Closed-loop 3D printing based on dynamic chemistry

By Kostas Parkatzidis, Community Board member.

3D printing has revolutionized the production of polymer-based materials, with the development of numerous printing techniques that continuously enhance speed, resolution, and accessibility. Among the most significant advancements is light-based 3D printing, which utilizes photopolymerization reactions to solidify inks, offering precise spatiotemporal control over the printing process. However, light-based 3D printing primarily relies on uncontrolled polymerization of (meth)acrylate and epoxide monomers/ cross-linkers, which yield non-functional, non-recyclable materials. To fully exploit the potential of 3D printing, there is growing interest in integrating advanced chemistries, such as dynamic chemistry, that enable the fabrication of functional materials capable of post-printing modifications in shape, properties, and functionality. Most polymer-based objects created through current 3D printing techniques cannot be chemically recycled due to the chemical inertness of the materials and the irreversible polymerization processes involved. Thus, it is imperative to incorporate new chemistries into 3D printing that enable the fabrication of advanced, functional, and chemically recyclable materials at the end of their lifecycle.

In a recent work by Du Prez and Nguyen, a closed-loop 3D printing process utilizing dynamic chemistry was reported. The authors synthesized an acrylate photocurable polymeric material based on dynamic β-amino ester cross-linkers, which can be used as an ink for 3D printing. Importantly, this material can undergo decross-linking via a transesterification reaction, resulting in the depolymerization of the formed polymer network. This process is not only reversible, enabling the making and unmaking of polymers, but it also operates under highly appealing and relatively mild conditions.

Figure 1: a) Chemical overview of the polymerization and depolymerization reactions of the dynamic network and b) closed-loop 3D printing. Image reproduced from DOI: 10.1039/D4MH00823E with permission from the Royal Society of Chemistry.

The team first synthesized an acrylate-terminated β-amino ester-containing cross-linker, which serves as a building block for the formation of a dynamic polymer network. This cross-linker was prepared via a one-step aza-Michael addition reaction. The process is straightforward and utilizes commercially available reagents, making the material easily adaptable for other researchers. These low-molecular-weight diacrylate polymers undergo photo-induced free radical polymerization, resulting in the formation of a dynamic polymer network.

This dynamic nature of the polymeric network enables thermomechanical reprocessing of the material. To demonstrate this aspect, the authors used compression molding (at 150 °C under 2 tons of pressure for 30 minutes) for reprocessability. The recycling procedure was repeated three times, with the material showing a slight increase in shear modulus and activation energy, while maintaining stable thermal properties and chemical integrity. The increase in temperature results in a reduction of cross-link density, demonstrating the role of dissociative exchange via (retro) aza-Michael addition. In contrast, polymeric networks without dynamic bonds did not exhibit any reprocessability, highlighting the promise of dynamic chemistry in enabling reprocessable materials.

In the next step, to demonstrate more advanced chemical recycling of this dynamic network, the team employed another reaction (transesterification) using a commercially available methacrylate with a hydroxyl moiety (hydroxyethyl methacrylate) as a decross-linker. The hydroxyl group of this functional methacrylate reacts with the β-amino ester, resulting in the decross-linking of the network and its depolymerization. This reaction is temperature-dependent and requires an optimized amount of decross-linker to achieve a high depolymerization yield. Notably, the depolymerization reaction proceeds without the need for any catalyst or solvent, making the procedure even more appealing. Upon depolymerization of the polymer network, the resulting mixture consists of methacrylate-terminated compounds, as confirmed by electrospray ionization mass spectrometry. These compounds can be further employed for another cycle of photo-curing, enabling the development of curable-depolymerizable dynamic materials.

In the final part, the team demonstrated the translation of this concept into closed-loop 3D printing using the dynamic photocurable resin. Multiple printing cycles were performed with recycled photocurable resin to assess the repeatability of this procedure. The resulting samples exhibited consistent shapes and appearances for at least three cycles, thus demonstrating repeatable printability after chemical recycling.

Overall, this study elegantly combines fundamental aspects of dynamic polymer chemistry and its application in 3D printing, further enhancing interest in dynamic chemistry for both functional and recyclable materials.

