itemprop="name">K. Leichsenring</span></a></span>, </span><span><span itemtype="http://schema.org/Person" itemscope="itemscope" itemprop="author"><a title="Asha Viswanathan" itemprop="url" href="/person/16afbb85807dbc73f3599b68ac7ec0018/author/1"><span itemprop="name">A. Viswanathan</span></a></span>, </span><span><span itemtype="http://schema.org/Person" itemscope="itemscope" itemprop="author"><a title="Steven Kutschke" itemprop="url" href="/person/16afbb85807dbc73f3599b68ac7ec0018/author/2"><span itemprop="name">S. Kutschke</span></a></span>, </span> und <span><span itemtype="http://schema.org/Person" itemscope="itemscope" itemprop="author"><a title="Markus Siebert, TobiasBöl" itemprop="url" href="/person/16afbb85807dbc73f3599b68ac7ec0018/author/3"><span itemprop="name">M. Siebert, TobiasBöl</span></a></span></span>. </span><span class="additional-entrytype-information"><span itemtype="http://schema.org/PublicationIssue" itemscope="itemscope" itemprop="isPartOf"><em><span itemprop="journal">Acta Biomaterialia</span>, </em> </span>(<em><span>Oktober 2021<meta content="Oktober 2021" itemprop="datePublished"/></span></em>)</span>Tue Jul 19 11:10:29 CEST 2022Acta Biomaterialiaoct453--465Age-dependent mechanical and microstructural properties of the rabbit soleus muscle1342021Age-dependent Axial Inspo Microstructural Morphometry Oryctolagus Semi-confined Siebert Soleus characteristics compression cuniculus muscle properties tests tissue During growth there are serious changes in the skeletal muscles to compensate for the changed requirements in terms of body weight and size. In this study, the age-dependent (between 21 and 100 days) mechanical and microstructural properties of rabbit soleus muscle tissue were investigated. For this purpose, morphological properties (animal mass, soleus muscle mass, tibial length) were measured at 5 different times during aging. On the other hand, fibre orientation-dependent axial and semi-confined compression experiments were realised. In addition, the essential components (muscle fibres, extracellular matrix, remaining components), dominating the microstructure of muscle tissue, were analysed. While the mechanical results show hardly any age-dependent differences, the morphological and microstructural results show clear age-dependent differences. All morphological parameters increase significantly (animal mass by 839.2%, muscle mass 1050.6%, tibial length 233.6%). In contrast, microstructural parameters change differently. The percentage of fibres (divided into slow-twitch (ST) and fast-twitch (FT) fibres) increases significantly (137.6%), while the proportions of the extracellular matrix and the remaining components (48.2% and 46.1%) decrease. At the same time, the cross-sectional area of the fibres increases significantly (697.9%). The totality of this age-dependent information provides a deeper understanding of age-related changes in muscle structure and function and may contribute to successful development and validation of growth models in the future.
