Materials Advances 2024 Paper Prize runner-up

Meet some of the authors of the runner-up paper

Evaluation of techniques used for visualisation of hydrogel morphology and determination of pore size distributions

Imanda Jayawardena, Petri Turunen, Bruna Cambraia Garms, Alan Rowan, Simon Corrie and Lisbeth Grøndahl

Imanda is a Marie Skłodowska-Curie Actions – Science Foundation Ireland Research Fellow at the Irish Photonics Integration Centre (IPIC). Her current research focuses on developing a bone-on-a-chip device for longitudinal osteogenesis monitoring using non-invasive, label-free, non-ionising spectroscopic techniques. Imanda’s areas of research interests include, biomaterials, biophotonics, biophysics, physical chemistry, biomedical engineering, medical devices and the broader field of health and medicine. She has prior research experience in immunochemistry, microscopic techniques, mass spectroscopy assisted proteomics, and working with hydroxyapatite nanoparticles. Imanda is also a fellow of the Higher Education Academy (HEA) owing to her contributions towards university-level teaching.
Dr. Bruna Cambraia Garms is a biomaterial scientist specializing in polymeric platforms for drug release systems, medical device design, and cell-material interactions. She completed her PhD at the University of Queensland, Brisbane, where she investigated new hydrogels for cancer research. Currently, as a Research Fellow in the Department of Materials Science and Engineering at Monash University, Australia, Dr. Garms works on a device for cardiac solutions. Dr Garms’ research interests lie in biomaterials engineering with projects aimed at addressing critical medical challenges.
Simon Corrie completed his undergraduate degree in Chemical Engineering and PhD in Physical Chemistry at the University of Queensland, before undertaking postdoctoral studies at the HPV Research Laboratory at the University of Washington, Seattle (Merck Company Foundation Fellowship). After returning to Australia to develop microneedle arrays for wearable immunoassays (Smart Futures Fellowship; ARC DECRA), he joined the Chemical and Biological Engineering Department at Monash University in 2016 to establish the Nanosensor Engineering Lab. His research interests lie in developing nano-particles and proteins for applications in bio-sensing and bio-assays with application in biomedicine and agriculture.
Lisbeth Grøndahl obtained her PhD in chemistry from the University of Copenhagen, Denmark and now holds a position as Professor in the School of Chemistry and Molecular Biosciences at the University of Queensland, Australia. She is a Fellow of Biomaterials Science and Engineering and works in the interdisciplinary field of biomaterials science with a focus on development of approaches to create and comprehensively characterise functional polymeric biomaterials in the form of membranes, scaffolds, hydrogels, and nanoparticles. In 2018 she was highlighted as one of 16 women at the forefront of biointerface science research by the international journal Biointerphases.

What aspect of your work are you most excited about at the moment?

Petri Turunen: I am excited of working with array of advanced microscopy techniques at my disposal to support research on biomolecular and synthetic systems.

Lisbeth Grøndahl: Providing detailed guidance on material characterisation, since that allows reproducible and impactful work to be generated, not just by my research team, but more broadly.

 

How do you feel about Materials Advances as a place to publish research on this topic?

Petri Turunen: I think Materials Advances is a great journal to publish materials research.

Lisbeth Grøndahl: Materials Advances provides an excellent forum for publication of research into material characterisation and setting standards and communicating sound protocols.

 

Can you share one piece of career-related advice for early career scientists?

Petri Turunen: My advice would be not to be afraid to do lateral career moves and there are more and more alternative career paths in science for example in core facilities.

Lisbeth Grøndahl: It is through detailed evaluation of material properties that you will make ground-breaking discoveries that will have a long-lasting legacy.

