Archive for the ‘News’ Category

8th International Dendrimer Symposium – Poster Prize Winners

Polymer Chemistry and Soft Matter was delighted to award two Poster Prizes at 8th International Dendrimer Symposium held in Madrid, Spain on 23rd – 27th June. The winners were:

Polymer Chemistry Award: Poster 44
M.A. VAN DONGEN (University of Michigan, USA)
Generationnaly pure PAMAM dendrimers as precisely controlled structural building blocks.

Soft Matter Award: Poster 40
Joona MIKKILA (Finland)
Dendrimers mediated formation of inclusion body mimicking virus paracrystals.

Each winner received an RSC Poster Prize certificate as well as 1 year electronic subscription to the journal.

Digg This
Reddit This
Stumble Now!
Share on Facebook
Bookmark this on Delicious
Share on LinkedIn
Bookmark this on Technorati
Post on Twitter
Google Buzz (aka. Google Reader)

Julia Yeomans elected to FRS

It was with great pleasure that we learnt that regular Soft Matter author Professor Julia Yeomans has recently been elected to the Fellowship of the Royal Society.

Professor Yeomans is a theoretical and computational physicist working on statistical physics, hydrodynamics, soft condensed matter and biological physics. Among her current research interests are microswimmers, active systems, liquid crystals and drop dynamics. She holds an ERC Advanced Grant ‘Microflow in Complex Environments’.

Julia obtained her MA in Physics and DPhil in Theoretical Physics from the University of Oxford. She spent two years as a post doc at Cornell University, USA, in the group of Michael Fisher and then returned to the UK, to a Lectureship at the University of Southampton. Shortly thereafter she joined the Rudolf Peierls Centre for Theoretical Physics at Oxford. She is currently Professor of Physics at Oxford, a member of the Oxford Centre for Soft and Biological Matter, and Pauline Chan Fellow, St Hilda’s College.

Earlier this year, Julia was also awarded the EPJE Pierre Gilles De Gennes Lecture Prize, for her contribution to the study of the dynamical behaviour of complex and active liquids in confined geometries. She said of winning the prize: ‘I am delighted by this award. It is recognition for the wonderful students, post-docs and colleagues from all over the world that I have had the privilege and pleasure of working with.’

Recent Soft Matter publications by Julia Yeomans include:

Modelling unidirectional liquid spreading on slanted microposts
Andrea Cavalli, Matthew L. Blow and Julia M. Yeomans
Soft Matter, 2013, Advance Article

Length-dependent translocation of polymers through nanochannels
R. Ledesma-Aguilar, T. Sakaue and J. M. Yeomans
Soft Matter, 2012,8, 1884-1892

Hydrodynamic synchronization at low Reynolds number
Ramin Golestanian, Julia M. Yeomans and Nariya Uchida
Soft Matter, 2011, 7, 3074-3082

To keep up-to-date with all the latest research, sign-up to our RSS feed or Table of contents alert.

Digg This
Reddit This
Stumble Now!
Share on Facebook
Bookmark this on Delicious
Share on LinkedIn
Bookmark this on Technorati
Post on Twitter
Google Buzz (aka. Google Reader)

What happens when I poke it? Interview with Eric Furst in Chemistry World

Eric M. Furst winner of the 2013 Soft Matter LectureshipSoft Matter lectureship award winner Eric Furst talks to Chemistry World writer Jennifer Newton.

Who or what inspired you to become a scientist in the first place?
It was in my blood – I came from a family of engineers so I was exposed at a very early age to science and engineering. I was almost pre-destined in that sense. As a kid, I was inspired by visits to the air and space museum as well as the Space Program here in the US. I even had a picture of the Space Shuttle Columbia over my bed.

Your research is focused on soft matter. What attracted you to that field?
It happened when I was an undergraduate at Carnegie Mellon University, where there was a tremendous group of faculty, including Bob Tilton who I worked with directly. They had a wonderful program on colloids and polymers and that’s when I really got hooked. I started to study polymer adsorption and interfaces and read a lot in the literature about polymer thermodynamics. It’s an area with engineering applications, something that I am obviously interested in. The physical chemistry of the systems is so neat and profound. I also really enjoyed the more fundamental side to it.
I then went on to do a PhD at Stanford University, working with Alice Gast, and that was her area. It has always been a subject that a lot of engineers work on, especially in the US, but it is also a fertile ground of chemists, physicists and materials scientists and I really like that multi-disciplinary aspect of the soft matter community.

