Malika Jeffries-EL selects her Editor’s Choice in organic electronics

Chemical Science welcomes our newest Associate Editor, Professor Malika Jeffries-EL, who brings a wealth of experience in organic electronics and functional materials to Chemical Science.

Malika recently came to the end of her time as an Associate Editor for Journal of Materials Chemistry C and Materials Advances and, in celebration of her joining the Editorial Board for Chemical Science, she has selected her Editor’s Choice from papers published in Chemical Science, Journal of Materials Chemistry C and Materials Advances. We hope you enjoy reading through this selection!

Malika Jeffries-EL

 

You can explore the full collection of papers that are in Malika’s Editor’s Choice here!

Highlighted articles include:

A cell membrane-targeting AIE photosensitizer as a necroptosis inducer for boosting cancer theranostics
Niu Niu, Ying Yu, Zhijun Zhang, Miaomiao Kang, Lei Wang, Zheng Zhao, Dong Wang and Ben Zhong Tang
Chem. Sci., 2022, 13, 5929-5937

Detection of multi-reference character imbalances enables a transfer learning approach for virtual high throughput screening with coupled cluster accuracy at DFT cost
Chenru Duan, Daniel B. K. Chu, Aditya Nandy and Heather J. Kulik
Chem. Sci., 2022, 13, 4962-4971

Acenaphthene-triphenylamine (acceptor-donor) based luminophores for organic light emitting diodes: combined experimental and theoretical study
Jairam Tagare, Aravind Babu Kajjam, Kasturi Singh, Sabita Patel and Sivakumar Vaidyanathan
Mater. Adv., 2022, 3, 399-408

Synthesis and photoswitchable amphiphilicity and self-assembly properties of photochromic spiropyran derivatives
Yiwei Zhang, Maggie Ng, Eugene Yau-Hin Hong, Alan Kwun-Wa Chan, Nathan Man-Wai Wu, Michael Ho-Yeung Chan, Lixin Wu and Vivian Wing-Wah Yam
J. Mater. Chem. C, 2020, 8, 13676-13685

Open-circuit-voltage shift of over 0.5 V in organic photovoltaic cells induced by a minor structural difference in alkyl substituents
Mitsuharu Suzuki, Kengo Terai, Cassandre Quinton, Hironobu Hayashi, Naoki Aratani and Hiroko Yamada
Chem. Sci., 2020,11, 1825-1831

 

We encourage you to submit your best work in organic electronics and functional materials to Malika and our team of Associate Editors now! Check out the Chemical Science author guidelines for more information.

 

Chemical Science, Royal Society of Chemistry

 

Keep up to date with our latest articles, reviews, collections & more by following us on Twitter. You can also keep informed by signing up to our E-Alerts.

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Chemical Science HOT Articles: October 2022

We are pleased to share a selection of our referee-recommended HOT articles for October 2022. We hope you enjoy reading these articles, congratulations to all the authors whose articles are featured! As always, Chemical Science is free for authors and readers.

You can explore our full 2022 Chemical Science HOT Article Collection here!

 

Browse a selection of our October HOT articles below:

Discovery of a monomeric green fluorescent protein sensor for chloride by structure-guided bioinformatics
Weicheng Peng, Caden C. Maydew, Hiu Kam, Jacob K. Lynd, Jasmine N. Tutol, Shelby M. Phelps, Sameera Abeyrathna, Gabriele Meloni and Sheel C. Dodani
Chem. Sci., 2022, Advance Article

Impact of a polymer modifier on directing the non-classical crystallization pathway of TS-1 zeolite: accelerating nucleation and enriching active sites
Jiani Zhang, Risheng Bai, Yida Zhou, Ziyi Chen, Peng Zhang, Jiyang Li and Jihong Yu
Chem. Sci., 2022, Advance Article

A broadly applicable quantitative relative reactivity model for nucleophilic aromatic substitution (SNAr) using simple descriptors
Jingru Lu, Irina Paci and David C. Leitch
Chem. Sci., 2022, Advance Article

Tandem electrocatalytic CO2 reduction with Fe-porphyrins and Cu nanocubes enhances ethylene production
Min Wang, Vasilis Nikolaou, Anna Loiudice, Ian D. Sharp, Antoni Llobet and Raffaella Buonsanti
Chem. Sci., 2022, Advance Article

