Update to article guidelines

All Molecular Systems Design & Engineering articles must now include a separate paragraph (no more than 200 words) that:

  • explains the molecular design or optimisation strategy and its general utility
  • emphasizes the desired systems functionality and design constraints
  • highlights the immediate or future application potential of the work.

This paragraph is intended to be accessible to the broad interdisciplinary readership of the journal, and therefore should be written in a general manner to complement more detailed discussions of these aspects within the main text. It should not reproduce the abstract.

For more information please see the journal homepage, or if you have any questions get in touch by email.

When will I see a change?
This change has taken effect from now and is applicable for all submissions. The text will appear in a new ‘Design, System, Application’ box on the first page of all articles, excluding those currently published.

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First Advance Articles published

We are delighted to announce publication of the first Advance Articles in Molecular Systems Design & Engineering. Some of the first articles in the journal include:

Capture and immobilisation of iodine (I2) utilising polymer-based ZIF-8 nanocomposite membranes
E. M. Mahdi, Abhijeet K. Chaudhuri and Jin-Chong Tan
Paper

Polymer nanocomposites made up of nanoporous metal–organic frameworks (MOFs) are fast becoming a staple of next generation hybrid composites, and are currently being intensely developed for gas capture and separation.

Microparticulate/nanoparticulate powders of a novel Nrf2 activator and an aerosol performance enhancer for pulmonary delivery targeting the lung Nrf2/Keap-1 pathway
Priya Muralidharan, Don Hayes, Stephen M. Black and Heidi M. Mansour
Paper

Solid-state respirable particle engineering design, physicochemical characterization, & in vitro aerosolization of advanced microparticulate/nanoparticulate dry powder inhalers targeting the lung Nrf2/Keap-1 pathway.

Charge generation in organic photovoltaics: a review of theory and computation
Kenley M. Pelzer and Seth B. Darling
Review

One of the most important factors in determining organic photovoltaic device performance is the efficiency of exciton dissociation and charge separation at donor/acceptor heterojunctions. This review discusses theoretical and computational approaches to modeling this crucial process of charge generation.

Molecular engineering of cyanine dyes to design a panchromatic response in co-sensitized dye-sensitized solar cells
Giulio Pepe, Jacqueline M. Cole, Paul G. Waddell and Scott McKechnie
Paper

Cyanines are optically tunable dyes with high molar extinction coefficients, suitable for applications in co-sensitized dye-sensitized solar cells (DSCs); yet, barely thus applied.

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Introducing the Molecular Systems Design & Engineering Editorial Board

We are guided by an expert Editorial Board of world renowned scientists and engineers, ensuring that Molecular Systems Design & Engineering is truly positioned to help build and support an emerging molecular engineering community.  Each member brings a wealth of expertise in their own aspect of molecular engineering, contributing to an overall vision for the future of the field.

Juan de Pablo

© University of Chicago

Juan de Pablo is Liew Family Professor in Molecular Engineering at the University of Chicago’s Institute for Molecular Engineering, USA, and Molecular Systems Design & Engineering Editorial Board Chair. His research involves theory and simulation at a molecular level, studying the properties of molecules and how they can be assembled in an organised manner to have specific functions. His work with Paul Nealey into block copolymer self-assembly has proved a crucial development for the semiconductor industry. He also studies protein and DNA folding, glassy materials, and liquid crystals. See his recent papers in Soft Matter:

Homeotropic nano-particle assembly on degenerate planar nematic interfaces: films and droplets, Alejandro Londoño-Hurtado, Julio C. Armas-Pérez, Juan P. Hernández-Ortiz and Juan J. de Pablo, Soft Matter, 2015, 11, 5067–5076;

A molecular view of the role of chirality in charge-driven polypeptide complexation, K. Q. Hoffmann, S. L. Perry, L. Leon, D. Priftis, M. Tirrell and J. J. de Pablo, Soft Matter, 2015, 11, 1525–1538.