You’ve been awarded the 2013 Soft Matter lectureship. How does that feel?
It’s tremendous. It’s amazing recognition and I’m honoured by it. When you look at the names associated with the award, many of whom I know personally, they’re great young leaders in the field. I’ve found the soft matter area to be my intellectual home and I’m really excited to have that sort of exposure.

What do you class as your most important contribution to the soft matter field?
I can tell you about my favourite contributions. One of them has been microrheology. This is an area that actually dates back almost 100 years with people looking at Brownian motion, including Einstein. About 20 years ago now, Dave Weitz and Tom Mason had the idea that you can use this motion to learn about the rheology of materials and the rheology of systems. I think we’ve made some really nice contributions to that in terms of the gelation of biomaterials. Along with my collaborators, we’ve been able to show how microrheology can be used to screen materials to get an understanding of their physical properties and their rheology. It has a gorgeous engineering aspect to it and it fits nicely into the ideas that people have for screening materials and creating libraries of materials. There is some beautiful underlying physics in the problem too.
Another contribution we’ve made is to do with the directed self-assembly of materials. How can we get things like nanoparticles or colloids to self-assemble into unique structures? There is a tremendous amount of work going on in this area right now. And we’ve been able to show how fields can be useful to direct self-assembly.

What do you imagine will be the next big breakthrough in your field?
Along the lines of directed self-assembly, a major breakthrough will be when we get predictive capabilities. Materials chemists have been extremely creative at making particles with different shapes and with different directing interactions. Right now we are sitting on a cusp where we have an enormous library. To make the leap to manufacturing to make real materials that are functional would have huge benefits. Self-assembled nanomaterials are very scalable and would become very low-cost. It’s a very enabling type of technological advance. Things like the Materials Genome Initiative and increases in computational power are giving us a tool box to make those advances.

Is there a particular question you are trying to answer in your lab at the moment?
Not exactly. One of things I love about soft matter is that I can be as unfocused as I want!
We do want to better understand directed self-assembly. I think we’re at the tip of the iceberg for finding the building blocks and pathways that lead to certain structures.
We’re also really interested in protein therapeutics and that just shows the breadth of the problems you can tackle with soft matter research. For years, my research group has focussed on rheology – the flow of materials – and with that comes microrheology, which is a really enabling method to study the stability and the viscosity of protein solutions. With protein therapeutics emerging in the market place we could help develop upstream processes to identify proteins and the best way to manufacture them. We have a project with industry on protein therapeutics that is a little more directed to engineering applications and actually getting things to market.

What’s your favourite piece of equipment in your lab?
It’s got to be the laser tweezers we’ve been using for the past 12 years. Picking things up with light never gets old. It’s one of those wacky things. We’ve used them in complex fluids to pull things apart and glue things together. Microscopy is an important technique for soft matter but to be able to go in and prod things – that adds an extra dimension. You can see what it looks like but what happens when I poke it?

Have you got a favourite material that you like to work with?
Colloids. Colloidal suspensions are so unique. They’re building blocks, they’re little rheometers, so many of the things we use on a day-to-day basis have a colloidal component.

What advice do you have for young scientists?
Look for opportunities. Look for the people who are going to mentor you. Watch what they do and remember that. Students and young people need to figure out what they’re excited about. Get in laboratories, discover things and ask questions.

Can you tell us a little known fact about yourself?
I really enjoyed being a radio DJ in my undergraduate and graduate days. Music has always been a tremendous part of my life. Breaking boundaries in music is a lot like science. You’re always asking, “what don’t I know?”

The interview with Eric Furst was first published in Chemistry World.
http://www.rsc.org/chemistryworld/2013/06/interview-eric-furst-soft-matter-rheology

Digg This
Reddit This
Stumble Now!
Share on Facebook
Bookmark this on Delicious
Share on LinkedIn
Bookmark this on Technorati
Post on Twitter
Google Buzz (aka. Google Reader)

Announcing Eric M. Furst as the 2013 Soft Matter Lectureship recipient

Eric M. Furst winner of the 2013 Soft Matter LectureshipThe Soft Matter Editorial Board have chosen Professor Eric M. Furst as the recipient of this year’s Soft Matter Lectureship. This annual Lectureship was established by the journal in 2009 to honour a younger scientist who has made a significant contribution to the soft matter field. We would like to thank everyone who nominated someone – as always there was an excellent group of candidates – and congratulate Professor Furst.