Anthranilamide-protected vinylboronic acid: rational monomer design for improved polymerization/transformation ability providing access to conventionally inaccessible copolymers
Hiroshi Suzuki, Tsuyoshi Nishikawa, Hiroshi Makino and Makoto Ouchi
Chem. Sci., 2022, Advance Article

Controlling the fluorescence quantum yields of benzothiazole-difluoroborates by optimal substitution
Patryk Rybczyński, Manon H. E. Bousquet, Anna Kaczmarek-Kędziera, Beata Jędrzejewska, Denis Jacquemin and Borys Ośmiałowski
Chem. Sci., 2022, Advance Article

 

Chemical Science, Royal Society of Chemistry

Submit to Chemical Science today! Check out our author guidelines for information on our article types or find out more about the advantages of publishing in a Royal Society of Chemistry journal.

Keep up to date with our latest articles, reviews, collections & more by following us on Twitter. You can also keep informed by signing up to our E-Alerts.

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Chemical Science welcomes Professor Malika Jeffries-EL as a new Associate Editor

We wish a very warm welcome to our new Chemical Science Associate Editor Malika Jeffries-EL.

Malika Jeffries-EL

 

Malika Jeffries-EL was born in Brooklyn, New York and attended Wellesley College for her Bachelor’s degree and The George Washington University for masters and doctorate degrees. Malika then worked as a post-doctoral fellow under the direction of Professor Richard D. McCullough at Carnegie Mellon University, where she developed her interest in organic electronics. Malika started her research group at Iowa State University and then moved it to Boston University in 2016. Since July 2020 she has also served as the Associate Dean of the Graduate School in Arts and Sciences.

Malika’s research focuses on the design and synthesis of organic semiconductors for use in OLEDs and OPVs. In recognition of her group’s research, she has received the 2012 Rising Star Award from the ACS Women Chemists Committee, the 2013 Iota Sigma Pi Agnes Fay Morgan Award, and the 2021 Percy Julian Award from the National Organization of Black Chemist and Chemical Engineers (NOBCChE), among many others. Malika is also a Fellow of the American Chemical Society, and a Fellow of the Royal Society of Chemistry. Prior to joining Chemical Science in 2022, Malika was an Associate Editor for Journal of Materials Chemistry C from 2013 to 2022.

Please join us in welcoming Professor Malika Jeffries-EL to the Chemical Science as an Associate Editor. We encourage you to submit your best work to Malika and our team of Associate Editors now! Please see the Chemical Science author guidelines for more information on our article types.

 

Check out some of Malika Jeffries-EL’s publications in Royal Society of Chemistry journals:

Two-dimensional benzo[1,2-b:4,5-b′]difurans as donor building blocks for the formation of novel donor–acceptor copolymers
Carmen L. Gott-Betts , Alfred A. Burney-Allen , David L. Wheeler and Malika Jeffries-EL
Mater. Adv., 2022, 3, 4831-4838

A computational and experimental investigation of deep-blue light-emitting tetraaryl-benzobis[1,2-d:4,5-d′]oxazoles
D. Wheeler, S. Tannir, E. Smith, A. Tomlinson and M. Jeffries-EL
Mater. Adv., 2022, 3, 3842-3852

Benzobisoxazole cruciforms: a tunable, cross-conjugated platform for the generation of deep blue OLED materials
Ramiro Chavez III, Min Cai, Brian Tlach, David L. Wheeler, Rajiv Kaudal, Ayuna Tsyrenova, Aimée L. Tomlinson, Ruth Shinar, Joseph Shinar and Malika Jeffries-EL
J. Mater. Chem. C, 2016, 4, 3765-3773

 

Chemical Science, Royal Society of Chemistry

Submit to Chemical Science today! Check out our author guidelines for information on our article types or find out more about the advantages of publishing in a Royal Society of Chemistry journal.

Keep up to date with our latest articles, reviews, collections & more by following us on Twitter. You can also keep informed by signing up to our E-Alerts.

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Chemical Science Reviewer Spotlight – October 2022

By .

To further thank and recognise the support from our excellent reviewer community, we are highlighting reviewers who have provided exceptional support to the journal over the past year.