To find out more, please read:

Direct restoration of photocurable cross-linkers for repeated light-based 3D printing of covalent adaptable networks
Loc Tan Nguyen and Filip E. Du Prez
Mater. Horiz., 2024, DOI:10.1039/D4MH00823E


About the blogger


 

Dr. Kostas Parkatzidis is a Swiss National Science Foundation Postdoc Fellow in the group of Professor Zhenan Bao at Stanford University (United States), working on the molecular design of polymer-based skin-inspired materials for various applications. Kostas obtained his PhD from ETH Zurich (Switzerland) under the supervision of Professor Athina Anastasaki where he focused on the development of advanced polymer synthesis and chemical recycling methodologies. He also holds MSc in Organic Chemistry and BSc in Materials Science and Engineering obtained from the University of Crete (Greece). Since 2023, Kostas has served as a Materials Horizons Community Board member.

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Unveiling Crystalline Complexity: How Structural Disorder Shapes Heteroanionic Materials

By Raul Marquez, Community Board member.

Perovskite oxynitrides are intriguing materials with significant relevance in photoelectrochemistry and catalysis. Their crystallinity is often simplified using high-symmetry unit cells as a convenient approximation. However, this approach fails to capture the complex local atomic displacements of anions and neighboring cations caused by the differing ionic radii of oxygen and nitrogen anions. A recent study by the Seitz Group provides a more nuanced understanding of perovskite oxynitrides’ true crystallinity, using a newly synthesized calcium tungsten oxynitride, CaW(O,N)3, as a model system. The authors leverage experimental and computational techniques to explore its crystal structure, focusing on distortion, anion ordering, and symmetry. This study highlights four key findings:

CaW(O,N)3 exhibits structural distortion. The study marks the first successful synthesis of CaW(O,N)3. Using a combination of density functional theory (DFT), X-ray diffraction (XRD), and neutron diffraction (ND), the authors reveal that this material adopts an orthorhombic Pnma average structure. This structure exhibits significant octahedral distortion and preferential anion site occupancy, highlighting its deviation from a purely symmetric model.

Symmetry models for perovskite oxynitrides need to account for disorder. The authors demonstrate that traditional high-symmetry models fail to capture the full complexity of CaW(O,N)3. Instead, a low-symmetry model with a P1 space group—which incorporates a larger unit cell and random anion positioning—better represents the disorder inherent in the crystal. This disorder forms a “polymorphous network,” where the observed high symmetry is only an average, masking the true lower local symmetry of CaW(O,N)3.

The structural disorder can be extended to other perovskite oxynitrides. The structural disorder observed in CaW(O,N)3 was also identified in its analog, SrW(O,N)3. Like CaW(O,N)3, the authors obtained a better representation of the structural disorder in SrW(O,N)3 by applying similar low-symmetry models, suggesting that such disorder is a common characteristic across perovskite oxynitrides.

Structural disorder in perovskite oxynitrides causes changes in electronic properties. Comparative X-ray Absorption Spectroscopy (XAS) revealed differences in electronic structures between Ca- and Sr-based perovskite oxynitrides. SrW(O,N)3 exhibits stronger covalency between its anions and W 5d orbitals. These differences are attributed to the distinct electronic configurations and ionic radii of Ca²⁺ and Sr²⁺, which alter the interaction of W with neighboring anions.

 

Figure 1. summarises the study using CaW(O,N)3, as a model system. Experimental and computational techniques are used to explore its crystal structure, focusing on distortion, anion ordering, and symmetry. Image reproduced from DOI: 10.1039/D4MH00317A with permission from the Royal Society of Chemistry.

 

In summary, this study provides a comprehensive evaluation of the crystallinity and electronic properties of perovskite oxynitrides, emphasizing the importance of structural disorder. This work is a must-read for researchers studying heteroanionic materials, offering guidance on characterizing their structural and electronic properties through essential experimental and computational methods. Furthermore, it underscores the need for more sophisticated models to accurately represent these materials’ symmetry and local structure, accounting for the inherent complexities introduced by mixed anion occupancy. These findings are crucial for optimizing perovskite oxynitrides’ performance in catalytic and photoelectrochemical applications, where electronic and structural properties are pivotal in their performance.