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Materials Advances 2024 Paper Prize winner

Meet some of the authors of the winning paper

Redox-active, porous pyrene tetraone dendritic polymers as cathode materials for lithium-ion batteries

Lucas Ueberricke, Felix Mildner, Yuquan Wu, Elisa Thauer, Tom Wickenhäuser, Wen-Shan Zhang, Yana Vaynzof, Sven M. Elbert, Rasmus R. Schröder, Rüdiger Klingeler and Michael Mastalerz

Lucas Ueberricke studied chemistry at the Ruprecht-Karls-Universität Heidelberg, Germany and at Tohoku University, Sendai, Japan. After obtaining his B. Sc. (2013) and M.Sc. (2017), he continued with his PhD studies under the supervision of Prof. Dr. Michael Mastalerz in Heidelberg, where he graduated with summa cum laude in 2021. He then joined the group of Prof. Dr. Atsushi Wakamiya at Kyoto University, Japan, for postdoctoral research on self-assembled hole-extracting monolayers for perovskite solar cells. Since 2022 he is working as senior researcher at Nippon Electric Glass Co., Ltd. (NEG) in Otsu, Japan, where he is investigating crystallization phenomena in glasses.
Felix Mildner Felix graduated from the University Heidelberg in 2019 with an BSc in Chemistry and from Imperial College London in 2020 with an MRes in Nanomaterials. During his masters project he investigated silver spill-over at electrified solid state interfaces in the context of Memristors using ab initio methods. For his PhD, Felix is working with Prof Nicholas Harrison at Imperial College to study the design principles of high efficiency photocathode materials using ab initio methods and the quantum mechanical modelling of photoemission processes. Novel photocathode materials are necessary for the operation of next generational light sources and free electron lasers (FELs).
Yana Vaynzof is the Chair for Emerging Electronic Technologies at the Technical University Dresden (TUD) and the director of the Institute for Emerging Electronic Technologies at the Leibniz Institute for Solid State and Materials Research Dresden (IFW). Yana Vaynzof is the recipient of a number of fellowships and awards, including the ERC Starting and Consolidator Grants. Her research interests lie in the field of emerging photovoltaics focusing on the study of material and device physics of organic, quantum dot and perovskite solar cells by integrating device fabrication with the application and development of advanced spectroscopic methods.
Professor Klingeler is a Professor of experimental physics at Ruprecht-Karls-Universität Heidelberg. His research group focuses on correlated quantum materials, applying fundamental studies on thermodynamic response functions down to MilliKelvin temperatures and up to high magnetic fields. Their work on unconventional superconductivity, electronic nemantic order and quantum magnetism challenge standard theories, extending our understanding of quantum many-body systems.
Mastalerz Michael 03 Professor Mastalerz has been based in the Organic Chemistry Institute at Ruprecht-Karls-Universität Heidelberg since 2013. His research interests cover organic porous materials, crystal engineering and self-assembly, supramolecular chemistry, and non-planar extended aromatic molecules.
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Welcome to new Journal of Materials Chemistry A Scientific Editor Sofía Calero

New Journal of Materials Chemistry A Scientific Editor

Welcome to Sofía Calero

Journal of Materials Chemistry A is delighted to welcome Prof. Sofía Calero to the Editorial Board as a Scientific Editor. Please join us in congratulating Sofía on her new role and find out more about her in the interview below:

Sofía Calero is a professor of Applied Physics and chairs the Materials Simulation and Modelling group at the department of Applied Physics and Science Education, at Eindhoven University of Technology, The Netherlands.

Dr. Calero is part of the Board of Directors of the International Adsorption Society and the Spanish Adsorption Group, which she currently chairs. She is the author of over 300 refereed scientific publications  and has been the recipient of numerous prestigious scientific prizes and Awards, including the Marie Curie Excellence Award, ERC Consolidator Grant, Salvador de Madariaga Grant, Dutch VPP-KNAW grant, Spanish Royal Society of Chemistry awards for Young Researchers and later on for Scientific Excellence and the Irene Curie Grant. Her research involves the application of molecular simulation to industrially relevant systems and the development of force fields, algorithms and simulation methods to reverse-engineer properties of porous materials.

What does it mean to you to join the Editorial Board, as a Scientific Editor on Journal of Materials Chemistry A?

Joining the board as a Scientific Editor gives me the opportunity to be in touch with the most advanced science in the materials field. This is great for me, as I understand it would be for all those scientists who enjoy the work they do.