Statement of significance
This article reports the first comprehensive data set on age-dependent morphological (animal mass, soleus muscle mass, tibial length), mechanical (axial and semi-confined compression), and microstructural (muscle fibres, extracellular matrix, remaining components) properties of the rabbit soleus muscle. On the one hand, the results of this study contribute to the understanding of muscle mechanics and thus to understanding of load transfer mechanisms inside the muscle tissue during growth. On the other hand, these results are relevant to the fields of constitutive formulation of age-dependent muscle tissue.Influence of layer separation on the determination of stomach smooth muscle properties.https://puma.ub.uni-stuttgart.de/bibtex/2f3d78410850201349b3420cb0f71115a/inspo5inspo52022-07-19T11:10:29+02:00Contractile Force Organ Separated Stomach Uniaxial experiments layer length muscle properties relationship tensile velocity wall <span data-person-type="author" class="authorEditorList "><span><span itemtype="http://schema.org/Person" itemscope="itemscope" itemprop="author"><a title="Mischa Borsdorf" itemprop="url" href="/person/1b79cfd3a81cd8360cba0a6d4729f7452/author/0"><span itemprop="name">M. Borsdorf</span></a></span>, </span><span><span itemtype="http://schema.org/Person" itemscope="itemscope" itemprop="author"><a title="Markus Böl" itemprop="url" href="/person/1b79cfd3a81cd8360cba0a6d4729f7452/author/1"><span itemprop="name">M. Böl</span></a></span>, </span> und <span><span itemtype="http://schema.org/Person" itemscope="itemscope" itemprop="author"><a title="Tobias Siebert" itemprop="url" href="/person/1b79cfd3a81cd8360cba0a6d4729f7452/author/2"><span itemprop="name">T. Siebert</span></a></span></span>. </span><span class="additional-entrytype-information"><span itemtype="http://schema.org/PublicationIssue" itemscope="itemscope" itemprop="isPartOf"><em><span itemprop="journal">Pflugers Arch</span>, </em> </span>(<em><span>Juni 2021<meta content="Juni 2021" itemprop="datePublished"/></span></em>)</span>Tue Jul 19 11:10:29 CEST 2022Pflugers ArchJune911-920Influence of layer separation on the determination of stomach smooth muscle properties.4732021Contractile Force Organ Separated Stomach Uniaxial experiments layer length muscle properties relationship tensile velocity wall Uniaxial tensile experiments are a standard method to determine the contractile properties of smooth muscles. Smooth muscle strips from organs of the urogenital and gastrointestinal tract contain multiple muscle layers with different muscle fiber orientations, which are frequently not separated for the experiments. During strip activation, these muscle fibers contract in deviant orientations from the force-measuring axis, affecting the biomechanical characteristics of the tissue strips. This study aimed to investigate the influence of muscle layer separation on the determination of smooth muscle properties. Smooth muscle strips, consisting of longitudinal and circumferential muscle layers (whole-muscle strips [WMS]), and smooth muscle strips, consisting of only the circumferential muscle layer (separated layer strips [SLS]), have been prepared from the fundus of the porcine stomach. Strips were mounted with muscle fibers of the circumferential layer inline with the force-measuring axis of the uniaxial testing setup. The force–length (FLR) and force–velocity relationships (FVR) were determined through a series of isometric and isotonic contractions, respectively. Muscle layer separation revealed no changes in the FLR. However, the SLS exhibited a higher maximal shortening velocity and a lower curvature factor than WMS. During WMS activation, the transversally oriented muscle fibers of the longitudinal layer shortened, resulting in a narrowing of this layer. Expecting volume constancy of muscle tissue, this narrowing leads to a lengthening of the longitudinal layer, which counteracted the shortening of the circumferential