mokarram76's blog
https://imechanica.org/blog/27761
enNumerics of growth-induced deformations
https://imechanica.org/node/24836
<div class="field field-name-taxonomy-vocabulary-6 field-type-taxonomy-term-reference field-label-hidden"><div class="field-items"><div class="field-item even"><a href="/taxonomy/term/76">research</a></div></div></div><div class="field field-name-taxonomy-vocabulary-8 field-type-taxonomy-term-reference field-label-hidden"><div class="field-items"><div class="field-item even"><a href="/taxonomy/term/10998">Biological Growth</a></div><div class="field-item odd"><a href="/taxonomy/term/8163">morphoelasticity</a></div><div class="field-item even"><a href="/taxonomy/term/271">morphogenesis</a></div><div class="field-item odd"><a href="/taxonomy/term/8827">mechanics of morphogenesis</a></div></div></div><div class="field field-name-body field-type-text-with-summary field-label-hidden"><div class="field-items"><div class="field-item even"><p><img src="https://pbs.twimg.com/media/EqAdR-IW4AA-8Yd?format=jpg&name=large" alt="" width="279" height="203" /><img src="https://pbs.twimg.com/media/EqAdusgXYAghBCH?format=jpg&name=4096x4096" alt="" width="308" height="196" /></p>
<p>Dear iMechanicians,</p>
<p>Growth-induced deformation or morphoelasticity is an interesting phenomenon ranging from living tissues to biological plants in nature. We recently publish a paper in JMPS that solves some challenging boundary value problems by addressing few key issues in computational morphoelasticity. It might be interesting for you. </p>
<p>PDF : <a class="css-4rbku5 css-18t94o4 css-901oao css-16my406 r-1n1174f r-1loqt21 r-1qd0xha r-ad9z0x r-bcqeeo r-1ny4l3l r-1ddef8g r-qvutc0" dir="ltr" href="https://t.co/I35Qe5uMvM?amp=1" target="_blank" rel="noopener noreferrer" data-focusable="true">authors.elsevier.com/a/1cKSi57Zjx1mN</a></p>
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<tr class="odd"><td><span class="file"><img class="file-icon" alt="PDF icon" title="application/pdf" src="/modules/file/icons/application-pdf.png" /> <a href="https://imechanica.org/files/JMPS2021.pdf" type="application/pdf; length=5108521" title="JMPS2021.pdf">computational morphoelasticity</a></span></td><td>4.87 MB</td> </tr>
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</div></div></div>Wed, 30 Dec 2020 18:01:45 +0000mokarram7624836 at https://imechanica.orghttps://imechanica.org/node/24836#commentshttps://imechanica.org/crss/node/24836Mathematical formulations for elastic magneto-electrically coupled soft materials at finite strains
https://imechanica.org/node/24787
<div class="field field-name-taxonomy-vocabulary-6 field-type-taxonomy-term-reference field-label-hidden"><div class="field-items"><div class="field-item even"><a href="/taxonomy/term/76">research</a></div></div></div><div class="field field-name-taxonomy-vocabulary-8 field-type-taxonomy-term-reference field-label-hidden"><div class="field-items"><div class="field-item even"><a href="/taxonomy/term/12936">Magneto-active polymers</a></div><div class="field-item odd"><a href="/taxonomy/term/485">electro-active polymers</a></div><div class="field-item even"><a href="/taxonomy/term/5073">Energy Harvesting</a></div><div class="field-item odd"><a href="/taxonomy/term/6600">finite strain</a></div></div></div><div class="field field-name-body field-type-text-with-summary field-label-hidden"><div class="field-items"><div class="field-item even"><p> </p>
<p><img src="https://pbs.twimg.com/media/EoNwY_CWEAM0LKR?format=jpg&name=large" alt="" width="882" height="656" /></p>
<p id="sp0001">Recently, among other smart and multifunctional materials, magneto-electric soft materials are expected to open a new horizon with myriad of potential applications such as wireless energy harvesting, spintronics and nonvolatile memories, magneto-electric random access memory, to mention a few. Magneto-electric coupling can be defined as the ability of a material to electrically polarize upon the application of a magnetic field and conversely, to magnetize under the application of an electric field. In contrast to traditional multi-ferroic hard materials, magneto-electric soft materials are of largely deformable where electric and magnetic fields and mechanical deformations are intricately coupled at finite strians. In this contribution, we will emphasis to formulate generalised mathematical frameworks of finitely deformed magneto-electric soft materials. After elaborating fundamental and governing equations, some homogeneous and non-homogeneous classical boundary value problems are studied under magneto-electrically coupled loads. <a href="https://doi.org/10.1016/j.ijengsci.2020.103429">https://doi.org/10.1016/j.ijengsci.2020.103429</a></p>
