Nanoscale & Nanoscale Advances Blog

Experimental and theoretical evidence for unprecedented strong interactions of gold atoms with boron on boron/sulfur-doped carbon surfaces

Nanoscale Advances publishes experimental and theoretical work across the breadth of the nanoscienes, which are open access and free to read. We are excited to highlight a recent article on the detection of direct Au-B interactions in nanomaterials with the potential for controlling the dynamics of metal atoms on fabricated matrices and a new-generation of nano-devices with wide applications.

In this post, we share insights from our interview with the authors of this paper titled “Experimental and theoretical evidence for unprecedented strong interactions of gold atoms with boron on boron/sulfur-doped carbon surfaces“.

Insights from the authors of a recent Nanoscale Advances article

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

“The prospect of using new techniques to explore the chemistry of metals on the nanoscale level, not only for understanding the chemistry of biologically essential metals, but also for applications in disease diagnosis and drug design.”

What do you find most challenging about your research?

“The challenges posed by dynamic metallomics- those of defining on the nanoscale the oxidation states of metal ions, the nature of the coordinated ligands, as well as their coordination geometries and tracking changes on timescales of nanoseconds to years.
Our paper shows we have come close to achieving this for a single gold atom. We dream of using a similar approach to unravel the chemistry of the formation and properties of metallic iron and copper nanocrystals in the brain [https://www.science.org/doi/10.1126/sciadv.abf6707]”

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

“Perfect for our current discoveries which are based not only on experimental studies using state-of-the-art techniques, but also on challenging theoretical calculations.”

What is one piece of career-related advice or wisdom that you would like to share with early career scientists?

“Enjoy the excitement of discovery research- the unexpected findings that open up totally new areas of research. That was how our research on single-metal-atom coordination chemistry began!”

Meet the authors

Samya Banerjee (MRSC) received his PhD in 2015 from the Indian Institute of Science. Subsequently, he was a postdoctoral fellow at Johns Hopkins University, USA, a Royal Society-SERB Newton International Fellow at the University of Warwick, UK (with Prof. Peter J. Sadler), and a postdoctoral fellow at the Georg-August Universität Göttingen, Germany. He is currently an Assistant Professor at the Indian Institute of Technology (BHU), India. Recently, he was awarded a 2022 Dalton Division Horizon Prize by the Royal Society of Chemistry for pioneering work on “catalysis of redox reactions in cancer cells by synthetic organometallic complexes”. His research interests include the development of metal-based anticancer, antibacterial and antimalarial drugs.

Juliusz A. Wolny graduated in Chemistry at the University of Wrocław and completed his PhD thesis in inorganic chemistry. He worked in the area of synthetic chemistry and molecular spectroscopy in the groups of Professors Mikołaj F. Rudolf in Wrocław, Alex von Zelewsky in Fribourg, and Hans Toftlund in Odense. He has also worked in the area of applied quantum chemistry and synchrotron spectroscopy in the group of Professor Alfred X. Trauwein in Lübeck. Since 2006, he has been a researcher at the University of Kaiserslautern in the group of Professor Volker Schünemann. His scientific interest involves the spin-crossover effect, vibrational spectroscopy, conventional and synchrotron Mössbauer spectroscopy and application of quantum chemical methods to inorganic complexes.

Mohsen is a senior EM staff scientist at the electron Physical Science Imaging Centre (ePSIC) at the Diamond Light Source. His main research is currently on the use of Scanning Electron Nanobeam Diffraction (SEND) for better statistical characterisation of engineering materials via development of automated data analysis workflows combined with script-controlled data collection on the electron microscope. He completed his PhD at the University of Alberta (Edmonton, Canada) in 2010, with thesis on transmission electron microscopy (TEM) characterisation of beam-sensitive Mg-based hydride systems.