What is the current biggest challenge you face in your field?

There are many. In silico work on materials is now in a very good moment. Computers are faster and we are increasingly immersed in the development of efficient methodologies. Accurate and transferable force fields remain a challenge for many systems. Examples are amorphous and defective materials, challenging properties related to energy production and storage or, in the field of adsorption, large complex adsorbates that can lead to adsorbent phase transitions.

Why do you feel that researchers should choose to publish their work in Journal of Materials Chemistry A?

Because it is a very good journal, addressing some of the most emerging challenges for current materials.

Can you tell us about one of your latest Journal of Materials Chemistry A publications?

It was related to work to evaluate the performance of adsorption heat pumps and cooling systems (https://pubs.rsc.org/en/content/articlelanding/2024/ta/d3ta05258c). To do this, we combined adsorption data of alcohols in MOFs with a thermodynamic model, generating a process that allowed us to obtain, among other properties, the coefficient of performance, the working capacity, the specific heat or cooling effect and the heat released in the adsorption and desorption cycles. Furthermore, our process has the advantage of identifying the optimal conditions for each adsorbent-fluid pair.

 

 

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Welcome to new Journal of Materials Chemistry B Advisory Board member João Borges

New Journal of Materials Chemistry B Advisory Board member

Welcome to Dr João Borges

Journal of Materials Chemistry B is delighted to welcome Dr João Borges (University of Aveiro, Portugal) to the Advisory Board. Please join us in congratulating João on his new position and find out more about him in the interview below:

 

Dr. João Borges is a Senior Researcher at the Department of Chemistry and CICECO – Aveiro Institute of Materials at the University of Aveiro, Portugal. He received his PhD in Chemistry from the University of Porto in 2013. His research focuses on the molecular design, synthesis and development of bioinstructive supramolecular multicomponent biomaterials to interface with living systems. In particular, he has been developing chemically programmable and dynamic supramolecular hydrogels and Layer-by-Layer-driven soft self-assembling biomaterials by combining polysaccharides, self-assembling peptides and nucleic acids, to be used as bioinstructive matrices to control cell functions and as platforms for controlled drug/therapeutics delivery. He has served as a Guest Editor for Journal of Materials Chemistry B in 2024. He has been strongly committed to delivering a positive social impact by being invested in science communication, outreach, and policy and he has been connecting, supporting and empowering early-career scientists in advancing their professional development as a member of the Global Young Academy, Young Academy of Portugal of the Lisbon Academy of Sciences, International Younger Chemists Network (IYCN), and European Young Chemists’ Network. He is co-chair of the Global Conversation on Sustainability by IUPAC and the IYCN, and a National Representative of the IYCN Standing Committee at IUPAC.

What does it mean to you to join the Advisory Board of Journal of Materials Chemistry B?

I am truly honored and delighted to join the Advisory Board of the prestigious Journal of Materials Chemistry B, which publishes high quality research at the interface of materials chemistry, biology and medicine. The unique opportunity to join the Advisory Board will enable me to contribute further to the journal and to support the materials chemistry community by several means. Those include contributing with strategic advice, suggestions and recommendations to keep the high standards of quality of the journal, aiding in promoting and publishing impactful materials chemistry research, as well as in proposing themed collections (I am currently co-editing a themed collection) and perspective articles in the field, and helping in shaping the future directions and development of the journal by working closely with peer Editorial Board Members.

What is the current biggest challenge you face in your field?

 One of the biggest challenges for those working at the interface of materials chemistry, biology and medicine is still accelerating translational research by navigating the regulatory issues, i.e. bridging the gap between the lab research and the clinics towards benefiting society. The possibility to enable the translation of pioneering devices, technologies and advanced therapies at a faster pace that could improve the quality and life expectancy of citizens and reduce the healthcare costs is fundamental to address many pressing healthcare challenges that society faces and contribute to sustainable development.

In addition, as a young scientist, one of the major challenges we face is funding which is transversal to several fields and areas of research.

Why do you feel that researchers should choose to publish their work in Journal of Materials Chemistry B?