Professor de Pablo’s work is partially motivated by solving some of the major technological and humanitarian challenges of our time, but equally by a fascination for working on fundamental problems and developing a better understanding of nature. His recent interview in Chemistry World explains how his institute is structured to drive the connection between the two. He is a fellow of the AAAS and the APS, and received the 2011 Charles Stine Award from the American Institute of Chemical Engineers.


Samson Jenekhe Samson Jenekhe is Boeing-Martin Professor of Chemical Engineering and Professor of Chemistry at the University of Washington, USA, and a Scientific Editor for Molecular Systems Design & Engineering, helping to ensure that articles meet the stringent criteria required for publication in the journal. His expertise lies in polymers – their design, synthesis and assembly; understanding and control of their electronic and photonic properties; and their implementation in device applications. Take a look at his work in ChemComm:

Side chain engineering of n-type conjugated polymer enhances photocurrent and efficiency of all-polymer solar cells, Ye-Jin Hwang, Taeshik Earmme, Selvam Subramaniyan and  Samson A. Jenekhe, Chem. Commun., 2014, 50, 10801–10804.

Professor Jenekhe was named by Thomson Reuters as one of the top 100 materials scientists of the decade (2000–2010), and also received the 2014 Charles Stein Award from the American Institute of Chemical Engineers.


Niren MurthyNiren Murthy is Professor in the Department of Bioengineering at the University of California at Berkeley, USA, and a Scientific Editor for Molecular Systems Design & Engineering, helping to ensure that articles meet the stringent criteria required for publication in the journal.  His research is focused on the development of new molecules and materials for molecular imaging and drug delivery.  A new class of fluorescent probes – hydrocyanines – that can be used to detect reactive oxygen species (ROS) in vivo and in vitro have been developed in his lab. His recent ChemComm article presents a new polyketal type polymer with application in gene and drug delivery:

A biodegradable adamantane polymer with ketal linkages in its backbone for gene therapy, Santanu Maity, Priya Choudhary, Manu Manjunath, Aditya Kulkarni and Niren Murthy, Chem. Commun., 2015, 51, 15956–15959.

Professor Murthy’s hydrocyanine ROS probes are now commercially available under the name ROSstar.


David AwschalomDavid Awschalom is Liew Family Professor in Molecular Engineering at the University of Chicago’s Institute for Molecular Engineering, USA, and a Molecular Systems Design & Engineering Editorial Board Member. He is a leading authority in the field of spintronics – understanding and using electron spin behaviour in solid state systems for device applications in areas such as quantum information and sensing. He also studies optical and magnetic phenomena in semiconductors and nanoscale structures. Among numerous awards, he was the recipient of the American Physical Society’s 2015 Julius Edgar Lilienfield Prize for his research into the physics of spin-coherent materials and systems, ‘as well as his superb lecturing on these topics to diverse audiences. A great example of this is his recent talk at Physics@FOM on ‘Abandoning Perfection for Quantum Technolgies‘. Professor Awschalom is a fellow of the American Physical Society and the American Associate for the Advancement of Science.


Claire AdjimanClaire Adjiman is Professor of Chemical Engineering at Imperial College London, UK, and a Molecular Systems Design & Engineering Editorial Board Member. Her research focuses on how molecular-level considerations can be brought into process design through modelling and optimisation – for example, some of her recent work uses a combination of quantum mechanical calculations and computer aided molecular design to determine an optimal solvent that increases the rate of a chemical reaction. She is a co-director of the Institute for Molecular Science and Engineering, which targets solving problems related to the world’s grand challenges through molecular innovation. Take a look at her inaugural lecture from 2013: ‘Molecules on Best Behaviour: The Engineering of Molecular Systems‘. Professor Adjiman is the recipient of an EPSRC Leadership Fellowship until 2017 as a future global research leader.


Marcus MuellerMarcus Müller is Professor at the Institute for Theoretical Physics, Göttingen, Germany, and a Molecular Systems Design & Engineering Editorial Board Member. He studies the physics of soft matter, including polymer solutions, molecular self-assembly, wetting phenomena and biological problems, using computational simulation and numerical methods. His recent Soft Matter paper looks at the process of dynamin-mediated membrane fission at molecular resolution using a coarse-grained model:

Coarse-grained simulation of dynamin-mediated fission, Marc Fuhrmans and Marcus Müller, Soft Matter, 2015, 11, 1464–1480.