This month, we’ll be highlighting Wade Petersen, Pachaiyappan Rajamalli, Shikha Dhiman and Daniel Gryko. We asked our reviewers a few questions about what they enjoy about reviewing, and their thoughts on how to provide a useful review.

Wade Petersen, University of Cape Town. Dr. Petersen’s work aims to develop low-cost chemical synthesis methods for accessing biologically important heterocycles.

 

Pachaiyappan Rajamalli, Indian Institute of Science, Bangalore. Pachaiyappan works on organic electronics, mainly focusing on the development of organic functional materials for organic light-emitting diodes.

 

Shikha Dhiman, Eindhoven University of Technology. Shikha investigates the structure-function-dynamics relationship of supramolecular polymers utilising advanced techniques such as super-resolution imaging to optimise their potential applications.

 

Daniel Gryko, Institute of Organic Chemistry – Polish Academy of Sciences. Professor Gryko is trying to discover novel functional dyes possessing better photophysical properties compared to existing ones. They could find applications in organic optoelectronics including organic light-emitting diodes.

 

 

What encouraged you to review for Chemical Science?

Shikha Dhiman: Chemical Science focuses on high-quality, multidisciplinary research, and reviewing is one component of my service to the scientific community in assessing and improving the quality of articles.

Daniel Gryko: The exceptionally high level of science which is published regularly in Chemical Science.

 

What do you enjoy most about reviewing?

Wade Petersen: I enjoy getting a ’sneak peak’ into the latest work by the scientific community as well as playing a small part in improving the manuscript (where possible) by offering some suggestions. It is also wonderful to see authors taking on this advice in the published version of the manuscript. It certainly makes your effort worthwhile and is energising to want to review again.

 

What advice would you give a first-time author looking to maximise their chances of successful peer review?

Pachaiyappan Rajamalli: Your work should be unique, and good clarity in your writing will enhance the success rate. 

Daniel Gryko: First of all make sure you Conclusions section contains real conclusions rather than another rephrased version of your abstract. Secondly, the manuscript has to contain comparisons with the state of the art. This is especially true for synthetic manuscripts and papers focused on functional dyes. Last, but definitely not least, see if you can summarize the novelty in two sentences only. That truly helps with self-evaluation of the manuscript.

 

Do you have any advice to our readers seeking publication in Chemical Science on what makes a good paper?

Shikha Dhiman: Readers are drawn in by a clear and intriguing abstract that highlights the substantial contribution made along with self-explanatory figures. Following that, the contribution, which is supported by properly conducted experiments, appropriately interpreted data, and an essential outlook for the reader, completes a good story.

 

What would you recommend to new reviewers to ensure their report is helpful?

Pachaiyappan Rajamalli: The report should clearly indicate your decision whether to accept or reject it. Check for the novelty of the work, if the work is novel, please give your input to improve the manuscript.

 

What has been your biggest learning point from reviewing?

Wade Petersen: The true value that you can add to authors in improving their work for publication. It is easy to simply say ’no’. But offering a detailed review on how the work can be improved for successful review really is a great service to the both the authors and to the community as a whole.

 

Tune in next month to meet our next group of #ChemSciReviewers!

 

If you want to learn more about how we support our reviewers, check out our Reviewer Hub.

Interested in joining our ever-growing reviewer community? Apply here now!

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Highlighting our #MyFirstChemSci

Recently, Chemical Science author Professor E. W. Bert Meijer (Eindhoven University of Technology, The Netherlands) sent us a video which showcased his first paper published in Chemical Science ‘Macrocyclization of enzyme-based supramolecular polymers, Chem. Sci., 2010,1, 79-88’ (https://doi.org/10.1039/C0SC00108B).

His paper was also the first paper published online in Chemical Science when the journal launched in 2010.

 

Thanks to Professor Meijer for sharing the video with us!

 

Chemical science logo

Keep up to date with our latest articles, reviews, collections & more by following us on Twitter. You can share your first Chemical Science publication by posting on Twitter with the hashtag #MyFirstChemSci.