Journal of Materials Chemistry B is a truly reputable and widely read interdisciplinary forum for publishing cutting-edge research at the interface of chemistry, materials science, biology and medicine, which maximizes the visibility and impact of scientific research. One can publish a wide range of studies at the forefront of materials chemistry research, from a more fundamental science perspective on the design and synthesis of materials to their applications in biology and medicine. In addition, I also very much appreciate the professionalism and commitment of the editorial team, as well as the thoughtful and trustworthy peer-review process which undoubtedly helps to improve the quality of the science communicated by the authors and to increase its impact.

Can you tell us about one of your latest Journal of Materials Chemistry B publications?

 Our most recent publication was an original full paper published in 2023 on the development of marine-origin polysaccharides-based free-standing multilayered membranes as sustainable nanoreservoirs for controlled drug delivery. This manuscript emphasizes the synergistic use of sustainable marine-origin biopolymers, their chemical modification into water-soluble biopolymers at physiological pH, and their processing into robust biocompatible and biodegradable membranes/devices for controlled drug/therapeutics delivery by resorting to the green and cost-effective bottom-up layer-by-layer assembly nanotechnology. The proposed membranes represent promising sustainable nanocarriers for the encapsulation and sustained release of therapeutics in in vitro and in vivo scenarios, holding great promise to be used as implantable biomaterials for modular tissue engineering and regenerative medicine strategies. This manuscript is part of several themed collections, including Journal of Materials Chemistry B Emerging Investigators and  2023 Journal of Materials Chemistry B Most Popular Articles. We are delighted that this manuscript has been well received by the materials chemistry community and has been gathering the attention of the readers of the journal.

 

 

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Congratulations to the prize winners from SNAIA CRISTMAS 2023

Materials Advances was delighted to sponsor 3 prizes for Poster Presentations at the SNAIA CRISTMAS 2023 event which took place in the Chimie Paris Tech on 13-15 December 2023.

It was difficult for the organisers to pick the prize winners due to the exceptional quality of all the posters presented at the event – the prize winners below were “truly outstanding”!

Victor Filatov, SkyLab AG, Switzerland

Poster Presentation: “Towards a restoration of cotton fabrics: the research of a novel combination based on sucrose and malic acid for cross-linking fibres and colour retention during laundry washing cycles”

Anastasia Novikova, Ben-Grunion University on the Negev, Israel

Poster Presentation: “Hollow-Micro pillared Glass Fabricated on Hollow Joe Pye Weed-Inspired Tubes for Detecting Molecular Signatures”

Abigail Bond, University of Leeds, UK

Poster Presentation: “Towards the Liquid Crystal Chemical Sensor via Confinement Within a Stripe Pattern”

Congratulations to the winners from the Materials Advances team!

 

If you would like to attend the next edition of the event then visit the 2024 webpage here: https://cristmas.org/

SNAIA – CRISTMAS – Most Recent Innovations in Materials Science and Advanced Characterisation Methods

The 2024 event will provide a unique platform to meet, share knowledge and establish links between experts from academia and industry covering the most exciting emerging applications within fields of Photonics, (Opto)Electronics, Chemistry, Biology, Medicine, Engineering, Quantum Computing, and Art.

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Congratulations to the poster prize winners at the Cambridge Bioelectronics Symposium

Congratulations to the poster prize winners at the Cambridge Bioelectronics Symposium held on 1-3 July 2024 in Cambridge, UK. Ahmed Omara won the Journal of Materials Chemistry B award, while Joseph Asfouri won the Journal of Materials Chemistry C award.

Ahmed Omara, Leibniz Institute for Polymer Research Dresden

Presentation of poster prize certificate to Ahmed Omara

Poster title: Hydrogel-Functionalized Microelectrode Arrays (MEAs) for Multimodal Cell Stimulation

Biography: Ahmed Omara, originally from Egypt, holds a bachelor’s degree in mechanical engineering with a double concentration in material science and mechatronics, and a minor in economics from the American University in Cairo, graduating in 2015. He pursued an Erasmus Mundus master’s program in nanoscience and nanotechnology, spending the first year in Belgium and the second in Barcelona, Spain. Specializing in nanomaterials, he discovered a passion for biomaterials, hydrogels, tissue engineering, and electronics.