Professor Müller was a previous winner of the John H. Dillon Medal of the American Physical Society for outstanding accomplishment and unusual promise in research in polymer physics.


Paul RaithbyPaul Raithby is Professor of Inorganic Chemistry at the University of Bath, UK, and a Molecular Systems Design & Engineering Editorial Board Member. His research interests lie in materials design – connecting the molecular structure of materials and their properties – across areas including crystallography, organometallic oligomers & polymers and transition metal clusters & catalysts. Read his work on the behaviour of molecular switches with potential as piezochromic sensors in CrystEngComm:

High-pressure crystallographic and spectroscopic studies on two molecular dithienylethene switches, Christopher H. Woodall, Simon K. Brayshaw, Stefanie Schiffers, David R. Allan, Simon Parsons, Rafael Valiente and Paul R. Raithby, CrystEngComm, 2014, 16, 2119–2128.

Professor Raithby is Principle Investigator for the EPSRC Directed Assembly Network grant, with over 1000 academic and industry members developing control over the production of materials and substances with targeted properties.

To keep up with the news from Molecular Systems Design & Engineering, including the latest Editorial Board appointments, be sure to sign up to our e-alerts and follow us on Twitter.

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Juan de Pablo on molecular engineering

Juan de Pablo

Chemistry World has spoken to Molecular Systems Design & Engineering‘s Editorial Board Chair Professor Juan de Pablo about the evolution and potential of molecular engineering. He argues that the field is about to explode due to newly gained knowledge and alternative modes of researcher organisation and collaboration.

Read the full article here.

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Sign up for the Molecular Systems Design & Engineering Email Alerts

email alerts

The Molecular Systems Design & Engineering Email Alerts are a great way to find out about all the latest news and content from the journal.

We’ll let you know as soon as our first advanced articles are published, as well as other important developments, so be sure to sign up now.

Table of contents alerts for the latest issue of the journal will begin once we have published our first issue.

Don’t forget you can also follow us on Twitter to keep fully up to date.

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Submit now to make the first issue of Molecular Systems Design & Engineering

Issue 1 of Molecular Systems Design & Engineering is due to be published in 2016.

Make sure you have the chance to be included – submit now so that we can consider your work for the inaugral issue.

Submit

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The emerging field of molecular engineering

Logos

Molecular Systems Design & Engineering, the unique home for pioneering molecular engineering research, is now open for submissions.

MSDE coverA joint venture between the Royal Society of Chemistry and IChemE, the journal’s mission is to forge links between disciplines and accelerate advance in molecular engineering by publishing reports of outstanding significance from all those using and developing molecular-level design and control.

What is molecular engineering?

I think our ability to manipulate, understand, simulate and control matter at molecular length scales has increased dramatically over the last several decades. Certainly nanotechnology is all about controlling matter at nanometre length scales, and I think what comes now with that ability – that newly gained ability – is the possibility of building devices, systems and functional materials that serve a purpose on the basis of molecular principles. That’s what I would call molecular engineering, says Editorial Board Chair Professor Juan de Pablo, from the University of Chicago’s Institute for Molecular Engineering. He identifies three elements that are characteristic of molecular engineering research:

  • a design approach, which requires understanding and control;
  • the goal of building or assembling a useful system such as a material or device;
  • and, of course, doing both of these things at a very small length scales.

The work is often highly interdisciplinary because of the breadth of knowledge, expertise and equipment required to include each of these aspects.

I don’t think there is a journal right now that really combines all of these elements, so I think that this journal will help us popularise this way of working, and the new field that we call molecular engineering– Prof. Juan de Pablo.

Molecular engineering across the Royal Society of Chemistry

We’ve put together a collection of some key molecular engineering research from across the Royal Society of Chemistry, which we hope you enjoy reading. After you’re done, why not explore the scope of Molecular Systems Design & Engineering and send us your own best molecular engineering research now for the chance of being included in our very first issue?