 

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Multifunctional materials from tuneable nanoparticles

Metal-organic framework (MOF) nanoparticles combine with carbon microfibres to make large-scale materials with many possible applications

Assembling very small-scale nanoparticles into larger structures, commonly known as macroarchitectures, offers opportunities to exploit the nanoparticles’ unique chemical and physical properties while they are embodied within much larger components. Researchers in China, Australia and Japan developed a method that readily combines nanoparticles called metal-organic frameworks (MOFs) and micron-sized carbon fibres into versatile macroarchitecture materials.

The team, at Nanjing University of Science and Technology, China, the University of Queensland, Australia and the JST-ERATO Yamauchi Materials Space Tectonics Project, Japan, report their innovation in an article in the open access journal Chemical Science.

“While retaining the characteristics of the nanomaterial they are built from, our macroarchitectures also add in many new kinds of features such as high surface areas, high mechanical strength and low density,” says Professor Yusuke Yamauchi of the University of Queensland group.

From nano to macro in a simpler process

The manufacturing procedure begins with the MOF nanoparticles, which consist of metal ions or metallic clusters connected by organic (carbon-based) linker groups. Varying the metallic and organic components can generate a wide variety of MOFs with different chemical and physical properties.

The MOFs are then combined with hollow carbon-based fibres to form much larger centimetre-scale aerogels, which are highly porous and have extremely low densities. These unique materials can be generated in a variety of desired shapes, and possess great elasticity and compressibility, combined with chemical stability and physical strength.

Existing methods for making similar materials are problematic as their assembly usually yields products with relatively poor mechanical properties, and requires the use of adhesives or templates which have to be removed in additional steps. In contrast, the new method causes ‘zeolitic imidazolate framework (ZIF-8)-polyacrylonitrile nanofibers’ to directly assemble into centimetre-sized aerogels with controllable shapes and tuneable properties.

“The materials integrate the properties of one-dimensional nanofibers and three-dimensional carbon aerogels,” says Yamauchi.

Many possible uses

The macroarchitectures composed of three-dimensional porous interconnected networks could have commercial applications in many fields. The initial key to unlocking a wide range of practical uses is to design MOF structures that will achieve specific functions in each resulting aerogel. These could involve adsorbing specific chemicals into the pores of the final structure, catalysing chemical processes, or converting and storing energy, including electrical energy within capacitors.

Laboratory-scale trials have already demonstrated that some of the porous structures – which the researchers describe as “somewhat resembling that of a loofah sponge” – have impressive oil-retaining properties when exposed to mixtures of oil and water. This effect could be exploited to clean oil from polluted water. One version of the materials also has catalytic properties that could be useful for chemically degrading a variety of other pollutants.

The aerogels also have an impressive ability to absorb light and convert it into heat at high efficiency, which could be used to prepare drinkable water by desalinating seawater. “We believe that in the future our materials could be used for several large-scale and cost-effective water purification applications,” says Yamauchi.

The researchers now aim to develop the potential for moving from laboratory scale proof-of-concept demonstrations to commercially useful applications.

Chemical Science is open and free for both readers and authors.

Article details:

Zhang, Z. et al: “Modular assembly of MOF-derived carbon nanofibers into macroarchitectures for water treatment.” Chem. Sci., 2022, 13, 9159-9164

nano particles to new multifunctional macroarchitectures infographic

 

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Chemical Science Reviewer Spotlight – September 2022

To further thank and recognise the support from our excellent reviewer community, we showcase reviewers who have provided exceptional support to the journal over the past year.

This month, we are highlighting Christoforos Kokotos, Joanna Wencel-Delord, Rosana Álvarez Rodríguez and Joaquin Barroso. We asked our reviewers a few questions about what they enjoy about reviewing, their experiences with Chemical Science and also for some tips about how to provide a useful review and also what they look for in a manuscript.

Christoforos Kokotos, University of Athens.  The research group of Christoforos focuses on asymmetric organocatalysis, the organocatalytic activation of small molecules, like H22, for oxidation reactions and organic photochemistry, especially applications in the synthesis of pharmaceuticals, agrochemicals, or the discovery of novel medicinal agents.

Joanna Wencel-Delord, University of Strasbourg. Joanna is interested in developing original, straightforward, and efficient synthetic routes to construct complex (chiral) molecules. Her research focuses on various approaches such as C-H activation, 3d-metal catalysis, and the chemistry of rare hypervalent compounds.