Dedication to Professor Nicolas Barry: Nicolas obtained his PhD at Neuchâtel University in Switzerland in 2011. He was then awarded a research fellowship by the Swiss National Science Foundation to join the Sadler lab in the Department of Chemistry at the University of Warwick. His research on organometallic precious metal carborane complexes encapsulated in polymer micelles opened up an entirely new area of research. Unexpectedly, TEM studies of such micelles with Richard Beanland and Peter Sadler at Warwick led to the discovery that irradiation of these nanoparticles in a TEM instrument rapidly generates a graphenic lattice containing precious metal atoms which migrate to form molecules, clusters and nanocrystals. That work initiated several subsequent studies on single-metal-atom coordination chemistry, and the role of dopants in the formation of metal nanocrystals, including that on gold reported in this current Nanoscale Advances paper. In 2014 he was awarded a Leverhulme Early Career Research Fellowship to initiate an independent career at Warwick, and in 2016 a Royal Society University Research Fellowship, which he took up at the University of Bradford. In 2020 he was appointed to a Professorship there. He excited school students with his enthusiasm for chemistry, leading an exhibit entitled ‘Molecular Music – the sound of chemistry’ at the 2019 Royal Society Summer Science Exhibition, in partnership with Ilkley Grammar School, turning the vibrations in molecules into musical notes. He was a highly talented metal coordination chemist. His research collaborators, colleagues, school-students, friends, and family alike all miss him greatly.

Dr Yisong Han is currently Scientific Officer at the University of Warwick, where he provides advanced scientific and technical support for transmission electron microscopy (TEM) instruments. Before joining Warwick, he gained extensive postdoctoral research experience in characterising a variety of materials using TEM related techniques. He completed his PhD at the University of Nottingham in 2007.

Dr Houari Amari is a Research Group Leader at the Leibniz institute for crystal growth (Berlin, Germany). He obtained his MSc (Hons.) from the University of Strasbourg (France) and his Ph.D. from the University of Sheffield (United Kingdom). His Ph.D. was related to investigations of novel semiconductors using advanced transmission electron microscopy (TEM) techniques. Dr Amari’s actual research is focused on achieving atomic-level structural and chemical characterization of a wide range of materials, including semiconductors and dielectrics, using in-situ TEM.

Prof. Beanland is academic director of Warwick’s Electron Microscopy facility and holds a personal chair in the Department of Physics at the University of Warwick, with interests in electron diffraction, structure solution, and atomic-scale characterisation of materials.

Volker Schünemann studied physics at the University of Hamburg and did his PhD thesis under the supervision of Alfred X. Trautwein at the University of Lübeck, where he worked on the synthesis and characterization of iron nanoparticles in zeolites. This was his first exposure to temperature- and field-dependent Mössbauer spectroscopy. Subsequently, in 1993, he did postdoctoral work on bimetallic FeRh particles in the group of W.M.H. Sachtler at Northwestern University, Evanston, USA. Here the focus was on catalytic properties in CO hydrogenation. After his return in 1994 to the group of Alfred X. Trautwein to the University of Lübeck, he started to work on biological applications of Mössbauer spectroscopy and investigated different classes of iron-containing proteins such as heme and iron-sulfur proteins. In 2004, he became a professor at the University of Kaiserslautern and established a laboratory for temperature- and field-dependent Mössbauer spectroscopy. The focus of his group is on the study of the function and electronic and dynamical properties of iron centers in nature (iron proteins) and coordination chemistry (e.g., spin-crossover compounds, molecular magnets, and biomimetic iron complexes) using conventional and synchrotron-based Mössbauer spectroscopy. Quantum chemical calculations based on density functional theory (DFT) are also used to better understand electronic and dynamic properties.

Peter obtained his BA, MA and DPhil at the University of Oxford. Subsequently he was a Medical Research Council Research Fellow at the University of Cambridge and National Institute for Medical Research. From 1973-96 he was Lecturer, Reader and Professor at Birkbeck College, University of London, and from 1996-2007 held the Crum Brown Chair of Chemistry at the University of Edinburgh. In 2007, he took up a Chair in Chemistry at the University of Warwick as Head of Department, where he is now a Professor. He is a Fellow of the Royal Society of Chemistry, the Royal Society of Edinburgh, and the Royal Society of London, an EPSRC RISE Fellow (Recognising Inspirational Scientists and Engineers), a Fellow of the European Academy of Sciences, and an Honorary Fellow of the Chemical Research Society of India, and the Chinese Chemical Society. He was awarded the Royal Society 2022 Davy Medal, and 2022 Royal Society of Chemistry Dalton Horizon Team Prize.

We congratulate the authors on their impactful work and wish them success in their future academic research!