Eric M. Furst is a Professor of Chemical and Biomolecular Engineering and Director of the Center for Molecular Engineering and Thermodynamics at the University of Delaware. Furst received his BS with University Honors in Chemical Engineering from Carnegie Mellon University, his PhD from Stanford University, and afterwards studied biophysics as a Chateaubriand postdoctoral fellow at Institut Curie, Paris. His interests span a wide range of topics in soft matter science and engineering, but focus in particular on the physics and chemistry of the colloidal domain. Furst’s research group is recognized for their contributions to active and passive microrheology, biomaterial rheology, interfacial phenomena, directed self-assembly of colloids and nanoparticles, and colloid electrokinetics.

Digg This
Reddit This
Stumble Now!
Share on Facebook
Bookmark this on Delicious
Share on LinkedIn
Bookmark this on Technorati
Post on Twitter
Google Buzz (aka. Google Reader)

Introducing Soft Matter Associate Editor Jianbin Huang

Professor Jianbin Huang is interested in the research of the physical chemistry of surfactants, especially in mixed surfactant systems. The main work in his group is research on the molecular organized assemblies in aqueous solutions, such as vesicle or micelles. He is interested in vesicle formation in mixed cationic and anionic surfactant systems (including the mixed systems of ionic surfactant with oppositely charged polymer) and try to find:

a) the relations among the molecular structures of amphiphiles, properties of molecular organized assemblies and phase behavior of mixed surfactants;

b) the effective methods to adjust the phase behavior and micro-structure transition (i.e.transformation between vesicle to micelle) by the variation of environmental factors (for example, pH, salt and additives).

Some novel surfactants (such as some bola and Gemini amphiphiles) and the mixture of classical surfactant with them also fixed our eyes. The researches on the synthesis, aggregation behavior and interface properties in these kinds of surfactant systems are investigated in aqueous, non-aqueous and mixed solvents. Moreover, the applications of surfactant, especially mixed surfactant in detergent and daily use are also developed. As the first author or correspondence, Professor Huang has published over 40 articles in international and Chinese academic journals in the last five years.

His recent papers include:

A surfactant-assisted unimolecular platform for multicolor emissions
Soft Matter, 2012,8, 10472-10478

Extremely pH-sensitive fluids based on a rationally designed simple amphiphile

Soft Matter, 2012,8, 9079-9085

Self-assembled laminated nanoribbon-directed synthesis of noble metallic nanoparticle-decorated silica nanotubes and their catalytic applications
J. Mater. Chem., 2012,22, 18314-18320

Metal-driven hierarchical self-assembled zigzag nanoarchitectures with electrical conductivity
Chem. Commun., 2013,49, 704-706

Follow the latest journal news on Twitter @softmatter or go to our Facebook page.

Digg This
Reddit This
Stumble Now!
Share on Facebook
Bookmark this on Delicious
Share on LinkedIn
Bookmark this on Technorati
Post on Twitter
Google Buzz (aka. Google Reader)

Soft Matter Lectureship 2013: Nominations now open

Do you know someone who deserves recognition for their contribution to the soft matter field?

Now is your chance to propose they receive the accolade they deserve.

Soft Matter is pleased to announce that nominations are now being accepted for the Soft Matter Lectureship 2013.  This annual award was established by the journal in 2009 to honour a younger scientist who has made a significant contribution to the soft matter field.

Qualification

To be eligible for the Soft Matter Lectureship, the candidate should be in the earlier stages of their scientific career, typically within 15 years of attaining their doctorate or equivalent degree, and will have made a significant contribution to the field.

Description

The recipient of the award will be asked to present a lecture three times, one of which will be located in the home country of the recipient. The Soft Matter Editorial Office will provide the sum of £1000 to the recipient for travel and accommodation costs.

The award recipient will be presented with the award at one of the three award lectures. They will also be asked to contribute a lead article to the journal and will have their work showcased on the back cover of the issue in which their article is published.