To find out more, please read:

Synthesis and symmetry of perovskite oxynitride CaW(O,N)3
Matthew E. Sweers, Tzu-chen Liu, Jiahong Shen, Bingzhang Lu, John W. Freeland, Christopher Wolverton, Gabriela B. Gonzalez Aviles, and  Linsey C. Seitz
Mater. Horiz., 2024,11, 4104-4114 DOI: 10.1039/D4MH00317A


About the blogger


 

Raul A. Marquez is a Ph.D. in Chemistry candidate working with Prof. C. Buddie Mullins at The University of Texas at Austin and a Materials Horizons Community Board member. His research focuses on understanding the transformations of electrocatalytic materials and developing advanced characterization methods for energy storage and conversion technologies. Follow Raul’s latest research on LinkedIn.

 

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Open call for papers – Soft wearable sensors

Soft wearable sensors

Open call for papers

We are pleased to announce an open call for papers to a themed collection across Nanoscale Horizons and Materials Horizons, published by the Royal Society of Chemistry. 

This collection is being guest edited by Professors John Rogers (Northwestern University, USA), Wenlong Cheng (University of Sydney, Australia), Alina Rwei (TU Delft, Netherlands), Dae-Hyeong Kim (Seoul National University, South Korea) and Nanshu Lu (University of Texas at Austin, USA).

Next-generation soft wearable sensors hold significant promise for revolutionizing healthcare and human-computer interaction by providing seamless integration between the human body and electronic devices. These advanced systems, characterized by their flexibility, stretchability, and biocompatibility, enable continuous monitoring of physical parameters such as body motion, physiological parameters like heart rate, and biochemical markers like electrolytes and cortisol levels in sweat in real-time. This real-time data collection can lead to more personalized and timely medical interventions, enabling a shift from hospital-centred healthcare to patient-centred healthcare.

Beyond healthcare, next-generation soft wearable sensors have applications in fitness, sports, and augmented reality (AR)/virtual reality (VR), paving the way for innovative approaches to human performance enhancement and interactive technologies. They offer significant advancements in human-machine interaction, enhancing experiences in the metaverse and beyond. This special issue aims to highlight the latest research, developments, and innovative applications in soft wearable sensors from a materials and nanotechnology perspective, and we believe your work would make a valuable contribution to this discussion.

This special-themed collection aims to provide a platform to showcase the recent progress and challenges in the field of soft wearable sensors addressing the exciting current challenges in biosensors, bioelectronics, medicine, healthcare, AR/VR and soft robotics. The scope of the collection is broad, including but are not limited to:

 

  • Soft wearable materials and design
  • Innovative fabrication methods of soft wearable sensors
  • Materials and technologies for enhanced sensor performance
  • Integration of sensors with wearable systems
  • Significance of machine learning and artificial intelligence for remote diagnostics and automatic decision making
  • Applications in health monitoring, rehabilitation, AR/VR and sports
  • Challenges and future directions in the development of soft wearable sensors

 

Open for submissions until 14 March 2025


How to submit


Submissions should fit within the scope of either Nanoscale Horizons or Materials Horizons. Please visit the journal webpages for more information on their scope, standards, article types and author guidelines. We invite authors to select the journal that best suits their submission. Please note that primary research is accepted in the form of Communications for both journals and require a ‘New Concepts statement’ to help ascertain the significance of the research. General guidance and examples can be found here.

For Nanoscale Horizons, we welcome exceptionally high-quality studies across all fields of nanoscience and nanotechnology in the form of Communications and Review-type articles (Reviews and Focus articles).

For Materials Horizons, we welcome exceptionally high-quality materials science in the form of Communications and Review-type articles (Reviews, Opinions and Focus articles).

We strongly encourage you to submit an original research article. If you are interested in submitting a review-type article, please contact the Editorial Office at materialshorizons-rsc@rsc.org in the first instance with a proposed title and abstract, as initial approval is required before submission to avoid topic overlap and ensure that we cover topics in need to review.