layer during isotonic contractions. Consequently, the shortening velocities of the WMS were decreased significantly. This effect was stronger at high shortening velocities.From Understanding Mechanical Behavior to Curvature Prediction of Humidity-Triggered Bilayer Actuatorshttps://puma.ub.uni-stuttgart.de/bibtex/242cac9d2ba4a425519eb806b878a44a6/dominikfauserdominikfauser2021-10-13T14:11:25+02:00PEDOT:PSS actuators bilayer curvature humidity mechanical myown prediction properties trigger <span data-person-type="author" class="authorEditorList "><span><span itemtype="http://schema.org/Person" itemscope="itemscope" itemprop="author"><a title="Carsten Dingler" itemprop="url" href="/person/1800a1c06e05de15500674bb2eda638b7/author/0"><span itemprop="name">C. Dingler</span></a></span>, </span><span><span itemtype="http://schema.org/Person" itemscope="itemscope" itemprop="author"><a title="Henry Müller" itemprop="url" href="/person/1800a1c06e05de15500674bb2eda638b7/author/1"><span itemprop="name">H. Müller</span></a></span>, </span><span><span itemtype="http://schema.org/Person" itemscope="itemscope" itemprop="author"><a title="Matthias Wieland" itemprop="url" href="/person/1800a1c06e05de15500674bb2eda638b7/author/2"><span itemprop="name">M. Wieland</span></a></span>, </span><span><span itemtype="http://schema.org/Person" itemscope="itemscope" itemprop="author"><a title="Dominik Fauser" itemprop="url" href="/person/1800a1c06e05de15500674bb2eda638b7/author/3"><span itemprop="name">D. Fauser</span></a></span>, </span><span><span itemtype="http://schema.org/Person" itemscope="itemscope" itemprop="author"><a title="Holger Steeb" itemprop="url" href="/person/1800a1c06e05de15500674bb2eda638b7/author/4"><span itemprop="name">H. Steeb</span></a></span>, </span> und <span><span itemtype="http://schema.org/Person" itemscope="itemscope" itemprop="author"><a title="Sabine Ludwigs" itemprop="url" href="/person/1800a1c06e05de15500674bb2eda638b7/author/5"><span itemprop="name">S. Ludwigs</span></a></span></span>. </span><span class="additional-entrytype-information"><span itemtype="http://schema.org/PublicationIssue" itemscope="itemscope" itemprop="isPartOf"><em><span itemprop="journal">Advanced Materials</span>, </em> <em><span itemtype="http://schema.org/PublicationVolume" itemscope="itemscope" itemprop="isPartOf"><span itemprop="volumeNumber">33 </span></span>(<span itemprop="issueNumber">9</span>):
<span itemprop="pagination">2007982</span></em> </span>(<em><span>2021<meta content="2021" itemprop="datePublished"/></span></em>)</span>Wed Oct 13 14:11:25 CEST 2021Advanced Materials92007982From Understanding Mechanical Behavior to Curvature Prediction of Humidity-Triggered Bilayer Actuators332021PEDOT:PSS actuators bilayer curvature humidity mechanical myown prediction properties trigger Abstract Nature will always be an endless source of bioinspiration for man-made smart materials and multifunctional devices. Impressively, even cutoff leaves from resurrection plants can autonomously and reproducibly change their shape upon humidity changes, which goes along with total recovery of their mechanical properties after being completely dried. In this work, simple bilayers are presented as autonomously moving, humidity-triggered bending actuators. The bilayers—showing reproducible bending behavior with reversible kinematics and multiway behavior—are studied in terms of their mechanical behavior upon humidity changes. The active layer consists of a highly conducting polymer film based on poly(3,4-ethylenedioxythiophene):poly(styrene sulfonate) (PEDOT:PSS) with poly(dimethylsiloxane) (PDMS) as passive layer. The response to humidity is explored with dynamic mechanical thermal analysis and quartz crystal microbalance measurements. Introduction of a composite beam model allows to predict the curvature of the actuators with input from the rheological measurements. It is clearly demonstrated that volumetric strain and Young's modulus, both