Selection

The recipient of the award will be selected and endorsed by the Soft Matter Editorial Board.

Nominations

Those wishing to make a nomination should send details of the nominee, including a brief C.V. (no longer than 2 pages A4) together with a letter (no longer than 2 pages A4) supporting the nomination, to the Soft Matter Editorial Office (softmatter-rsc@rsc.org) by 28 February 2012.  Self nomination is not permitted.

Digg This
Reddit This
Stumble Now!
Share on Facebook
Bookmark this on Delicious
Share on LinkedIn
Bookmark this on Technorati
Post on Twitter
Google Buzz (aka. Google Reader)

Work by the 2011 Soft Matter Lectureship winner showcased in Soft Matter Issue 1, 2013

Work by the 2011 Soft Matter Lectureship winner, Dr Michael Solomon, is showcased on the back cover of Issue 1 of Soft Matter 2013. The cover highlights the research collaboration between Dr John Younger of the Department of Emergency Medicine and Dr Michael Solomon of the Department of Chemical Engineering at the University of Michigan, USA. Their paper ‘In situ rheology of Staphylococcus epidermidis bacterial biofilms’ is free to read for a short time.

Nominations for the 2013 Soft Matter Lectureship will be opening early next year. Stay tuned for more information.

Follow the latest journal news on Twitter @softmatter or go to our Facebook page.

To keep up-to-date with all the latest research, sign-up to our RSS feed or Table of contents alert.

Digg This
Reddit This
Stumble Now!
Share on Facebook
Bookmark this on Delicious
Share on LinkedIn
Bookmark this on Technorati
Post on Twitter
Google Buzz (aka. Google Reader)

Top 10 most-read Soft Matter articles in July

This month sees the following articles in Soft Matter that are in the top ten most accessed for July:

Mechanics and physics of hydrogels 
Jian Ping Gong, Wei Hong 
Soft Matter, 2012, 8, 8006-8007 
DOI: 10.1039/C2SM90083A  

Self-assembly scenarios of patchy colloidal particles 
Günther Doppelbauer, Eva G. Noya, Emanuela Bianchi and Gerhard Kahl  
Soft Matter, 2012, 8, 7768-7772 
DOI: 10.1039/C2SM26043C  

Super-tough double-network hydrogels reinforced by covalently compositing with silica-nanoparticles  
Qiang Wang, Ruixia Hou, Yajun Cheng and Jun Fu  
Soft Matter, 2012, 8, 6048-6056 
DOI: 10.1039/C2SM07233E  

Colloidal gelation of oppositely charged particles 
Emily R. Russell, Joris Sprakel, Thomas E. Kodger and David A. Weitz  
Soft Matter, 2012, 8, 8697-8703 
DOI: 10.1039/C2SM25901J 

Colloidal particles at the interface between an isotropic liquid and a chiral liquid crystal  
Anne C. Pawsey, Juho S. Lintuvuori, Tiffany A. Wood, Job H. J. Thijssen, Davide Marenduzzo and Paul S. Clegg  
Soft Matter, 2012, 8, 8422-8428 
DOI: 10.1039/C2SM25434D 

Microfluidic systems for single DNA dynamics  
Danielle J. Mai, Christopher Brockman and Charles M. Schroeder  
Soft Matter, 2012, 8, 10560-10572 
DOI: 10.1039/C2SM26036K  

Reversible adhesion between a hydrogel and a polymer brush  
Guillaume Sudre, Ludovic Olanier, Yvette Tran, Dominique Hourdet and Costantino Creton 
Soft Matter, 2012, 8, 8184-8193 
DOI: 10.1039/C2SM25868D  

Robust superomniphobic surfaces with mushroom-like micropillar arrays  
Seong Min Kang, Sang Moon Kim, Hong Nam Kim, Moon Kyu Kwak, Dong Ha Tahk and Kahp Y. Suh
Soft Matter, 2012, 8, 8563-8568 
DOI: 10.1039/C2SM25879J  

Statistical mechanics for static granular media: open questions  
Massimo Pica Ciamarra, Patrick Richard, Matthias Schröter and Brian P. Tighe 
Soft Matter, 2012, 8, 9731-9737 
DOI: 10.1039/C2SM06898B  

Controlling the self-assembly pathways of amphiphilic block copolymers into vesicles  
Mengying Xiao, Guangjie Xia, Rong Wang and Daiqian Xie  
Soft Matter, 2012, 8, 7865-7874 
DOI: 10.1039/C2SM25281C  

Why not take a look at the articles today and blog your thoughts and comments below.