When ready please submit your manuscript directly to the submissions platform for Nanoscale Horizons or Materials Horizons where our Editors will assess as per the scope and standards of the journal. Please add a note in the ‘Comments to the Editor’ and ‘Themed issues’ sections of the submission that this is a submission to the ‘Soft wearable sensors’ themed collection in response to the Open Call. Please note that all submissions will be subject to our standard rigorous peer review process, including initial editorial assessment as to suitability for the journal and maintain before peer review, if found appropriate. If accepted, your article would be published in a usual issue of the journal and added to the online collection for extra visibility.

We sincerely hope that you will be able to accept our invitation to contribute to this exciting collection on such an important topic.

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Congratulations to the poster prize winners at MAKRO 2024

We were delighted to support poster prize awards along with RSC Applied Polymers and Polymer Chemistry at the recent GDCh Makro conference in Dresden, Germany which was held from 16 – 18 September 2024. Congratulations to our winners, Annalena Groß and Ronja Bodesheimer. Find out more about them below.

 

Annalena Groß studied chemistry at the University of Freiburg, Germany, specializing in polymer science. Her master’s thesis focused on the characterization and phase behavior of polystyrene microgels, under the guidance of Prof. Bartsch. Following her graduation, she held a position as a research assistant at NEUSTART KULTUR. Keen to re-enter academic research, Annalena Groß started her PhD in February 2024 in the junior research group of Dr. Céline Calvino at the University of Freiburg. Her work focuses on the development of photo-thermo processes for the reversible crosslinking of polymers.

Annalena received a prize for her poster entitled, ‘Exploring the Multiresponsiveness of Quinolinone Motifs for Reversible Polymerizations’

 

 

 

 

 

 

 

 

 

 

 

 

 

Ronja Bodesheimer received a Bachelor in Science in Applied Chemistry from BTU Cottbus Senftenberg Germany in 2020 with a thesis entitled ‘Synthesis and characterisation of hydrogels with potential anti-biofouling activity’. Ronja then received a Master of Science in chemical engineering from HTW Dresden, Germany in 2021 with the thesis ‘Synthesis and characterisation of amphiphic star-based block copolymers for homogenous connetworks’ before becoming a research associate in the InnoVET project CLOU at HTW Dresden. Since 2022, Ronja is a research associate and PhD student in the InsBIOration project at IPF Dresden and TU Dresden in Germany.

Ronja received a prize for their poster entitled, ‘Bio-inspired polymer metallisation with the adhesion promoter dopamine’

Please join us in congratulating our winners!

Copyright: Leibniz-IPF/Emanuel Richter

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Materials Horizons 10th Anniversary Cover Showcase

As you may know, Materials Horizons is celebrating their 10th anniversary! To join in the celebrations, we have asked authors to find creative ways to add a ’10’ to the cover artwork and are excited to show you the results in our cover showcase.

Check out the covers in our showcase below and keep an eye out for additions!

Explore all featured articles in our 10th anniversary cover articles collection

From stress to charge: investigating the piezoelectric response of solvate ionic liquid in structural energy storage composites

Backscattering silicon spectrometer (BASIS):sixteen years in advanced materials characterisation

Leveraging volatile memristors in neuromorphic computing:from materials to system implementation

Thermochromic hydrogel-based energy efficient smart windows: fabrication, mechanisms, and advancements

Enhanced environmental adaptability of sandwich-like MoS2/Ag/WC nanomultilayer films via Ag nanoparticle diffusion-dominated defect repair

Epsilon-nera-zero thin films in a dual-functional system for thermal infrared camouflage and thermal management within the atmospheric window

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Congratulations to the CEMDI oral prize winners!

Materials Horizons, Digital Discovery and MSDE were delighted to sponsor three oral prizes at the 2nd Annual Computational Energy Materials Design Infrastructure (CEMDI) symposium held in Montreal, Canada from 27 – 29 May. Congratulations to Parastoo Agharezaei, Yasser Salah Eddine Bouchareb and Mehdi Shamekhi!