An infographic highlighting new protein-protected noble metal nanoclusters

Higher-order assembly of BSA gold nanoclusters using supramolecular host–guest chemistry: a 40% absolute fluorescence quantum yield
Anjan Maity* and Atul Kumar
Nanoscale Adv., 2022, 4, 2988-2991, DOI: 10.1039/D2NA00123C

Meet the authors

Anjan Maity was born and brought up in a village named Naguria, just beside the Rupnarayan River in Purba Medinipur in a humble farmer’s family. From childhood, he had the vision to contribute to society and propel his country in the right direction by becoming an IAS officer. But, life directed him on a different path, and he have become a prolific researcher in the chemical science community. He pursued his B.Sc. in Chemistry (Hons.) from Vidyasagar University, followed by an M.Sc. in Chemistry at the Indian Institute of Technology, Kharagpur (IIT-Kharagpur) securing all India rank (AIR) 62 in IIT-JAM examination. He had multiple brief research stints at the Indian Institute of Technology, Kanpur (IIT-Kanpur), Indian Institute of Technology, Guwahati (IIT-Guwahati), JNCASR-Bangalore, and National Chemical Laboratory, Pune (NCL-Pune). Finally, he joined as a Ph.D. scholar at the Indian Institute of Science, Bangalore, India, in January 2020 with the support of a UGC fellowship securing AIR 24 in the National Eligibility Test (NET). He worked under a prestigious Ph.D. fellowship (Prime Minister’s Research Fellowship, PMRF, Ministry of Education, Government of India). His research is purely experimental in nature and based on the synthesis and characterizations of protein-protected gold nanoclusters, tuning its optoelectronic properties by utilizing supramolecular host-guest chemistry and further utilizing it in biology. Apart from research, he studies music, is an avid music listener, and loves playing the violin.

a) What aspect of your work are you most excited about at the moment and what do you find most challenging about your research?

It is a biocompatible fluorescent molecule that can be utilized in biological applications. The most challenging task was synthesizing the CB7 molecule and designing the higher-order assembly.

b) How do you feel about Nanoscale Advancesas a place to publish research on this topic?

Nanoscale Advances is a gold open access journal. Because of this, my work visibility and citation will be much higher. Moreover, since my work is more advanced in this topic of BSA gold nanocluster, so, I feel it is perfect for my work.

c) Can you share one piece of career-related advice or wisdom with other early career scientists?

This is an excellent research area not only in academia but also will help to get a position as a scientist in various industries.

We wanted to share with you some of the most popular articles published in Nanoscale Advances since the journal was launched last year. These articles are the most highly cited, most read, or most highly shared online to date.

Our community have published some fantastic research in Nanoscale Advances since launch in 2018 and we wanted to make it even easier for you to find the best articles.

Nanoscale Advances most popular articles, 2018

Here are just a few picks from the collection. We hope you enjoy them.

Reviews

Biomolecule-derived quantum dots for sustainable optoelectronics

Satyapriya Bhandari, Dibyendu Mondal, S. K. Nataraj and R. Geetha Balakrishna

Nanoscale Adv., 2019, 1, 913-936

Communications

Detection of microRNA biomarkers via inhibition of DNA-mediated liposome fusion

Coline Jumeaux, Eunjung Kim, Philip D. Howes, Hyemin Kim, Rona Chandrawati and Molly M. Stevens

Nanoscale Adv., 2019, 1, 532-536

Are octahedral clusters missing on the carbon energy landscape?

Tomas Lazauskas, Alexey A. Sokol and Scott M. Woodley

Nanoscale Adv., 2019, 1, 89-93

Papers

Chemically reactive protein nanoparticles for synthesis of a durable and deformable superhydrophobic material

Arpita Shome, Adil Majeed Rather and Uttam Manna

Nanoscale Adv., 2019, Advance Article

Synthesis and characterization of silver nanoparticle-loaded amorphous calcium phosphate microspheres for dental applications

Mayuresh Keskar, Camila Sabatini, Chong Cheng and Mark T. Swihart

Nanoscale Adv., 2019, 1, 627-635

Tetradic phosphor white light with variable CCT and superlative CRI through organolead halide perovskite nanocrystals

Gopi C. Adhikari, Preston A. Vargas, Hongyang Zhu, Alexei Grigoriev and Peifen Zhu

Nanoscale Adv., 2019, Advance Article

Rh-doped MoSe₂ as a toxic gas scavenger: a first-principles study

Hao Cui, Guozhi Zhang, Xiaoxing Zhang and Ju Tang

Nanoscale Adv., 2019, 1, 772-780

For the full collection, please see the journal website here.