Side chain engineering of n-type conjugated polymer enhances photocurrent and efficiency of all-polymer solar cells, Ye-Jin Hwang, Taeshik Earmme, Selvam Subramaniyan and Samson A. Jenekhe, Chem. Commun., 2014, 50, 10801–10804.

Digital colloids: reconfigurable clusters as high information density elements, Carolyn L. Phillips, Eric Jankowski, Bhaskar Jyoti Krishnatreya, Kazem V. Edmond, Stefano Sacanna, David G. Grier, David J. Pine and Sharon C. Glotzer, Soft Matter, 2014, 10, 7468–7479.

Emulsion-templated silica nanocapsules formed using bio-inspired silicification, David Wibowo, Chun-Xia Zhao and Anton P. J. Middelberg, Chem. Commun., 2014, 50, 11325–11328.

Biodegradable glycopolymer-b-poly(ε-caprolactone) block copolymer micelles: versatile construction, tailored lactose functionality, and hepatoma-targeted drug delivery, Wei Chen, Fenghua Meng, Ru Cheng, Chao Deng, Jan Feijen and Zhiyuan Zhong, J. Mater. Chem. B, 2015, 3, 2308–2317.

Rational molecular designs for drastic acceleration of the color-fading speed of photochromic naphthopyrans, Katsutoshi Arai, Yoichi Kobayashi and Jiro Abe, Chem. Commun., 2015, 51, 3057–3060.

Mechanical properties of self-assembled nanoparticle membranes: stretching and bending, Yifan Wang, Pongsakorn Kanjanaboos, Sean P. McBride, Edward Barry, Xiao-Min Lin and Heinrich M. Jaeger, Faraday Discuss., 2015, 181, 325–338.

A photoswitchable supramolecular complex with release-and-report capabilities, Jesper R. Nilsson, Melanie C. O’Sullivan, S. Li, Harry L. Anderson and Joakim Andréasson, Chem. Commun., 2015, 51, 847–850.

Inhibition of atherosclerosis-promoting microRNAs via targeted polyelectrolyte complex micelles, Cheng-Hsiang Kuo, Lorraine Leon, Eun Ji Chung, Ru-Ting Huang, Timothy J. Sontag, Catherine A. Reardon, Godfrey S. Getz, Matthew Tirrell and Yun Fang, J. Mater. Chem. B, 2014, 2, 8142–8153.

To keep up with the latest news from Molecular Systems Design & Engineering, be sure to sign up to our e-alerts and follow us on twitter @RSC_MolEng.

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A first in its field

Announcing Molecular Systems Design & Engineering

It’s not often that a new journal can claim to be unique in its field. So we are delighted to announce Molecular Systems Design & Engineering – a truly interdisciplinary, international and high-impact journal bringing together biology, chemistry, physics, engineering, computational and materials science.

The journal will look at how understanding molecular properties, behaviour and interactions can be used to design better systems and processes for a desired effect or specific application to solve technological problems of global significance. Launched jointly by the Royal Society of Chemistry and the Institution of Chemical Engineers (IChemE), it combines the expertise and commitment of two influential organisations.

The journal will cover both experimental and theoretical research in:

  • the design and characterisation of molecules and systems of molecules;
  • modelling molecular system behaviours that inspire new molecular designs for engineering applications; and
  • constraints that impact systems’ functionality.

Molecular Systems Design & Engineering will be led by our innovative Editorial Board Chair, Juan de Pablo (The Institute for Molecular Engineering, the University of Chicago), assisted by an expert team of active researchers in the field.

Why publish your research with us?

At the Royal Society of Chemistry, our proven record in launching new and ground-breaking titles speaks for itself. We aim high, and our impressive, high-impact journal portfolio is testament to our success.

And high-impact research demands high visibility. So all content published in Molecular Systems Design & Engineering in 2016 and 2017 will be free to access upon registration – offering you maximum exposure for your work.

Be first in the first

Molecular Systems Design & Engineering is now accepting submissions for its first issues in 2016. Submit your work now for your chance to be included.

We’ll be sharing more news soon – so make sure you stay up to date with our Email Alerts Service.

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