 

Find out more about our winners below:

 

Smiling headshot Parastoo Agharezaei

Parastoo Agharezaei is a researcher in the field of materials science and engineering, holding a Bachelor’s degree from the University of Tehran, awarded in 2017. She pursued a Joint Master’s degree with an Erasmus Mundus excellence full scholarship, earning dual Master’s degrees in Materials Science from TU Darmstadt, Germany, and in Physics with a minor in Quantum Modeling of Nanomaterials from the University of Liege, Belgium, in 2020. Currently, Parastoo is advancing her expertise in Computational Materials Science through a Ph.D. program at INRS, University of Quebec, focusing her doctoral thesis on the design of alloy catalysts for ammonia production using Density Functional Theory and Machine Learning.

Title of presentation: Design of CuNi-based single-doped alloy catalysts for ammonia production via Density Functional Theory

 

Smiling headshot in the sunshine

 

Mehdi Shamekhi

Mehdi Shamekhi is currently a PhD candidate in the Department of
Physics at Concordia University, working under the supervision of Prof.
Gilles H. Peslherbe on the computational design and investigation of bimetallic
alloys for the electrocatalytic nitrogen reduction reaction (NRR). Mehdi employs a combination of machine
learning and computational chemistry to advance his research, using
machine learning algorithms to screen the chemical space of bimetallic alloy
catalysts and identify promising candidates for further characterization
via density functional theory. Detailed knowledge of the electronic structure
of these catalysts indeed enables the design of catalysts that are both
active and selective toward the NRR, contributing to the development of efficient
catalysts for sustainable ammonia synthesis. Mehdi aspires to continue
his research in computational chemistry and electrocatalysis, aiming to make
significant contributions to the field of sustainable energy solutions. His longterm
goal is to develop innovative materials that can address global energy
challenges through green chemistry and advanced computational methods.

Title of presentation: Machine learning assisted screening and DFT characterization of bimetallic alloy catalysts for the nitrogen reduction reaction

Yasser Salah Eddine Bouchareb

Yasser Salah Eddine Bouchareb is currently pursuing a Ph.D. program at INRS, University of Quebec, working under the supervision of Prof. Kulbir Ghuman, and co-supervised by Prof. Jonathan Shock, on the design of alloy catalysts for CO2 PhotoCapture using Density Functional Theory and Machine Learning.

Title of presentation: Screening binary alloys for CO2 photo capture using GNN

 

Congratulations to our winners!

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Discover our 2024 Materials Horizons Emerging Investigators

Materials Horizons Emerging Investigator series

Discover our 2024 Emerging Investigators

Since the launch of Materials Horizons, the journal has had a clear vision to publish exceptionally high-quality work whilst acting as a resource to researchers working at all career levels. We continue to be impressed by the quality of the research published and at the same time are looking for new ways of recognising and promoting the outstanding authors behind articles published in the journal.

The Materials Horizons Emerging Investigators Series showcases early-career researchers who have published exceptional work in the journal. The initiative started in 2020 and so far we have featured over 40 up-and-coming researchers in the series. For each issue of the journal, the Editorial Office and Editorial Board select an Emerging Investigator from a pool of eligible authors, highlighting the researcher and their recently published work in an interview Editorial.

Discover our 2024 Materials Horizons Emerging Investigators so far and read their publications below:

 

Dr Jie Xu

Argonne National Laboratory, USA

Read the Editorial

Read the Emerging Investigator article, ‘Real-time correlation of crystallization and segmental order in conjugated polymers’ (https://doi.org/10.1039/D3MH00956D

 

 

Professor Dr Wee-Jun Ong

Center of Excellence for NaNo Energy & Catalysis Technology (CONNECT), Xiamen University, Malaysia

Read the Editorial

Read the Emerging Investigator article, ‘Isotype heterojunction: tuning the heptazine/triazine phase of crystalline nitrogen-rich C3N5towards multifunctional photocatalytic applications’ (https://doi.org/10.1039/D3MH01115A)

 

Professor Dr Hai-Bo Zhao

National Engineering Laboratory for Eco-Friendly Polymer Materials (Sichuan), College of Chemistry, Sichuan University

Read the Editorial

Read the Emerging Investigator article, ‘Controllable proton-reservoir ordered gel towards reversible switching and reliable electromagnetic interference shielding’ (https://doi.org/10.1039/D3MH01795H)