After his masters Ahmed returned to Egypt in 2021 where he worked as a lead scientist to create biodegradable plastics from natural sources at Sadko group of companies. Currently, he is pursuing a PhD at the Leibniz Institute for Polymer Research in Dresden, Germany, focusing on fabricating bioelectronic devices and functionalizing them with hydrogel for multimodal cell simulation at a single-cell resolution level.

 

Joseph Asfouri, University of Cambridge

Poster prize certificate presented to Joseph AsfouriPoster title: Towards a 3D, Flexible, Biohybrid Device for Cell Replacement Therapy for Parkinson’s Disease

Biography: Joseph is a master’s student in George Malliaras’ lab at the University of Cambridge. During his undergraduate years at Rice University, he studied electrical engineering and neuroscience while conducting research on magnetogenetic neural stimulation at Rice, deep brain stimulation for depression at Baylor College of Medicine, and brain-computer interfaces for motor prostheses at the University of Washington. At Cambridge, he designed a novel bioelectronic implant to enhance stem cell therapy for Parkinson’s disease. Along with his passion for neural engineering, his interests include science policy and commercialization to translate neurotechnology safely and efficiently from the lab to the clinic. This fall, Joseph will return to the US to start his PhD in the UC Berkeley-UCSF Joint Bioengineering Program.

 

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Open call for papers: 1D Fibrous Materials for Advanced Energy Storage and Conversion – A Materials Advances Themed Collection

We have extended the deadline for submissions to this upcoming Materials Advances themed collection on:

1D Fibrous Materials for Advanced Energy Storage and Conversion

Guest Edited by:

Dr Subrata Kundu, (Academy of Scientific and Innovative Research (AcSIR), India)

Professor Shaikh M. Mobin, (Indian Institute of Technology Indore (IITI), India) 

Dr Shaila Afroj (University of Exeter, United Kingdom).

Energy storage and conversion techniques are the cornerstones of a sustainable future, allowing us to capture renewable energy when it’s abundant. 1D fibrous materials having unique properties, such as high surface to volume ratio and conductivity, can revolutionize advanced energy storage and conversion devices. These unique properties make them a key material for next-generation clean energy technologies. This special themed collection will explore the full potential of various 1D fibrous based materials for energy conversion and storage application including, but not limited to;

  • Design, synthesis, and characterization of 1D fibrous materials for energy storage (batteries, supercapacitors) and conversion (solar cells, water splitting, fuel cells, electrolyzers, thermoelectric materials).
  • Exploring novel 1D fibrous materials with improved storage and conversion efficiencies.
  • Theoretical understanding of 1D fibrous materials for energy conversion and storage techniques.
  • Mechanistic study of 1D fibrous catalyst includes in-situ characterisation and machine learning.
  • Cost-effective and real time fabrication of 1D fibrous materials towards practical/industrial applications.

Submissions should fit within the scope of the collection and Materials Advances. Please click on the journal link for more information on the journal’s scope, standards, article types and author guidelines.

Open for submissions until 15th April 2025

If you are interested in submitting a review-type article, please contact the Editorial Office at materialsadvances-rsc@rsc.org in the first instance with a proposed title and abstract as initial approval is required before submission to limit the number of review-type articles and avoid potential topic overlap.

Please note that article processing charges apply to all articles submitted to Materials Advances if, following peer-review, they are accepted for publication. Details of the APC can be found here. Corresponding authors who are not already members of the Royal Society of Chemistry are entitled to one year’s Affiliate membership as part of their APC. Find out more about our member benefits.

If your institution has a read and publish deal with the RSC you may be entitled to a discount or waiver to publish your manuscript. We encourage you to use our new journal finder tool to see if you are eligible for a discount or waiver through an institutional deal.

 

Submit your manuscript now!

 

We look forward to receiving your manuscripts!

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Congratulations to the UKPorMat 24 Poster Prize Winners!