heavily influenced by the water uptake, dominate the bending behavior and therefore the curvature of the actuators. This loop of rheological characterization coupled with an analytical model allows to predict curvatures of in principle any complex geometry and material combination for moving parts in soft robotics.Material Behaviour: Embedding Physical Properties in Computational Design Processeshttps://puma.ub.uni-stuttgart.de/bibtex/27c25ceb2916d0d4d68004431d4f5ddc7/itkeitke2020-05-22T14:26:20+02:002012 architecture behaviour computational design embedding fleischmann from:petraheim itke knippers lienhard material menges physical process properties robotic schleicher <span data-person-type="author" class="authorEditorList "><span><span itemtype="http://schema.org/Person" itemscope="itemscope" itemprop="author"><a title="M. Fleischmann" itemprop="url" href="/person/17e43b49bdb7013207663634d1bcbef83/author/0"><span itemprop="name">M. Fleischmann</span></a></span>, </span><span><span itemtype="http://schema.org/Person" itemscope="itemscope" itemprop="author"><a title="Jan Knippers" itemprop="url" href="/person/17e43b49bdb7013207663634d1bcbef83/author/1"><span itemprop="name">J. Knippers</span></a></span>, </span><span><span itemtype="http://schema.org/Person" itemscope="itemscope" itemprop="author"><a title="Julian Lienhard" itemprop="url" href="/person/17e43b49bdb7013207663634d1bcbef83/author/2"><span itemprop="name">J. Lienhard</span></a></span>, </span><span><span itemtype="http://schema.org/Person" itemscope="itemscope" itemprop="author"><a title="Achim Menges" itemprop="url" href="/person/17e43b49bdb7013207663634d1bcbef83/author/3"><span itemprop="name">A. Menges</span></a></span>, </span> und <span><span itemtype="http://schema.org/Person" itemscope="itemscope" itemprop="author"><a title="Simon Schleicher" itemprop="url" href="/person/17e43b49bdb7013207663634d1bcbef83/author/4"><span itemprop="name">S. Schleicher</span></a></span></span>. </span><span class="additional-entrytype-information"><span itemtype="http://schema.org/PublicationIssue" itemscope="itemscope" itemprop="isPartOf"><em><span itemprop="journal">Architectural Design</span>, </em> <em><span itemtype="http://schema.org/PublicationVolume" itemscope="itemscope" itemprop="isPartOf"><span itemprop="volumeNumber">Vol. 82 </span></span>(<span itemprop="issueNumber">No. 2</span>):
<span itemprop="pagination">44 – 51</span></em> </span>(<em><span>2012<meta content="2012" itemprop="datePublished"/></span></em>)</span>Fri May 22 14:26:20 CEST 2020 Architectural DesignNo. 244 – 51Material Behaviour: Embedding Physical Properties in Computational Design ProcessesVol. 82 20122012 architecture behaviour computational design embedding fleischmann from:petraheim itke knippers lienhard material menges physical process properties robotic schleicher Material behaviour computes form. In the physical world, material form is always inseparably connected to internal constraints and external forces; in the virtual space of digital design, though, form and force are usually treated as separate entities – divided into processes of geometric form generation and subsequent engineering simulation. Using the example of the interdisciplinary ICD/ITKE Research Pavilion, constructed at the University of Stuttgart in 2010, Moritz Fleischmann, Jan Knippers, Julian Lienhard, Achim Menges and Simon Schleicher explain how feedback between computational design, advanced simulation and robotic fabrication expands the design space towards previously unexplored architectural possibilities.Material Behaviour: Embedding Physical Properties in Computational Design Processeshttps://puma.ub.uni-stuttgart.de/bibtex/27c25ceb2916d0d4d68004431d4f5ddc7/petraheimpetraheim2020-05-13T13:49:37+02:002012 architecture behaviour computational design embedding fleischmann itke knippers lienhard material menges physical process properties robotic schleicher <span data-person-type="author" class="authorEditorList "><span><span itemtype="http://schema.org/Person" itemscope="itemscope" itemprop="author"><a title="M. Fleischmann" itemprop="url" href="/person/17e43b49bdb7013207663634d1bcbef83/author/0"><span itemprop="name">M. Fleischmann</span></a></span>, </span><span><span itemtype="http://schema.org/Person" itemscope="itemscope" itemprop="author"><a title="Jan Knippers" itemprop="url" href="/person/17e43b49bdb7013207663634d1bcbef83/author/1"><span itemprop="name">J. Knippers</span></a></span>, </span><span><span itemtype="http://schema.org/Person" itemscope="itemscope" itemprop="author"><a title="Julian Lienhard" itemprop="url" href="/person/17e43b49bdb7013207663634d1bcbef83/author/2"><span itemprop="name">J. Lienhard</span></a></span>, </span><span><span itemtype="http://schema.org/Person" itemscope="itemscope" itemprop="author"><a title="Achim Menges" itemprop="url" href="/person/17e43b49bdb7013207663634d1bcbef83/author/3"><span itemprop="name">A. Menges</span></a></span>, </span> und <span><span itemtype="http://schema.org/Person" itemscope="itemscope" itemprop="author"><a title="Simon Schleicher" itemprop="url" href="/person/17e43b49bdb7013207663634d1bcbef83/author/4"><span itemprop="name">S. Schleicher</span></a></span></span>. </span><span class="additional-entrytype-information"><span itemtype="http://schema.org/PublicationIssue" itemscope="itemscope" itemprop="isPartOf"><em><span itemprop="journal">Architectural Design</span>, </em> <em><span itemtype="http://schema.org/PublicationVolume" itemscope="itemscope" itemprop="isPartOf"><span itemprop="volumeNumber">Vol. 82 </span></span>(<span itemprop="issueNumber">No. 2</span>):
<span itemprop="pagination">44 – 51</span></em> </span>(<em><span>2012<meta content="2012" itemprop="datePublished"/></span></em>)</span>Wed May 13 13:49:37 CEST 2020 Architectural DesignNo. 244 – 51Material Behaviour: Embedding Physical Properties in Computational Design ProcessesVol. 82 20122012 architecture behaviour computational design embedding fleischmann itke knippers lienhard material menges physical process properties robotic schleicher Material behaviour computes form. In the physical world, material form is always inseparably connected to internal constraints and external forces; in the virtual space of digital design, though, form and force are usually treated as separate entities – divided into processes of geometric form generation and subsequent engineering simulation. Using the example of the interdisciplinary ICD/ITKE Research Pavilion, constructed at the University of Stuttgart in 2010, Moritz Fleischmann, Jan Knippers, Julian Lienhard, Achim Menges and Simon Schleicher explain how feedback between computational design, advanced simulation and robotic fabrication expands the design space towards previously unexplored architectural possibilities.Experimental Study on Vegetable and Mineral Transformer Oils Propertieshttps://puma.ub.uni-stuttgart.de/bibtex/29fa191bbd5ec707d385848d854fdd5eb/annettegugelannettegugel2020-05-04T12:42:35+02:00Mineral Oil Properties Transformer Vegetable <span data-person-type="author" class="authorEditorList "><span><span itemtype="http://schema.org/Person" itemscope="itemscope" itemprop="author"><a title="A. Ciuriuc" itemprop="url" href="/person/1c1d6bc5b69b27022656f31dff9f05ed7/author/0"><span itemprop="name">A. Ciuriuc</span></a></span>, </span><span><span itemtype="http://schema.org/Person" itemscope="itemscope" itemprop="author"><a title="P. Notingher" itemprop="url" href="/person/1c1d6bc5b69b27022656f31dff9f05ed7/author/1"><span itemprop="name">P. Notingher</span></a></span>, </span><span><span itemtype="http://schema.org/Person" itemscope="itemscope" itemprop="author"><a title="Mark Jovalekic" itemprop="url" href="/person/1c1d6bc5b69b27022656f31dff9f05ed7/author/2"><span itemprop="name">M. Jovalekic</span></a></span>, </span> und <span><span itemtype="http://schema.org/Person" itemscope="itemscope" itemprop="author"><a title="Stefan