 

 

Associate Professor Dr Xuhui Zhang

Jiangnan University, China

Read the Editorial

Read the Emerging Investigator article, ‘Soft–hard dual nanophases: a facile strategy for polymer strengthening and toughening’ (https://doi.org/10.1039/D3MH01763J

 

Professor Zhengbao Yang

Hong Kong University of Science and Technology, Hong Kong

Read the Editorial

Read the Emerging Investigator article, ‘Exploring the Mpemba effect: a universal ice pressing enables porous ceramics’ (https://doi.org/10.1039/D3MH01869E)

 

Professor Yiyang Li

University of Michigan, USA

Read the Editorial

Read the Emerging Investigator article, ‘Oxygen tracer diffusion in amorphous hafnia films for resistive memory’ (https://doi.org/10.1039/d3mh02113k)

 

 

Professor Jingjing Duan

Nanjing University of Science and Technology, China

Read the Editorial

Read the Emerging Investigator article, ‘Unlock flow-type reversible aqueous Zn–CO2batteries’ (https://doi.org/10.1039/D4MH00219A

 

 

Professor Francesca Santoro

Forschungszentrum Jülich and RWTH Aachen, Germany

Read the Editorial

Read the Emerging Investigator article, ‘An organic brain-inspired platform with neurotransmitter closed-loop control, actuation and reinforcement learning’ (https://doi.org/10.1039/D3MH02202A)

 

Dr Sahnawaz Ahmed

National Institute of Pharmaceutical Education and Research (NIPER), Kolkata, India

Read the Editorial

Read the Emerging Investigator article,‘Chemically fueled dynamic switching between assembly-encoded emissions’ (https://doi.org/10.1039/D4MH00251B)

 

Professor Edison Huixiang Ang

National Institute of Education/Nanyang Technological University, Singapore

Read the Editorial

Read the Emerging Investigator article, ‘Construction of phase-separated Co/MnO synergistic catalysts and integration onto sponge for rapid removal of multiple contaminants’ (https://doi.org/10.1039/D4MH00285G)

We  would like to congratulate all our 2024 Emerging Investigators so far for being selected to feature. We hope that you enjoy reading their impactful publications and finding out more about them in their Editorial interviews. Keep an eye out for our next Emerging Investigators through 2024

Are you an independent researcher within 10 years of your PhD or within 5 years of your independent career? Submit your best research to Materials Horizons to be considered to feature in one of our next issues!

 

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Discover our 2023 Materials Horizons Emerging Investigators

Materials Horizons Emerging Investigator Series

Discover our 2023 Emerging Investigators

Since the launch of Materials Horizons, the journal has had a clear vision to publish exceptionally high-quality work whilst acting as a resource to researchers working at all career levels. We continue to be impressed by the quality of the research published and at the same time are looking for new ways of recognising and promoting the outstanding authors behind articles published in the journal.

The Materials Horizons Emerging Investigators Series showcases early-career researchers who have published exceptional work in the journal. The initiative started in 2020 and so far we have featured over 40 up-and-coming researchers in the series. For each issue of the journal, the Editorial Office and Editorial Board select an Emerging Investigator from a pool of eligible authors, highlighting the researcher and their recently published work in an interview Editorial.

 

Discover our 2023 Materials Horizons Emerging Investigators and read their publications below:

 

Dr Wei Zhai

National University of Singapore, Singapore

Read the Editorial

Read the Emerging Investigator article, ‘Multifunctional sound-absorbing and mechanical metamaterials via a decoupled mechanism design approach’ (https://doi.org/10.1039/D2MH00977C

 

Dr Yandong Ma

Shandong University, China

Read the Editorial

Read the Emerging Investigator article, ‘Layer-polarized anomalous Hall effects in valleytronic van der Waals bilayers’ (https://doi.org/10.1039/D2MH00906D

 

 

 

Dr Yue (Jessica) Wang

University of California, Merced, USA

Read the Editorial

Read the Emerging Investigator article,  ‘Oligoaniline-assisted self-assembly of polyaniline crystals’ (https://doi.org/10.1039/D2MH01344D