Fancy submitting an article to Soft Matter? Then why not submit to us today!

To keep up-to-date with all the latest research, sign up for the Soft Matter e-Alert or RSS feeds or follow Soft Matter on Twitter or Facebook.

Digg This
Reddit This
Stumble Now!
Share on Facebook
Bookmark this on Delicious
Share on LinkedIn
Bookmark this on Technorati
Post on Twitter
Google Buzz (aka. Google Reader)

Making a splash

When a droplet impacts on a solid surface it deforms. Depending on the properties of the drop and the surface (velocity, viscosity, surface tension, hydrophobicity etc.) this deformation can be temporary, the droplet spreads out before retracting and bouncing back, or permanent, the drop breaks apart on impact making a splash.

Air also plays an important role in determining the behaviour of the impacting drop. Detlef Lohse, University of Twente, is interested in understanding how and why the air layer profile under a drop influences its deformation as it falls and subsequently hits a surface. His group has developed an ultra-high speed colour interferometry imaging method, allowing them to resolve the dynamics of an impacting drop on short timescales. Using this method, Lohse has been able to measure the time evolution of the drop before and during impact on a solid surface. As the drop falls the air between the drop and surface is strongly squeezed. A region of high pressure builds up, which leads to the formation of a dimple on the underside of the drop. At high velocities this can result in splashing as the air is compressed on impact. The presence of an air bubble can also stop the droplet from touching the surface at all leading to some interesting effects.

When a liquid droplet impacts a surface heated above the liquid’s boiling point three impact behaviour regimes are observed. In the first, ‘contact boiling’, the droplet immediately boils as it comes into contact with the surface. The droplet contacts the surface and spreads out. Bubbles then form and the liquid evaporates. For ‘gentle film boiling’ the droplet appears to hit the surface before bouncing back. In this regime a Leidenfrost vapour layer forms under the drop before it hits, preventing it from coming into direct contact with the surface. The final behavioural regime is ‘spray film boiling’. In this case, although the droplet does not contact the surface, breakup does occur. A Leidenfrost vapour layer forms below the drop. As the vapour tries to escape it drags fluid out with it and the droplet forms a thinner pancake shape. Tiny drops are the ejected upwards in what can be quite a violent spray event. The impact conditions under which each regime can be observed were recently published in Physical Review Letters.

Lohse has also looked at how the structure of the surface can influence the splashing dynamics for high velocity impacting drops. In this case the surfaces are all at room temperature. This is discussed in detail for Newtonian and non-Newtonian liquids in two recent Soft Matter papers. Directional splashing can be tuned and suppressed by varying the periodicity of the lattice and, or the air pressure. A number of videos of the impacting drops can be found in the supplementary information accompanying the Soft Matter article and are well worth a look.

Digg This
Reddit This
Stumble Now!
Share on Facebook
Bookmark this on Delicious
Share on LinkedIn
Bookmark this on Technorati
Post on Twitter
Google Buzz (aka. Google Reader)

Soft Matter paper appears in BBC News story – Read for free until October 26th!

A Soft Matter paper by groups from the Centre of Molecular Materials for Photonics and Electronics and the Inkjet Research Centre at the University of Camrbidge has appeared in a BBC News story. The paper describes the inkjet printing of liquid crystals on to a wet, solution-based polymer with precise control over droplet size.

Printed photonic arrays from self-organized chiral nematic liquid crystals
D. J. Gardiner, W.-K. Hsiao, S. M. Morris, P. J. W. Hands, T. D. Wilkinson, I. M. Hutchings and H. J. Coles, Soft Matter, 2012, 8, 9977.

The BBC news story can be found here.

Don’t forget to keep up-to-date with all the latest research you can sign-up for the Soft Matter RSS feed or Table of contents alert.

To keep up with the journal news you can Like us on Facebook or Follow us on Twitter.

Digg This
Reddit This
Stumble Now!
Share on Facebook
Bookmark this on Delicious
Share on LinkedIn
Bookmark this on Technorati
Post on Twitter
Google Buzz (aka. Google Reader)