<p>PDF file attached</p>
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<tr class="odd"><td><span class="file"><img class="file-icon" alt="PDF icon" title="application/pdf" src="/modules/file/icons/application-pdf.png" /> <a href="https://imechanica.org/files/IJES2021.pdf" type="application/pdf; length=1040327">IJES2021.pdf</a></span></td><td>1015.94 KB</td> </tr>
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</div></div></div>Mon, 07 Dec 2020 14:18:53 +0000mokarram7624787 at https://imechanica.orghttps://imechanica.org/node/24787#commentshttps://imechanica.org/crss/node/24787A microstructural-based model for magneto-viscoelasticity at finite strains
https://imechanica.org/node/24707
<div class="field field-name-taxonomy-vocabulary-6 field-type-taxonomy-term-reference field-label-hidden"><div class="field-items"><div class="field-item even"><a href="/taxonomy/term/76">research</a></div></div></div><div class="field field-name-taxonomy-vocabulary-8 field-type-taxonomy-term-reference field-label-hidden"><div class="field-items"><div class="field-item even"><a href="/taxonomy/term/12295">Magnetoelasticity</a></div><div class="field-item odd"><a href="/taxonomy/term/12936">Magneto-active polymers</a></div><div class="field-item even"><a href="/taxonomy/term/8503">Magnetorheological elastomers</a></div></div></div><div class="field field-name-body field-type-text-with-summary field-label-hidden"><div class="field-items"><div class="field-item even"><p><img src="https://ars.els-cdn.com/content/image/1-s2.0-S0020768320304224-gr3_lrg.jpg" alt="" width="817" height="276" /></p>
<p>Common approaches to model MAPs are based on phenomenological continuum models, which are able to predict their magneto-mechanical behaviour but are sometimes failed to illustrate specific features of the underlying physics. To better understand the magneto-mechanical responses of MAPs and guide their design and manufacturing processes, this contribution presents a novel continuum constitutive model originated from a microstructural basis. The model is formulated within a finite deformation framework and accounts for viscous (rate) dependences and magneto-mechanical coupling. After the formulations, the model is calibrated with a set of experimental data. The model is validated with a wide range of experimental data that show its predictability. Such a microstructurally-motivated finite strain model will help in designing MAPs with complex three-dimensional microstructures.</p>
<p>For details, see the article</p>
<p><a href="https://www.sciencedirect.com/science/article/pii/S0020768320304224">https://www.sciencedirect.com/science/article/pii/S0020768320304224</a></p>
</div></div></div>Sat, 07 Nov 2020 06:54:22 +0000mokarram7624707 at https://imechanica.orghttps://imechanica.org/node/24707#commentshttps://imechanica.org/crss/node/24707A robust finite element framework for coupled computational electromechanics
https://imechanica.org/node/24623
<div class="field field-name-taxonomy-vocabulary-6 field-type-taxonomy-term-reference field-label-hidden"><div class="field-items"><div class="field-item even"><a href="/taxonomy/term/76">research</a></div></div></div><div class="field field-name-taxonomy-vocabulary-8 field-type-taxonomy-term-reference field-label-hidden"><div class="field-items"><div class="field-item even"><a href="/taxonomy/term/992">dielectric elastomer</a></div><div class="field-item odd"><a href="/taxonomy/term/12966">computational electromechanics</a></div><div class="field-item even"><a href="/taxonomy/term/9075">soft robotics</a></div><div class="field-item odd"><a href="/taxonomy/term/8170">Coupled Problems</a></div></div></div><div class="field field-name-body field-type-text-with-summary field-label-hidden"><div class="field-items"><div class="field-item even"><p><span><a href="https://imechanica.org/user"><img src="https://pbs.twimg.com/media/EhsVXZRXcAISCY8?format=jpg&name=large" alt="" width="666" height="528" />My account</a></span></p>