The 7th Annual UK PorMat Symposium was held at University of Liverpool on 4th-5th June by the RSC Porous Materials Interest Group. To accompany a programme filled with exceptional talks from a number of  esteemed researchers, posters were presented by PhD and post doctorial researchers . With a huge number of posters, from 86 candidates, displaying a wide variety of work within the porous materials field, it is our great pleasure in congratulating our three poster prize winners.

 

 

Winner of the Journal of Materials Chemistry A B and C poster prize: Bethan Turner, University of Liverpool.

‘Strategies towards porous metal-organic framework (MOF) glasses.’

 

Bethan Turner

Bethan Turner

 

Bethan graduated with an MCHEM in chemistry and is currently in the first year of their PhD at the University of Liverpool with Dr Lauren McHugh as a supervisor and Professor Andy Cooper as a co-supervisor.

“The work I do is centred around MOF glasses with the aim of tailoring them for real life application. In my poster I discussed the trialling of a prospective porogen and the outcomes of those experiments. It was ultimately unsuccessful in increasing porosity, however, it was deduced that the incorporation method may be the fault. Subsequently, alternative methods were proposed such as experimenting with altered linkers in the structure and incorporating the porogen through saturating the pores of the crystalline material by soaking in a saturated solution. Long with porous materials, I also have an interest in accessibility in chemistry teaching. And ultimately with my project, I hope to contribute to the efforts in developing materials for water purification.”

 

 

 

 

Winner of the Dalton Transactions poster prize: Omar Al-Miqdadi, Imperial College London.

‘Accelerating discovery and implementation of porous liquids for CO2 removal.’

Omar Al-Miqdadi

Omar Al-Miqdadi

 

Omar Al-Miqdadi’s background is in chemistry where they attended the University of Warwick for their undergraduate studies. During Omar’s master’s year, they worked under the supervision of Professor Richard Walton to discover iron-based metal organic frameworks which could be built from sustainably sourced organic ligands.

In 2022, Omar began their PhD at Imperial College London under the supervision of Dr Becky Greenaway and Professor Camille Petit. Their experience in metal organic frameworks proved to be useful when delving into the world of type III porous liquids; dispersions of metal organic frameworks in pore-excluded liquids. They are using automated high-throughput experimentation to discover effective type III porous liquids for CO2 capture.

“In order to discover the ‘best’ porous liquid systems for carbon capture, we have employed an automated high-throughput workflow as our approach. Using 8 different ionic liquids as our pore-excluded liquids, we vary cation functional group and alkyl chain length using a constant anion and metal organic framework.

We are able to synthesise ZIF-8 on the automated platform and using solid dispensing, combine it with the 8 ionic liquids. Using a different liquid handling platform, we then test the viscosity of these dispersions based on a relationship between flow rate and viscosity. Following this, we use thermogravimetric analysis to measure CO2 uptake of the dispersions and by comparing to the uptake of the neat ionic liquids, we’re able to determine whether they are porous combinations or not. Finally, we look at the stability of these porous liquids by using a camera and custom monitoring rack to analyse how well they remain dispersed and by using dynamic light scattering to analyse the ZIF-8 particle size over time looking for any potential aggregation.

We hope that by using this workflow we are able to elucidate key structure-property relationships and by continuing to study these systems are able to understand what makes a type III porous liquid a good CO2 capture sorbent.”

 

Winner of the Materials Advances poster prize: Evandro Castaldelli, University of Nottingham.

‘The role of interfacial chemistry on MOF-coated optical fibres for gas sensing applications.’

Evandro Castaldelli

Evandro Castaldelli

Evandro Castaldelli received his PhD in Chemistry in 2016 from Universidade de Sao Paulo, Brazil, working on the synthesis of a new semiconducting metal-organic framework with interesting photoelectronic properties. The electrical characteristics were investigated at University of Surrey, UK, where Evandro spent 12 months working with Prof Ravi Silva CBE. He followed up with his first post-doctoral position, in 2017, also at Universidade de Sao Paulo, working on the synthesis of phthalocyanine-based coordination polymers and derived graphene nanocomposites, for electrochemical applications in water splitting and glucose sensing.