Rosana Álvarez Rodríguez, University of Vigo.  Rosana’s research focuses on stereoselective synthesis of biologically active natural products through the use of novel synthetic tools with their mechanisms studied through both experimental and computational techniques.

Joaquin Barroso, National Autonomous University of Mexico. Joaquin’s group uses computers to pose and solve the appropriate equations that describe the chemical reality of various phenomena, with an emphasis in trying to understand how molecules transfer energy between them once they absorb sunlight during photosynthesis.

 

What encouraged you to review for Chemical Science?

Christoforos Kokotos:  Chemical Science is a high-quality interdisciplinary journal that publishes cutting edge research, and usually publishes research that I am highly interested in. Reviewing gives you the opportunity to help the authors improve their work and as a reviewer you can ask for clarifications in points that are not clear in the original submission. Also, I have a special connection to Chemical Science, since I was a member of David MacMillan’s group during the period that Chemical Science was preparing to get launched and I remember the excitement and thrill in the research group. [Editor’s note: David MacMillan was the first Editor-in-Chief of Chemical Science and worked closely with the team for the launch of the journal]

Rosana Álvarez Rodríguez: Chemical Science is a scientific journal of international prestige that publishes full articles of high impact. I especially like the Edge article format and the broad selection of published articles.

 

What do you enjoy most about reviewing?

Joanna Wencel-Delord: What I enjoy the most is to take time to carefully think about projects of other people and having the possibility to give some suggestions and request additional explanations. I also find that the reviewing process also helps you to grow as scientist and gain more experience.

 

What are you looking for in a paper that you can recommend for acceptance in Chemical Science?

Joanna Wencel-Delord: What I’m really looking for, is to be somehow surprised by the originality of concepts and unprecedented reactivity or properties presented in a clear manner and supported by solid experimental evidence. And, I would say that a well written and nicely illustrated introduction specifying the underlying project is one of the cornerstones.

Joaquin Barroso: Clarity. We all do research based on our own interests and ideas, so for me it’s never about ranking or comparing manuscripts for which one is better. Thus, when a manuscript is written in such a way that one can trek and journey along with the authors through their train of thought, and become convinced about their conclusions, that’s when I become excited about reading a manuscript.

 

What advice would you give a first-time author looking to maximise their chances of successful peer review?

Christoforos Kokotos:  First-time authors are always helped by advice given by senior colleagues. This helped me a lot at the beginning of my career. So, do seek advice from senior colleagues. The introduction part is extremely crucial and authors should provide a thorough overview of the field and present, in a clear manner, the goals of their study and how it correlates with existing knowledge. Also, I usually find a scheme at the beginning which summarizes previous work and current work extremely helpful, especially if it shows how current work improves and solves problems existing in the literature.

Rosana Álvarez Rodríguez: I think that the most important thing in a good article is scientific rigour, clarity when describing the result, and novelty. A good article should also be easy to read.

 

How has your approach to peer reviewing changed over time?

Joanna Wencel-Delord:  Over time I have been putting growing importance on fair and balanced citations of the previous contributions in the field and clear statements of the novelty and originality of the submitted manuscripts.

 

A final specific question for Joaquin Barroso, whose blog helped me immensely when I was studying for my PhD in computational chemistry; Have you found the experience of providing information, tutorials and guides on your blog helpful when reviewing papers? For example, with determining how to communicate points or suggest improvements for a paper?

Joaquin Barroso: Absolutely, I know how hard it is to make a point come across. In my blog I try to teach people how to perform various kinds of calculations in computational chemistry, so clarity, brevity, and specificity are key.

 

Tune in next month to meet our next group of #ChemSciReviewers!

 

If you want to learn more about how we support our reviewers, check out our Reviewer Hub.

Interested in joining our ever-growing reviewer community? Apply here now!

 

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A big shift for understanding molecular structure

A single molecule magnet could help us understand the biochemistry of health and disease

 

A single molecule that behaves like a powerful magnet could help chemists determine the structure of many other molecules. Researchers based in Italy and Brazil describe the development and potential of their unusually powerful Nuclear Magnetic Resonance (NMR) shift agent in the open access journal Chemical Science.