<p><span>In this work, we present a novel finite element framework for the simulation of coupled static and dynamic electromechanical interactions in electro-active polymeric materials. To model the incompressible nature of EAPs, a two-field mixed displacement–pressure formulation which, unlike the commonly-used mixed three-field and </span><span class="math"><span id="MathJax-Element-1-Frame" class="MathJax_SVG" tabindex="0" data-mathml="//www.w3.org/1998/Math/MathML"><mi mathvariant="bold-italic" is="true">F</mi></math>"><span class="MJX_Assistive_MathML">F</span></span></span><span>-bar formulations, is applicable for both nearly and fully incompressible materials, is employed. For the spatial discretisation, innovative quadratic Bézier triangular and tetrahedral elements are used. The governing equations for the coupled electromechanical problem are solved using a monolithic scheme; for elastodynamics simulations, a state-of-the-art implicit time integration is adapted. The accuracy and the computational efficiency of the proposed framework are demonstrated by studying several benchmark examples in computational electromechanics which include simulations of a spherical gripper in elastostatics and a dielectric pump in elastodynamics. </span></p>
<p><span>For PDF copy, <a href="https://www.sciencedirect.com/science/article/pii/S0045782520306289?dgcid=author">https://www.sciencedirect.com/science/article/pii/S0045782520306289?dgcid=author</a></span></p>
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<tr class="odd"><td><span class="file"><img class="file-icon" alt="PDF icon" title="application/pdf" src="/modules/file/icons/application-pdf.png" /> <a href="https://imechanica.org/files/EAP2020_0.pdf" type="application/pdf; length=10540430">EAP2020.pdf</a></span></td><td>10.05 MB</td> </tr>
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</div></div></div>Tue, 29 Sep 2020 08:53:32 +0000mokarram7624623 at https://imechanica.orghttps://imechanica.org/node/24623#commentshttps://imechanica.org/crss/node/24623Experimental study of Magneto-active polymers : A Comprehensive Review
https://imechanica.org/node/24527
<div class="field field-name-taxonomy-vocabulary-6 field-type-taxonomy-term-reference field-label-hidden"><div class="field-items"><div class="field-item even"><a href="/taxonomy/term/76">research</a></div></div></div><div class="field field-name-taxonomy-vocabulary-8 field-type-taxonomy-term-reference field-label-hidden"><div class="field-items"><div class="field-item even"><a href="/taxonomy/term/1635">magnetorheological Elastomers (MRE)</a></div><div class="field-item odd"><a href="/taxonomy/term/12936">Magneto-active polymers</a></div><div class="field-item even"><a href="/taxonomy/term/9075">soft robotics</a></div><div class="field-item odd"><a href="/taxonomy/term/8170">Coupled Problems</a></div></div></div><div class="field field-name-body field-type-text-with-summary field-label-hidden"><div class="field-items"><div class="field-item even"><p><span><span><img src="https://pbs.twimg.com/media/EfsDIxYXYAA_TTZ?format=jpg&name=large" alt="" width="494" height="389" /></span></span></p>
<p><span><span>Magnetorheological elastomers (MREs) are a class of recently emerged smart materials whose moduli are largely influenced when exposed to an external magnetic field. The MREs are particulate composites, where micro-sized magnetic particles are dispersed inside a non-magnetic polymeric matrix. These elastomers are known for changing their mechanical and rheological properties in the presence of a magnetic field. This change in properties is widely known as the magnetorheological (MR) effect. </span><span> The common magneto-mechanical characterization experiments of MREs include static and dynamic compression, tensile, and shear tests in both off-field and on-field. This review article aims to provide a comprehensive overview of the magneto-mechanical characterizations of MREs along with brief coverage of the MRE materials and their fabrica- tion methods.</span></span></p>
<p><span><span>For a PDF file, click </span></span></p>
<p><span><span><a href="https://bit.ly/3gajpJx">https://bit.ly/3gajpJx</a></span></span></p>
</div></div></div>Wed, 19 Aug 2020 20:17:26 +0000mokarram7624527 at https://imechanica.orghttps://imechanica.org/node/24527#commentshttps://imechanica.org/crss/node/24527Additive Manufacturing and the COVID-19 challenges: An in-depth study
https://imechanica.org/node/24507