 

Dr Dominik J. Kubicki

University of Warwick, UK

Read the Editorial

Read the Emerging Investigator article, ‘MOF/polymer hybrids through in situ free radical polymerization in metal-organic frameworks’ (https://doi.org/10.1039/D2MH01202B

 

Dr Megan Fieser

University of Southern California, USA

Read the Editorial

Read the Emerging Investigator article, ‘Controlling selectivity for dechlorination of poly(vinyl chloride) with (xantphos)RhCl’ (https://doi.org/10.1039/D2MH01293F

 

Professor Derek Ho

City University of Hong Kong, China

Read the Editorial

Read the Emerging Investigator article, ‘Order–disorder engineering of RuO2nanosheets towards pH-universal oxygen evolution’ (https://doi.org/10.1039/D3MH00339F)

 

Dr Jess M. Clough

Adolphe Merkle Institute, University of Fribourg, Switzerland

Read the Editorial

Read the Emerging Investigator article, ‘Microscopic strain mapping in polymers equipped with non-covalent mechanochromic motifs’ (https://doi.org/10.1039/D3MH00650F)

 

Dr Kevin Golovin

University of Toronto, Canada

Read the Editorial

Read the Emerging Investigator article, ‘Surface-engineered double-layered fabrics for continuous, passive fluid transport’ (https://doi.org/10.1039/D3MH00634D)

 

Dr Shanshan Yao

Stony Brook University, USA

Read the Editorial

Read the Emerging Investigator article, ‘Decoding silent speech commands from articulatory movements through soft magnetic skin and machine learning’ (https://doi.org/10.1039/D3MH01062G)

We  would like to congratulate all our 2023 Emerging Investigators for being selected to feature. We hope that you enjoy reading their impactful publications and finding out more about them in their Editorial interviews.

Are you an independent researcher within 10 years of your PhD or within 5 years of your independent career? Submit your best research to Materials Horizons to be considered to feature in one of our next issues!

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A pathway from nanoscale templates to magnetic assembly of plasmonic chiral nanoparticles: the future of chiral superstructures in nanotechnology

By Olga Guselnikova, Community Board member.

The synthesis and control of the performance of chiral superstructures are intriguing because they bring us closer to the magical concept of chirality, exemplified by the dichotomy between our hands. In the long run, scientists aim to control the chirality of matter, particularly molecules. The enduring challenge is to overcome the mismatch between the molecular work function and magnetic quadrupole transitions and/or the wavelength of light. “Due to this size mismatch, the molecule sees uniform electric and magnetic fields, just as we see the Earth as locally flat,” said Prof. Adam E. Cohen in one of his pioneering reviews on chirality (Nano Today (2009) 4, 269—279). The design of chiral superstructures allows us to sculpt the three-dimensional shape of the electromagnetic field at the size scale of an individual molecule. The most rapidly developing strategy to prepare these nanostructures involves using diverse nanoscale templates, such as origami techniques or lithography. However, the preparation of such nanostructures is very challenging, which slows down the field’s development. Another significant limitation is the inability to dynamically control the handedness and spectral characteristics.

Recent work by Chaolumen Wu and Yadong Yin suggests a magnetic assembly strategy to overcome these limitations. They prepared Ag@Fe3O4 nanoparticles through a relatively simple procedure and further assembled them by introducing a chiral magnetic field from a cubic permanent magnet. This magnet was placed beside the Ag@Fe3O4 suspension and was controlled by two parameters: rotation angle and distance to the suspension (shorter separation distance results in a stronger field strength). The formed assemblies are chains of nanoparticles oriented in a chiral structure. The main advantage of the suggested strategy is the very smoothly controlled dynamicity of the system: spectral position, handedness, and intensity of the chiral signal can be controlled by the magnetic angle and distance relative to the sample. Previously reported approaches required time-consuming simulations and production of plasmonic substrates with those varied chiral characteristics. The authors could fix the chiral superstructures in polymer films with precise control of the handedness, position of optical absorption, and degree of plasmonic coupling. The dynamic optical rotation enables the authors to demonstrate distinguishable color switching. Without the magnet, no color is observed; however, variation of magnet positions gives a wide palette from purple to pink, and from yellow to blue. Therefore, the authors mainly envision the application of this tunability for color-changing optical devices used in anti-counterfeiting and stress sensors.