NMR uses a strong magnetic field to split the spin levels of the nuclei at the centre of some atoms. Monitoring the splitting can reveal the chemical environment surrounding individual atoms, allowing the structure of entire molecules, including large biological macromolecules to be determined.

NMR is based on the same physical principles as medical MRI imaging, but instead of generating images of bodies it creates graphical read-outs of atomic interactions that can be readily deciphered by experts. It has been a fundamental tool of chemistry research since long before the widespread application of MRI imaging.

One problem, however, is that the signals from atoms in large molecules can overlap and interfere in ways that blur the data. This can be resolved by introducing a tiny magnetic tag into a region of interest within a large molecule. The magnetism of the tag shifts the signals from nearby atoms in a predictable way, separating them out from signals from other regions that are not of immediate interest.

The tags are called shift agents and many are available, but researchers are seeking more powerful and effective shift agents to make NMR signals ever clearer and allow them to reveal new details of molecular structure within larger molecules.

The researchers in Italy and Brazil found inspiration for their new shift agent in an unusual place – chemicals used in research towards quantum technologies.

“By searching molecular materials designed for the miniaturisation of information storage and quantum technologies, we have identified and re-designed a molecule that shifts the NMR signals of the neighbouring atoms twice as much as the currently used molecules,” says researcher Roberta Sessoli at the University of Florence. Sessoli and her colleagues in Italy collaborated with researchers at the Federal University of Parana, Brazil.

The molecule they devised has a cage-like arrangement of organic (carbon-based) chemical groups holding an atom of the rare-earth element dysprosium at its centre. It was produced by a relatively simple chemical modification that hugely increased the desirable magnetic properties of the molecule the team began with. Experiments and computational modelling showed that this design modification ensures the new shift agent has a very high and directional magnetic field while being sufficiently stable to be used in solution at room temperature.

The researchers hope that their shift agent can contribute to the worldwide effort to understand the structure of the very complex biomolecules that control the chemistry of life.

“The more we can learn about the structure and functions of proteins, for example, the better and faster we will be able to design new therapies for old and new diseases,” Sessoli says.

Chemical Science is open and free for both readers and authors.

 

Article details:

Santana, F. S. “A dysprosium single molecule magnet outperforming current pseudocontact shift agents.” Chemical Science, 2022, 13, 5680-5871

 

 

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Growing opportunities for semiconductors

Thin films of novel semiconductors could open a new window for optoelectronics

An international research team describe how to make thin films of semiconductor materials composed of calcium copper and phosphorus (CaCuP) in the open access journal Chemical Science.

“We have synthesised CaCuP thin films for the first time, and found them to be semiconductors with very high p-type electrical conductivity,” says Andrea Crovetto at the Technical University of Denmark. He worked on the research with colleagues in the UK, USA and Germany.

Crovetto explains that p-type conductivity (p for positive) is a form of semi-conduction in which electric current is carried by the movement of positively charged “holes” rather than by the mobile electrons of n-type (n for negative) conductivity. “The holes can be thought of as bubbles of missing electrons moving around a sea of inactive electrons,” he says.

High performance and transparent p-type conducting materials are keenly sought by researchers as they are expected to offer improved efficiency and new design opportunities for optoelectronic devices that work by inter-converting light and electrical energy in either direction. Applications could include solar cells generating electrical power, sensors driven by or responding to light, and also transparent electronics.

The challenge to find efficient p-type conducting films inspired Crovetto to write a research proposal and to visit the group led by Andriy Zakutayev at the National Renewable Energy Laboratory in the USA. He knew that Zakutayev’s team had a unique growth chamber that could create a wide range of phosphide films. He also sought guidance and assistance from David Scanlon at University College, London, UK, who was an expert on the theoretical aspects CaCuP phosphide films. His is the type of work that had predicted such films could have novel and very useful characteristics.

The researchers and other colleagues then collaborated to predict in more detail the properties of specific CaCuP films and then eventually to make and test them. PhD student Joe Willis from Scanlon’s group led this new round of theoretical predictions.

“CaCuP had never been made before as a thin film and I was afraid it might not be stable in air, so it was exciting to finally see it synthesised and find that it was not degrading when taking it out of the growth chamber,” says Crovetto.