In 2018, alongside Evandro’s post-doc, he was offered a position in industry as main researcher and scientific consultant at Golden Technology LDTA, Brazil, working in fine chemicals for textiles. Projects and interests encompassed all aspects of this industry, from pre-treatments, dyeing, finishing, and water treatment. Evandro was particularly excited to be part of the development of products to obtain functional textiles, including antimicrobial, insect repellent and flame-retardant coatings. During this time, he also had an active role in bridging the gap between academia and industry, when they attracted the interest of local research institutions for innovation partnerships.

In 2021 Evandro  decided to return to academia, when he started as a Lecturer in Physical Chemistry at Universidade Federal de Santa Catarina, Brazil, teaching Thermodynamics, Kinetics, Chemistry of Interfaces and Quantum Mechanics. Then, in 2022, he started my current role as Post-Doctoral Research Associate at University of Nottingham, UK, working with the development of optical fibres coated with metal-organic frameworks for gas sensing in healthcare. Evandro is also a volunteer demonstrator, for laboratory and outreach events, and tutor in Inorganic Chemistry.

“The development of sensors for gases and volatile organic compounds (VOCs) is key for a range of applications such indoor air quality control and healthcare. Metal-organic frameworks (MOFs) are promising candidates as they have been demonstrated to have excellent and tuneable selectivity for different gases and VOCs. Despite recent progress, MOF integration into devices is still a major challenge, as synthetic conditions are often harsh and deposition mechanisms are not yet fully understood1. Furthermore, studies are often limited to layer-by-layer deposition of archetypal MOFs. In this work we show: the rapid solvothermal deposition of isostructural MFM-101 and MFM-190(CH3) frameworks onto optical fibres; and the influence of synthetic conditions and role of surface functionalisation on coverage, morphology, and phase purity. Our results will fill a knowledge gap in this field and move towards a general protocol for controlled MOF deposition onto various substrates.
Surface-mounted MOFs are usually obtained via liquid phase epitaxial layer-by-layer growth on substrates featuring some surface functionalisation, which can be achieved via sol-gel, self-assembled monolayers or nanoparticle deposition. While it affords great control over film thickness, morphology, and homogeneity, it is often slow and may not be applicable to all MOFs. On the other hand, simple solvothermal techniques usually yield poor coverage and little control over thickness, crystal phase and orientation2. In our case study, we have used MFM-101 and MFM-190(CH3), two isostructural copper-based MOFs which are typically synthesized solvothermally at 80 °C, using HCl as modulator, with reaction times varying from 2 to 4 days3. These conditions are usually optimized to yield high quality, large crystals, which are often contradictory with effective surface coverage and fibre optic sensors. For the latter, crystals larger than 5 μm fall outside the effective sensing area. We were able to achieve phase purity and reduce crystal sizes to the 1-5 μm range by removing the modulator, while optimizing deposition temperatures and significantly reducing reaction times to 15 min.
U-shaped optical fibres were functionalised with hydroxyl (-OH) groups to provide initial anchoring for MOF deposition, while a non-functionalised (bare) fibre was included as reference. SEM/EDX and Raman analyses of the coatings revealed that morphology and phase purity can be controlled via surface functionalisation alone. Real-time spectroscopical investigation of MFM-101 and MFM-190(CH3) depositions provided information about growth kinetics and surface coverage, revealing the unexpected influence of interfacial chemistry not only on surface coverage, as well as in crystal density and size. On average, non-functionalised fibres had crystals in the 5-20 μm range while hydroxylated fibres showed crystals in the 1-5 μm range. The resulting sensors can be used with a range of VOCs, and, surprisingly, their performance is also affected by the initial anchoring group. Preliminary results in VOC sensing indicate that hydroxylated fibres perform significantly better than their non-functionalised counterparts.”
References
[1] A. Kirchon, L. Feng, H. F. Drake, E. A. Joseph and H.-C. Zhou, Chem. Soc. Rev. 2018, 47, 8611
[2] A. L. Semrau, Z. Zhou, S. Mukherjee, M. Tu, W. Li and R. Fischer, Langmuir 2021, 37, 6847-6863
[3] W. Li et al, J. Am. Chem. Soc. 2022, 144, 13196-13204

Congratulations once again to our UKPorMat 2024 poster prize winners!