<div class="field field-name-taxonomy-vocabulary-6 field-type-taxonomy-term-reference field-label-hidden"><div class="field-items"><div class="field-item even"><a href="/taxonomy/term/76">research</a></div></div></div><div class="field field-name-taxonomy-vocabulary-8 field-type-taxonomy-term-reference field-label-hidden"><div class="field-items"><div class="field-item even"><a href="/taxonomy/term/12789">Covid-19</a></div><div class="field-item odd"><a href="/taxonomy/term/3568">additive manufacturing</a></div><div class="field-item even"><a href="/taxonomy/term/12931">PPE</a></div><div class="field-item odd"><a href="/taxonomy/term/9171">3D printing</a></div><div class="field-item even"><a href="/taxonomy/term/497">polymers</a></div></div></div><div class="field field-name-body field-type-text-with-summary field-label-hidden"><div class="field-items"><div class="field-item even"><p><img src="https://www.carbon3d.com/wp-content/uploads/blog_covid19-do-our-part_swabs-printing.jpg" alt="3D printed Nasal Swabs" width="339" height="242" /><img title="3D Printed Nasal Swabs" src="https://www.3dnatives.com/en/wp-content/uploads/sites/2/test-swabs-cover.jpg" alt="" width="400" height="235" /></p>
<p>The COVID-19 pandemic created huge demand of relevant medical and personal protective equipment (PPE) and put unprecedented pressure on the healthcare system within a very short span of time. Moreover, the supply chains system faced extreme disruptions as a result of the frequent and severe lockdowns across the globe. In this situation, additive manufacturing (AM) becomes a supplementary manufacturing process to meet the explosive demands and ease the health disaster worldwide. Providing the extensive design customization, instant manufacturing route eliminating lengthy assembly line and ensuring low manufacturing lead time, the AM could successfully curve the extreme supply chain backlog. The AM community joins the fight against COVID-19 by producing medical equipment such as ventilators, nasopharyngeal swabs and PPE such as face masks and face shields. The aim of this article is to systematically summarize and to critically analyze all major efforts put forward by the AM industry, academics, researchers, users, and individuals. </p>
<p>See details here in PDF,</p>
<ul><ul><li class="nova-e-list__item"><span><a href="http://dx.doi.org/10.13140/RG.2.2.35767.55206">http://dx.doi.org/10.13140/RG.2.2.35767.55206</a></span></li>
</ul></ul></div></div></div>Wed, 12 Aug 2020 16:23:57 +0000mokarram7624507 at https://imechanica.orghttps://imechanica.org/node/24507#commentshttps://imechanica.org/crss/node/245073D printed Polyurethane : Viscoelastic experimental characterization and computational modelling
https://imechanica.org/node/24393
<div class="field field-name-taxonomy-vocabulary-6 field-type-taxonomy-term-reference field-label-hidden"><div class="field-items"><div class="field-item even"><a href="/taxonomy/term/76">research</a></div></div></div><div class="field field-name-taxonomy-vocabulary-8 field-type-taxonomy-term-reference field-label-hidden"><div class="field-items"><div class="field-item even"><a href="/taxonomy/term/632">metamaterials</a></div><div class="field-item odd"><a href="/taxonomy/term/12902">Additve manufacturing; 3D printing; Viscoelastic characterization; Polyurethane; Architected materials; Constitutive modelling</a></div></div></div><div class="field field-name-body field-type-text-with-summary field-label-hidden"><div class="field-items"><div class="field-item even"><p><span>Digital Light Synthesis (DLS) technology creates ample opportunities for making 3D printed soft polymers for a wide range of grades and properties. In DLS, a 3D printer uses a continuous building technique in which the curing process is activated by an ultra-violet (UV) light. In this contribution, EUP40, a recently invented commercially available elastomeric polyurethane (EPU) printed by the DLS technology, is experimentally characterized. For characterizing the mechanical properties, an extensive viscoelastic experimental study on the digitally printed EPU taking the strain rate-dependence are conducted. The study reveals a significant time-dependency on its mechanical responses. Moreover, the material demonstrates noticeable nonlinear viscosities that depend on strain and strain rates. Based on the experimental findings for the printed elastomer, a large strain viscoelastic model is devised where evolution laws are enhanced by strain and strain rate-dependent nonlinear viscosities. Following identifications of relevant material parameters, we validate the model with the experimental data that show its good predictability. Such an extensive experimental study along with a constitutive model will help in designing and simulating more complex cellular and structured metamaterials using 3D printed elastomeric polyurethanes.</span></p>