The electrical properties proved to be close to what was expected. One challenge for the future, however, is to make the films more transparent than was initially achieved. Crovetto says he was disappointed to see that the first films made were not as transparent as the team had hoped. They believe that this might be resolved by future developments in the chemistry of growing the films, which will be a priority task for their ongoing investigations.

Crovetto says that combining transparency with good p-type electrical conduction is not easily achieved using conventional materials like oxides or binary semiconductors. Successful incorporation of good transparency into the new CaCuP could therefore be a very significant step forwards. “Our work could open up a new field of phosphide materials discovery,” he concludes.

Chemical Science is open and free for both readers and authors.

Article details:

Willis, J. et al:  Prediction and realisation of high mobility and degenerate p-type conductivity in CaCuP thin films Chemical Science (2022).

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Chemical Science Reviewer Spotlight – August 2022

To further thank and recognise the support from our excellent reviewer community, we are highlighting reviewers who have provided exceptional support to the journal over the past year.

This month, we’ll be highlighting Satoshi Horike, Maria Contel, Stefanie Dehnen and Christopher Barner-Kowollik. We asked our reviewers a few questions about what they enjoy about reviewing, and their thoughts on how to provide a useful review.

Photo of Satoshi Horike

Satoshi Horike, Kyoto University. Satoshi’s research group studies hybrid glass-forming materials consisting of metals and molecules, involving solid-state ion conductors and porous solids.

Photo of Stefanie Dehnen

Stefanie Dehnen, Philipps-University Marburg. Stefanie is interested in the synthesis, in-depth analysis and application of cluster compounds, i.e. compounds with large molecules of atomically precise composition and defined structure comprising (semi-)metal atoms.

Photo of Maria Contel

Maria Contel, Brooklyn College, The City University of New York (CUNY). Maria’s research group is focused on developing anticancer and antimicrobial agents based on metal- compounds. They study modes of action to help optimize the design of drugs with an improved pharmacological profile. They also work on strategies to develop targeted drugs.

Photo of Christopher Barner-Kowollik

Christopher Barner-Kowollik, Queensland University of Technology. Christopher’s research focuses on understanding photochemical reactions via wavelength-by-wavelength reactivity assessments via so-called action plots, which drive precision photochemistry development for the design of advanced (macromolecular) photoresists for 3D laser lithography and 3D printing applications.

 

What encouraged you to review for Chemical Science?

Stefanie Dehnen: Chemical Science is one of the most important journals for research in all areas of chemistry. It is a pleasure to review for it, as the articles are usually of high quality and report on cutting-edge research (even if not all of them actually reach the quality required for publication in Chemical Science in the end).

Christopher Barner-Kowollik: The outstanding quality of the journal and the diverse and vibrant author community, underpinned by one of the most respected learned chemical societies in the world.

        

What advice would you give a first-time author looking to maximise their chances of successful peer review?

Maria Contel: I would have a supportive senior colleague with ample experience in the field to look at the manuscript and provide feedback. I would read quite a bit, every week and keep current with the literature (within your possibilities). There are also wonderful webinars on writing scientific papers, including those from specific journals, which can be very useful for first time authors.

Satoshi Horike: In many cases, the research field is competitive and has a vast background. It is important to clearly explain how the authors find and solve the challenges that have not yet been explored in the field. The focus should not be dispersed. If the paper includes non-conventional methods on synthesis and characterization, it is eye-catching and I feel that they have provided new values.

 

What makes a paper truly stand out for you when reviewing a paper?

Christopher Barner-Kowollik: Beautiful and carefully crafted schemes and figures, including the all-important overview scheme that should be at the end of every introduction, summarizing the idea and concept of the presented work. When reviewing a manuscript, I look at the figures first, even before reading the abstract. In my view, effective science communication starts with outstanding imagery, including the presentation of technical data such as NMR spectra.

 

What has been your biggest learning point from reviewing?

Maria Contel: To be concise and straight forward. Less is more when it comes to writing. You also need to tell a story and should not forget to cite relevant papers in your field!  

 

Tune in next month to meet our next group of #ChemSciReviewers!

 

If you want to learn more about how we support our reviewers, check out our Reviewer Hub.

Interested in joining our ever-growing reviewer community? Apply here now!

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