Tenbohlen" itemprop="url" href="/person/1c1d6bc5b69b27022656f31dff9f05ed7/author/3"><span itemprop="name">S. Tenbohlen</span></a></span></span>. </span><span class="additional-entrytype-information">(<em><span>2014<meta content="2014" itemprop="datePublished"/></span></em>)</span>Mon May 04 12:42:35 CEST 2020169-174Experimental Study on Vegetable and Mineral Transformer Oils Properties2014Mineral Oil Properties Transformer Vegetable Tensile properties of latex paint films with TiO 2 pigmenthttps://puma.ub.uni-stuttgart.de/bibtex/2ae8ffa656f41660bbacb596234557d52/fndettafndetta2020-01-17T12:54:57+01:00latex properties tensile <span data-person-type="author" class="authorEditorList "><span><span itemtype="http://schema.org/Person" itemscope="itemscope" itemprop="author"><a title="Eric WS Hagan" itemprop="url" href="/person/177993d7b9615d33acccbef7060462bcb/author/0"><span itemprop="name">E. Hagan</span></a></span>, </span><span><span itemtype="http://schema.org/Person" itemscope="itemscope" itemprop="author"><a title="Maria N Charalambides" itemprop="url" href="/person/177993d7b9615d33acccbef7060462bcb/author/1"><span itemprop="name">M. Charalambides</span></a></span>, </span><span><span itemtype="http://schema.org/Person" itemscope="itemscope" itemprop="author"><a title="Christina T Young" itemprop="url" href="/person/177993d7b9615d33acccbef7060462bcb/author/2"><span itemprop="name">C. Young</span></a></span>, </span><span><span itemtype="http://schema.org/Person" itemscope="itemscope" itemprop="author"><a title="Thomas JS Learner" itemprop="url" href="/person/177993d7b9615d33acccbef7060462bcb/author/3"><span itemprop="name">T. Learner</span></a></span>, </span> und <span><span itemtype="http://schema.org/Person" itemscope="itemscope" itemprop="author"><a title="Stephen Hackney" itemprop="url" href="/person/177993d7b9615d33acccbef7060462bcb/author/4"><span itemprop="name">S. Hackney</span></a></span></span>. </span><span class="additional-entrytype-information"><span itemtype="http://schema.org/PublicationIssue" itemscope="itemscope" itemprop="isPartOf"><em><span itemprop="journal">Mechanics of Time-Dependent Materials</span>, </em> <em><span itemtype="http://schema.org/PublicationVolume" itemscope="itemscope" itemprop="isPartOf"><span itemprop="volumeNumber">13 </span></span>(<span itemprop="issueNumber">2</span>):
<span itemprop="pagination">149--161</span></em> </span>(<em><span>2009<meta content="2009" itemprop="datePublished"/></span></em>)</span>Fri Jan 17 12:54:57 CET 2020Mechanics of Time-Dependent Materials2149--161Tensile properties of latex paint films with TiO 2 pigment132009latex properties tensile Automated numerical process chain for the design of folded sandwich coreshttps://puma.ub.uni-stuttgart.de/bibtex/22bd4bdf4e64b52fe8c55f005f7df9e16/mgeigermgeiger2019-11-08T16:11:00+01:00adaptive based ceramics, control controllable crystal devices, direct electrochromic facade films, glass glazed glazing glazing, heat intelligent liquid materials, mechanism, optical optimisation, optimization, performance properties protection, self-adjusting smart solar sunlight sunlight, survey, system system, systems, thermochromic transfer, units, visual windows, <span data-person-type="author" class="authorEditorList "><span><span itemtype="http://schema.org/Person" itemscope="itemscope" itemprop="author"><a title="Fabian Muhs" itemprop="url" href="/person/16824b2fe2fc917817789f612dae3555c/author/0"><span itemprop="name">F. Muhs</span></a></span>, </span><span><span itemtype="http://schema.org/Person" itemscope="itemscope" itemprop="author"><a title="Yves Klett" itemprop="url" href="/person/16824b2fe2fc917817789f612dae3555c/author/1"><span itemprop="name">Y. Klett</span></a></span>, </span> und <span><span itemtype="http://schema.org/Person" itemscope="itemscope" itemprop="author"><a title="Peter Middendorf" itemprop="url" href="/person/16824b2fe2fc917817789f612dae3555c/author/2"><span