<p><span>For details, please see the link</span></p>
<p><span><span><a href="https://www.sciencedirect.com/science/article/abs/pii/S0020746220302080">https://www.sciencedirect.com/science/article/abs/pii/S0020746220302080</a></span></span></p>
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<tr class="odd"><td><span class="file"><img class="file-icon" alt="PDF icon" title="application/pdf" src="/modules/file/icons/application-pdf.png" /> <a href="https://imechanica.org/files/EPU40NonLin2020.pdf" type="application/pdf; length=1876154">EPU40NonLin2020.pdf</a></span></td><td>1.79 MB</td> </tr>
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</div></div></div>Sat, 18 Jul 2020 12:25:04 +0000mokarram7624393 at https://imechanica.orghttps://imechanica.org/node/24393#commentshttps://imechanica.org/crss/node/243933D Printed Silicone Polymer : Thermo-viscoelastic experimental characterization and computational modelling
https://imechanica.org/node/24337
<div class="field field-name-taxonomy-vocabulary-6 field-type-taxonomy-term-reference field-label-hidden"><div class="field-items"><div class="field-item even"><a href="/taxonomy/term/76">research</a></div></div></div><div class="field field-name-taxonomy-vocabulary-8 field-type-taxonomy-term-reference field-label-hidden"><div class="field-items"><div class="field-item even"><a href="/taxonomy/term/12702">metamaterials; additve manufacturing; 3D printing; Multifunctional materials; Cellular composites; Architected materials</a></div></div></div><div class="field field-name-body field-type-text-with-summary field-label-hidden"><div class="field-items"><div class="field-item even"><p><span>In this contribution, a DLS-based digitally printed silicone (SIL30) is experimentally characterized. To understand polymer's temperature-dependent mechanical responses, an extensive thermo-viscoelastic experimental characterisation at various strain rates under tensile deformation and temperature fields from -20 °C to 60 °C is performed. Motivated by the thermo-mechanical results of the polymer, a thermodynamically consistent constitutive model at large strain is devised. Afterwards, the model is calibrated to the data that results in the identification of relevant parameters. 3D printed soft polymers are major candidates in designing complex and intricate architectured metamaterials for biomedical applications. Hence, a comprehensive thermo-mechanical experimental study and subsequent constitutive modelling will facilitate in designing and simulating more complex cellular metamaterials using 3D printed silicones.</span></p>
<p><span><a href="https://www.sciencedirect.com/science/article/pii/S2214860420307673?dgcid=author">https://www.sciencedirect.com/science/article/pii/S2214860420307673?dgcid=author</a></span></p>
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<tr class="odd"><td><span class="file"><img class="file-icon" alt="PDF icon" title="application/pdf" src="/modules/file/icons/application-pdf.png" /> <a href="https://imechanica.org/files/AdditiveManufac2020.pdf" type="application/pdf; length=4091343">AdditiveManufac2020.pdf</a></span></td><td>3.9 MB</td> </tr>
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</div></div></div>Tue, 30 Jun 2020 07:35:09 +0000mokarram7624337 at https://imechanica.orghttps://imechanica.org/node/24337#commentshttps://imechanica.org/crss/node/24337EPSRC Funded PhD position for 4 years @ Swansea University, UK
https://imechanica.org/node/24202
<div class="field field-name-taxonomy-vocabulary-6 field-type-taxonomy-term-reference field-label-hidden"><div class="field-items"><div class="field-item even"><a href="/taxonomy/term/76">research</a></div></div></div><div class="field field-name-taxonomy-vocabulary-8 field-type-taxonomy-term-reference field-label-hidden"><div class="field-items"><div class="field-item even"><a href="/taxonomy/term/5737">academic job</a></div><div class="field-item odd"><a href="/taxonomy/term/12559">#PhD_Position</a></div><div class="field-item even"><a href="/taxonomy/term/488">Renewable Energy</a></div><div class="field-item odd"><a href="/taxonomy/term/3631">fatique</a></div></div></div><div class="field field-name-body field-type-text-with-summary field-label-hidden"><div class="field-items"><div class="field-item even"><p><span>Hi </span></p>