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Thank you for contributing to Materials Advances

Materials Advances is celebrating its fourth birthday this year! As the journal continues to grow and establish its place within the materials research community, we would like to thank all our authors, reviewers, editors, and readers for their continued support.

 

Take a look at some of our recent metrics to see how the journal is performing.

There are many exciting journal initiatives that you can get involved with, including:

 

Topical themed collections: Find out about our current open calls for paper here or read some of our recently closed collections

Discover our new regional collection:

Spotlights on well-received review articles in Materials Advances

  • Read our blog series exploring some of our highly cited review articles

Check out our Popular Advances collection, which is updated regularly

  • Read the collection here

Materials Advances Paper Prize

  • The 2024 winners of the Materials Advances Paper Prize can be found here.
  • To be in with a chance of winning a future paper prize, submit your next piece of work to the journal.

Meet the Materials Advances team at upcoming conferences!

Our Editorial Office team will be attending conferences and events over the second half of 2024, including:

  • PhotoIUPAC 2024, July 14 – 19, Valencia
  • ACS/RSC-Qatar Regional MEA Conference 2024, November 3 – 5, Doha
Thank you again for your support of Materials Advances!
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Themed collection on hybrid pores

Hybrid Pores for CO2 Technologies

Guest Edited by Petra Ágota Szilágyi , Jenny G. Vitillo , and Gavin A. Craig

Materials Advances is delighted to introduce our latest themed collection focused on inorganic-organic porous materials that enable the capture, storage, sensing, and conversion of CO2.

You can explore the collection and read the introductory editorial from our guest editors below. Articles in the collection are published in Materials Advances so they are all open access and freely available.

                 Read the introductory editorial

 

Read some of the featured articles below.

Simulating excited states in metal organic frameworks: from light-absorption to photochemical CO2 reduction
Michael Ingham, Alex Aziz, Devis Di Tommaso and Rachel Crespo-Otero
Mater. Adv., 2023, 4, 5388-5419 DOI: 10.1039/D3MA00518F

 

 

 

 

Pore volume regulated CO2 adsorption in C–C bonded porous organic frameworks
Himan Dev Singh, Piyush Singh, Deepak Rase and Ramanathan Vaidhyanathan

Mater. Adv., 2023, 4, 3055-3060 DOI: 10.1039/D3MA00218G

 

 

Rapid microwave synthesis of sustainable magnetic framework composites of UTSA-16(Zn) with Fe3O4 nanoparticles for efficient CO2 capture
John Luke Woodliffe, Amy-Louise Johnston, Michael Fay, Rebecca Ferrari, Rachel L. Gomes, Ed Lester, Ifty Ahmeda and Andrea Laybourn
Mater. Adv., 2023, 4, 5838-5849 DOI: 10.1039/D3MA00351E

 

 

 

Unusual adsorption-induced phase transitions in a pillared-layered copper ethylenediphosphonate with ultrasmall channels
Margherita Cavallo, Matteo Signorile, Roberto Köferstein, Valentina Crocellà and Marco Taddei
Mater. Adv., 2023, 5, 183-198 DOI: 10.1039/D3MA00356F

 

 

 

 

Direct CO2 to methanol reduction on Zr6-MOF based composite catalysts: a critical review
Elif Tezel, Dag Kristian Sannes, Stian Svelle, Petra Ágota Szilágyi and Unni Olsbye
Mater. Adv., 2023, 4, 5479-5495 DOI: 10.1039/D3MA00345K

 

 

 

Connecting metal–organic cages (MOCs) for CO2 remediation
Javier Martí-Rujas
Mater. Adv., 2023, 4, 4333-4343 DOI: 10.1039/D3MA00477E

 

 

 

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