itemprop="name">P. Middendorf</span></a></span></span>. </span><span class="additional-entrytype-information"><span itemtype="http://schema.org/Book" itemscope="itemscope" itemprop="isPartOf"><em><span itemprop="name">7th International Meeting on Origami in Science, Mathematics and Education (OSME), September 5-7, 2018, Oxford, UK</span>, </em></span><em> 4, </em><em>Seite <span itemprop="pagination">1043--1058</span>. </em>(<em><span>2018<meta content="2018" itemprop="datePublished"/></span></em>)</span>Fri Nov 08 16:11:00 CET 20197th {International} {Meeting} on {Origami} in {Science}, {Mathematics} and {Education} ({OSME}), {September} 5-7, 2018, {Oxford}, {UK}1043--1058Automated numerical process chain for the design of folded sandwich cores42018adaptive based ceramics, control controllable crystal devices, direct electrochromic facade films, glass glazed glazing glazing, heat intelligent liquid materials, mechanism, optical optimisation, optimization, performance properties protection, self-adjusting smart solar sunlight sunlight, survey, system system, systems, thermochromic transfer, units, visual windows, Optical properties of the organic metal (BEDT-TTF)4Ni(dto)2https://puma.ub.uni-stuttgart.de/bibtex/2b807599ecaba466a50b5cc3526ee96cb/ulrikeoffenbeckulrikeoffenbeck2018-04-26T08:15:31+02:00BEDT-TTF metal organic properties <span data-person-type="author" class="authorEditorList "><span><span itemtype="http://schema.org/Person" itemscope="itemscope" itemprop="author"><a title="E. Griesshaber" itemprop="url" href="/person/1e55f8de8dbecdebc2a183e7b713b2859/author/0"><span itemprop="name">E. Griesshaber</span></a></span>, </span><span><span itemtype="http://schema.org/Person" itemscope="itemscope" itemprop="author"><a title="P. Haas" itemprop="url" href="/person/1e55f8de8dbecdebc2a183e7b713b2859/author/1"><span itemprop="name">P. Haas</span></a></span>, </span><span><span itemtype="http://schema.org/Person" itemscope="itemscope" itemprop="author"><a title="J. Thoms" itemprop="url" href="/person/1e55f8de8dbecdebc2a183e7b713b2859/author/2"><span itemprop="name">J. Thoms</span></a></span>, </span><span><span itemtype="http://schema.org/Person" itemscope="itemscope" itemprop="author"><a title="A. Darjushkin" itemprop="url" href="/person/1e55f8de8dbecdebc2a183e7b713b2859/author/3"><span itemprop="name">A. Darjushkin</span></a></span>, </span><span><span itemtype="http://schema.org/Person" itemscope="itemscope" itemprop="author"><a title="B.P. Gorshunov" itemprop="url" href="/person/1e55f8de8dbecdebc2a183e7b713b2859/author/4"><span itemprop="name">B. Gorshunov</span></a></span>, </span><span><span itemtype="http://schema.org/Person" itemscope="itemscope" itemprop="author"><a title="M. Dressel" itemprop="url" href="/person/1e55f8de8dbecdebc2a183e7b713b2859/author/5"><span itemprop="name">M. Dressel</span></a></span>, </span><span><span itemtype="http://schema.org/Person" itemscope="itemscope" itemprop="author"><a title="D. Schweitzer" itemprop="url" href="/person/1e55f8de8dbecdebc2a183e7b713b2859/author/6"><span itemprop="name">D. Schweitzer</span></a></span>, </span><span><span itemtype="http://schema.org/Person" itemscope="itemscope" itemprop="author"><a title="R.K. Kremer" itemprop="url" href="/person/1e55f8de8dbecdebc2a183e7b713b2859/author/7"><span itemprop="name">R. Kremer</span></a></span>, </span><span><span itemtype="http://schema.org/Person" itemscope="itemscope" itemprop="author"><a title="A. Golnik" itemprop="url" href="/person/1e55f8de8dbecdebc2a183e7b713b2859/author/8"><span itemprop="name">A. Golnik</span></a></span>, </span><span><span itemtype="http://schema.org/Person" itemscope="itemscope" itemprop="author"><a title="C. Bernhard" itemprop="url" href="/person/1e55f8de8dbecdebc2a183e7b713b2859/author/9"><span itemprop="name">C. Bernhard</span></a></span></span> und 3 andere Autor(en). </span><span class="additional-entrytype-information"><span itemtype="http://schema.org/PublicationIssue" itemscope="itemscope" itemprop="isPartOf"><em><span itemprop="journal">Synthetic Metals</span>, </em> <em><span itemtype="http://schema.org/PublicationVolume" itemscope="itemscope" itemprop="isPartOf"><span itemprop="volumeNumber">120 </span></span>(<span itemprop="issueNumber">1-3</span>):