<p><span>I am looking for a good PhD student in the area of <em>materials science/polymer science/computational engineering/mechanical engineering</em>. The position is fully funded by EPSRC and ORE Catapult for 4 years.</span></p>
<p><span><a href="https://www.swansea.ac.uk/postgraduate/scholarships/research/mechanical-engineering-epsrc-ore-phd-understanding.php">https://www.swansea.ac.uk/postgraduate/scholarships/research/mechanical-engineering-epsrc-ore-phd-understanding.php</a></span></p>
<p><span>The PhD scholarship is only for UK/EU citizens. The research aims to predict the effects of aging by a de-coupled approach in order to understand the fatigue failure behaviour of tidal turbine blades made of fibre-refinfored composites.</span></p>
<p><span>If you are interested for the postion, send me your CV, <a href="mailto:mokarram.hossain@swansea.ac.uk">mokarram.hossain@swansea.ac.uk</a></span></p>
</div></div></div>Thu, 14 May 2020 18:44:55 +0000mokarram7624202 at https://imechanica.orghttps://imechanica.org/node/24202#commentshttps://imechanica.org/crss/node/24202Ecoflex polymer : Comprehensive experimental study and constitutive modelling
https://imechanica.org/node/24118
<div class="field field-name-taxonomy-vocabulary-6 field-type-taxonomy-term-reference field-label-hidden"><div class="field-items"><div class="field-item even"><a href="/taxonomy/term/76">research</a></div></div></div><div class="field field-name-taxonomy-vocabulary-8 field-type-taxonomy-term-reference field-label-hidden"><div class="field-items"><div class="field-item even"><a href="/taxonomy/term/10736">Ecoflex</a></div><div class="field-item odd"><a href="/taxonomy/term/2674">shore hardness</a></div><div class="field-item even"><a href="/taxonomy/term/1398">continuum thermomechanics</a></div></div></div><div class="field field-name-body field-type-text-with-summary field-label-hidden"><div class="field-items"><div class="field-item even"><p>We have published two papers on Ecoflex, a popular silicone polymer in recent days. The polymer is largely temperature- and strain rate-insensitive. It comes up with several Shore Hardnesses. We characterize five Shores and develop a novel Shore-dependent modelling framework</p>
<p>Mechanics of Materials >> <a href="https://www.sciencedirect.com/science/article/pii/S016766362030020X">https://www.sciencedirect.com/science/article/pii/S016766362030020X</a></p>
<p><span>Polymer Testing >> <a href="https://www.sciencedirect.com/science/article/abs/pii/S0142941820301185">https://www.sciencedirect.com/science/article/abs/pii/S0142941820301185</a></span></p>
<p> </p>
<p> </p>
</div></div></div>Sat, 18 Apr 2020 10:49:14 +0000mokarram7624118 at https://imechanica.orghttps://imechanica.org/node/24118#commentshttps://imechanica.org/crss/node/24118Fully funded PhD position in Bio-mechanics, Swansea, UK
https://imechanica.org/node/22461
<div class="field field-name-taxonomy-vocabulary-6 field-type-taxonomy-term-reference field-label-hidden"><div class="field-items"><div class="field-item even"><a href="/taxonomy/term/76">research</a></div></div></div><div class="field field-name-body field-type-text-with-summary field-label-hidden"><div class="field-items"><div class="field-item even"><p><a href="http://imechanica.org/taxonomy/term/76"><br class="Apple-interchange-newline" />research</a>
</p><p>Hi</p>
<p>We are looking for a good PhD student in the field of: <em>Bio-mechanics/Computational Engineering/Computational Mecahnics/Material Engineering/Bio-medical Engineering</em>. <strong>It is a fully funded PhD scholarship for UK/EU citizens only.</strong></p>
<p><span><strong><a href="http://www.swansea.ac.uk/postgraduate/scholarships/research/engineering-joint-phd-experimental-investigations.php">http://www.swansea.ac.uk/postgraduate/scholarships/research/engineering-...</a></strong></span></p>