Figure 1: (a) Simulation of the chiral field distribution from a cubic permanent magnet and schematic illustration of the chirality transfer from a chiral magnetic field to magnetic nanoparticle assembly. (b) TEM image of Ag@Fe3O4 hybrid nanoparticles. (c) Schematic illustration of the setup for measuring the extinction and CD spectrum of particle dispersion under a chiral magnetic field. (d)–(f) Extinction (d), CD (e), and the corresponding g-factor (f) spectra of the Ag@Fe3O4 nanoparticle dispersion without a magnetic field or under a field along the X- and Z-axes. Reproduced from DOI: 10.1039/D3MH01597A with permission from the Royal Society of Chemistry

However, the author of this blog highlights alternative applications. Controlling chiroptical properties is a direct way to enable enantioselective sensing and catalysis by transferring chirality to small molecules. While the application of a chiral quadrupole magnetic field induces the assembly of Ag@Fe3O4, simultaneous irradiation of these structures with a wavelength corresponding to the maximum absorption, due to the presence of Ag, could enhance interactions with small molecules. Photocatalytic reactions performed under a magnetic field, which couple magnetic and light fields, are a novel concept. Although magnetic field-enhanced photocatalysis is relatively new and has mostly been applied to dye degradation, controlling chiral photochemistry with a magnetic field would significantly advance interactions with chiral molecules. In this scenario, applied magnetic fields to Ag@Fe3O4 could serve a dual role of (i) chirality induction and (ii) plasmonic carrier generation and prolongation of the lifetime of excited plasmons.

Research on chirality remains niche due to the complex preparation techniques of chiral superstructures. The published research opens new possibilities for more scientific groups to work in this direction, thanks to the simplicity of using cubic permanent magnets. However, measurement techniques, such as optical rotation density measurement setups, may still pose challenges for the wider community. Increased availability of these techniques should spur more investigations into various applications of chiral nanostructures, including color displays, anti-counterfeiting measures, and chiral sensing and catalysis.

To find out more, please read:

Magnetic assembly of plasmonic chiral superstructures with dynamic chiroptical responses
Chaolumen Wu, Qingsong Fan, Zhiwei Li, Zuyang Yea and Yadong Yin
Mater. Horiz., 2024,11, 680-687, DOI: 10.1039/D3MH01597A

 


About the blogger


 

Dr Olga Guselnikova is a member of the Materials Horizons Community Board. She recently joined the Center for Electrochemistry and Surface Technology (Austria) to work on functional materials as a group leader. Dr. Guselnikova received her PhD degree in chemistry from the University of Chemistry and Technology Prague (Czech Republic) and Tomsk Polytechnic University (Russia) in 2019. Her research interests are related to surface chemistry for functional materials. This means that she is applying her background in organic chemistry to materials science: plasmonic and polymer surfaces are hybridized with organic molecules to create high-performance elements and devices.

 

 

 

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Materials Horizons 10th anniversary Regional Spotlights

Materials Horizons 10th anniversary Regional Spotlights

Showcasing a selection of most popular articles from regions across the world

As part of our 10th anniversary celebrations of Materials Horizons, we have collated a series of Regional Spotlight collections to showcase some of our most popular articles from some of our key regions across the world. We are pleased to share with you our collections spotlighting a selection of most popular articles published over the last decade in Materials Horizons by corresponding authors based in five key regions: Europe, America, China, Asia-Pacific and, Africa and the Middle East.

We invite you to browse the collections to discover just some of the excellent research that has been published in Materials Horizons over the past decade. Click the buttons below to explore the collections.

 

We hope that you have enjoyed browsing the exciting research in our special anniversary Regional Spotlight collections. We are honoured to have published outstanding research from our global community over the last decade and look forward to many more years showcasing materials science from our authors based all over the world!

We would be delighted to receive your future work to Materials Horizons. Check out the scope and requirements on our platform and submit your next work now!

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