<span itemprop="pagination">731-732</span></em> </span>(<em><span>März 2001<meta content="März 2001" itemprop="datePublished"/></span></em>)</span>Thu Apr 26 08:15:31 CEST 2018Synthetic Metalsmar1-3731-732Optical properties of the organic metal (BEDT-TTF)4[Ni(dto)2]1202001BEDT-TTF metal organic properties Manifestation of multiband optical properties of MgB2https://puma.ub.uni-stuttgart.de/bibtex/2204f24e03675952ab7c9bc07779fe5b4/ulrikeoffenbeckulrikeoffenbeck2018-04-25T12:04:20+02:00MgB2 properties <span data-person-type="author" class="authorEditorList "><span><span itemtype="http://schema.org/Person" itemscope="itemscope" itemprop="author"><a title="A.B. Kuz'menko" itemprop="url" href="/person/1041dc0cea695fa4fcb44612d537e01de/author/0"><span itemprop="name">A. Kuz'menko</span></a></span>, </span><span><span itemtype="http://schema.org/Person" itemscope="itemscope" itemprop="author"><a title="F.P. Mena" itemprop="url" href="/person/1041dc0cea695fa4fcb44612d537e01de/author/1"><span itemprop="name">F. Mena</span></a></span>, </span><span><span itemtype="http://schema.org/Person" itemscope="itemscope" itemprop="author"><a title="H.J.A. Molegraaf" itemprop="url" href="/person/1041dc0cea695fa4fcb44612d537e01de/author/2"><span itemprop="name">H. Molegraaf</span></a></span>, </span><span><span itemtype="http://schema.org/Person" itemscope="itemscope" itemprop="author"><a title="D. van der Marel" itemprop="url" href="/person/1041dc0cea695fa4fcb44612d537e01de/author/3"><span itemprop="name">D. van der Marel</span></a></span>, </span><span><span itemtype="http://schema.org/Person" itemscope="itemscope" itemprop="author"><a title="B. Gorshunov" itemprop="url" href="/person/1041dc0cea695fa4fcb44612d537e01de/author/4"><span itemprop="name">B. Gorshunov</span></a></span>, </span><span><span itemtype="http://schema.org/Person" itemscope="itemscope" itemprop="author"><a title="M. Dressel" itemprop="url" href="/person/1041dc0cea695fa4fcb44612d537e01de/author/5"><span itemprop="name">M. Dressel</span></a></span>, </span><span><span itemtype="http://schema.org/Person" itemscope="itemscope" itemprop="author"><a title="I.I. Mazin" itemprop="url" href="/person/1041dc0cea695fa4fcb44612d537e01de/author/6"><span itemprop="name">I. Mazin</span></a></span>, </span><span><span itemtype="http://schema.org/Person" itemscope="itemscope" itemprop="author"><a title="J. Kortus" itemprop="url" href="/person/1041dc0cea695fa4fcb44612d537e01de/author/7"><span itemprop="name">J. Kortus</span></a></span>, </span><span><span itemtype="http://schema.org/Person" itemscope="itemscope" itemprop="author"><a title="O.V. Dolgov" itemprop="url" href="/person/1041dc0cea695fa4fcb44612d537e01de/author/8"><span itemprop="name">O. Dolgov</span></a></span>, </span><span><span itemtype="http://schema.org/Person" itemscope="itemscope" itemprop="author"><a title="T. Muranaka" itemprop="url" href="/person/1041dc0cea695fa4fcb44612d537e01de/author/9"><span itemprop="name">T. Muranaka</span></a></span></span> und 1 andere Autor(en). </span><span class="additional-entrytype-information"><span itemtype="http://schema.org/PublicationIssue" itemscope="itemscope" itemprop="isPartOf"><em><span itemprop="journal">Solid State Communications</span>, </em> <em><span itemtype="http://schema.org/PublicationVolume" itemscope="itemscope" itemprop="isPartOf"><span itemprop="volumeNumber">121 </span></span>(<span itemprop="issueNumber">9-10</span>):
<span itemprop="pagination">479-484</span></em> </span>(<em><span>März 2002<meta content="März 2002" itemprop="datePublished"/></span></em>)</span>Wed Apr 25 12:04:20 CEST 2018Solid State Communicationsmar9-10479-484Manifestation of multiband optical properties of MgB21212002MgB2 properties