<p><span>This is a joint PhD degree between Grenoble-Alpes University (<strong>France</strong>) and Zienkiewicz Centre for Computational Engineering (ZCCE, Swansea University, <strong>UK)</strong>. The ZCCE has a World-leading research history in the area of Computational Mechanics for last six decades. If you know any good student in the above mentioned areas, please ask him/her to send me CV, </span></p>
<p><a href="mailto:mokarram.hossain@swansea.ac.uk">mokarram.hossain@swansea.ac.uk</a></p>
</div></div></div>Mon, 25 Jun 2018 15:42:19 +0000mokarram7622461 at https://imechanica.orghttps://imechanica.org/node/22461#commentshttps://imechanica.org/crss/node/22461Fully funded PhD position in Swansea University, UK
https://imechanica.org/node/22405
<div class="field field-name-taxonomy-vocabulary-6 field-type-taxonomy-term-reference field-label-hidden"><div class="field-items"><div class="field-item even"><a href="/taxonomy/term/76">research</a></div></div></div><div class="field field-name-body field-type-text-with-summary field-label-hidden"><div class="field-items"><div class="field-item even"><p><span>Hi</span></p>
<p><span><strong>PhD Scholarship in the field of</strong><span>: Mechanical Engineering/Computational Engineering/Polymer Sciences/Material Engineering/Material Sciences. </span><span>It is a fully funded PhD scholarship for UK/EU citizens only.</span></span></p>
<p><span><span><a href="http://www.swansea.ac.uk/postgraduate/scholarships/research/engineering-kess-phd-reliability-analysis.php">http://www.swansea.ac.uk/postgraduate/scholarships/research/engineering-...</a></span></span></p>
<p><span>If you know any good student in Mechanical Engineering/Computational Engineering/Polymer Sciences/Material Engineering/Material Sciences, please ask him/her to send me CV</span></p>
<p><span><a href="mailto:mokarram.hossain@swansea.ac.uk">mokarram.hossain@swansea.ac.uk</a></span></p>
</div></div></div>Thu, 31 May 2018 13:42:27 +0000mokarram7622405 at https://imechanica.orghttps://imechanica.org/node/22405#commentshttps://imechanica.org/crss/node/22405my recent publications in curing modeling
https://imechanica.org/node/11038
<div class="field field-name-taxonomy-vocabulary-6 field-type-taxonomy-term-reference field-label-hidden"><div class="field-items"><div class="field-item even"><a href="/taxonomy/term/76">research</a></div></div></div><div class="field field-name-taxonomy-vocabulary-8 field-type-taxonomy-term-reference field-label-hidden"><div class="field-items"><div class="field-item even"><a href="/taxonomy/term/795">viscoelasticity</a></div><div class="field-item odd"><a href="/taxonomy/term/6599">curing</a></div><div class="field-item even"><a href="/taxonomy/term/6600">finite strain</a></div><div class="field-item odd"><a href="/taxonomy/term/6601">shrinkage</a></div></div></div><div class="field field-name-body field-type-text-with-summary field-label-hidden"><div class="field-items"><div class="field-item even"><p>
Hi
</p>
<p>
I am working on the modeling of curing process of polymer
</p>
<p>
we may like to take a look on my recent publications:
</p>
<p>
Hossain, M. ; Possart, G. ; Steinmann, P.A <a href="http://www.ltm.uni-erlangen.de/Mitarbeiter/Steinmann/paper/2010/Hossain_Steinmann.pdf" target="_blank">Finite Strain Framework for the Simulation of Polymer Curing. Part II. Viscoelasticity and shrinkage</a> .Computational Mechanics, published online<a rel="nofollow" name="hossain_possart2.pdf" href="http://www.ltm.uni-erlangen.de/Mitarbeiter/Steinmann/paper/2010/Hossain_Steinmann.pdf" title="hossain_possart2.pdf" id="hossain_possart2.pdf"></a>
</p>
<p>
Hossain, M. ; Possart, G. ; Steinmann, P.<br />
A <a href="http://www.ltm.uni-erlangen.de/Mitarbeiter/Steinmann/paper/2009/large%20strain%20curing%201.pdf" target="_blank">Finite Strain Framework for the Simulation of Polymer Curing. Part I: Elasticity.</a> Computational Mechanics 44 (2009), Nr. 5, p. 621-630
</p>
<p>
Hossain, M. ; Possart, G. ; Steinmann, P., <a href="http://www.ltm.uni-erlangen.de/Mitarbeiter/Steinmann/paper/2009/small%20strain%20curing.pdf" target="_blank">A Small-Strain Model to Simulate the Curing of Thermosets</a> Computational Mechanics 43 (2009), Nr. 6, p. 769-779
</p>
<p>
</p>
<p>
best regards
</p>
<p>
mokarram hossain
</p>
<p>
university of erlangen-nuremberg
</p>
<p>
germany
</p>
</div></div></div>Wed, 07 Sep 2011 15:33:27 +0000mokarram7611038 at https://imechanica.orghttps://imechanica.org/node/11038#commentshttps://imechanica.org/crss/node/11038Error | iMechanica