We wanted to share with you some of the most popular articles published in Nanoscale from last year. These articles are the top 5% most highly cited, most read, or most highly shared online throughout 2018.

Our community have published some fantastic research in Nanoscale during 2018 and we wanted to make it even easier for you to find the best articles.

Nanoscale most popular articles, 2018

Here are just a few picks from the collection. We hope you enjoy them.

Reviews

Plasmonics with two-dimensional semiconductors: from basic research to technological applications

Amit Agarwal, Miriam S. Vitiello, Leonardo Viti, Anna Cupolillo and Antonio Politano

Nanoscale, 2018, 10, 8938-8946

Recent advances in the nanoengineering of electrocatalysts for CO₂ reduction

Fengwang Li, Douglas R. MacFarlane and Jie Zhang

Nanoscale, 2018, 10, 6235-6260

Communications

Electrohydrodynamic printing of silver nanowires for flexible and stretchable electronics

Zheng Cui, Yiwei Han, Qijin Huang, Jingyan Dong and Yong Zhu

Nanoscale, 2018, 10, 6806-6811

Fabrication of hierarchical CoP nanosheet@microwire arrays via space-confined phosphidation toward high-efficiency water oxidation electrocatalysis under alkaline conditions

Xuqiang Ji, Rong Zhang, Xifeng Shi, Abdullah M. Asiri, Baozhan Zheng and Xuping Sun

Nanoscale, 2018, 10, 7941-7945

Papers

Graphitic and oxidised high-pressure high temperature (HPHT) nanodiamonds induce differential biological responses in breast cancer cell lines

Benjamin Woodhams, Laura Ansel-Bollepalli, Jakub Surmacki, Helena Knowles, Laura Maggini, Michael de Volder, Mete Atatüre and Sarah Bohndiek

Nanoscale, 2018, 10, 12169-12179

Spray coating of the PCBM electron transport layer significantly improves the efficiency of p-i-n planar perovskite solar cells

Yifan Zheng, Jaemin Kong, Di Huang, Wei Shi, Lyndsey McMillon-Brown, Howard E. Katz, Junsheng Yu and André D. Taylor

Nanoscale, 2018, 10, 11342-11348

Synthesis of garlic skin-derived 3D hierarchical porous carbon for high-performance supercapacitors

Qing Zhang, Kuihua Han, Shijie Li, Ming Li, Jinxiao Li and Ke Ren

Nanoscale, 2018, 10, 2427-2437

For more articles, see the full collection here.

When it comes to cancer treatment, smaller can sometimes be better, as a new HOT article published in Nanoscale has shown. New ultra-small hybrid nanoparticles, developed by Jiangfang Zhang and a team based at the University of California, have proven highly effective at delivering anti-cancer drugs in mice – the nanoparticles, which are under 25nm in size, could penetrate deep into the tumours of the mice to release the drug where it would be most effective.

The size of drug delivery nanocarriers has a crucial role in how effective they are at moving through the body: too large, and they will be cleared by the liver; too small, and they will be filtered by the kidneys. Cancer drug carriers work best at sizes below 50nm, where they can more easily infiltrate tumours, but preventing such small particles from aggregating once synthesised can be a challenge. Zhang’s team used both lipids and polymers to make their nanoparticles highly stable, even in physiological conditions –  the polymer cores took up the hydrophobic drug, while the lipid coating provided stability and protection from the aqueous environment of the body.

The nanoparticles were targeted to tumour cells by conjugating them to folate ligands – when injected into mice with induced tumours, the number of target nanoparticles present within the tumours was three times that of non-targeted carriers. What’s more, the anti-cancer drug docetaxel could be loaded into the nanoparticles and used to treat the mice, with highly promising results. Over half of the mice treated with the hybrid nanocarriers were still alive 64 days after having tumours induced, a significant extension compared to a clinically used drug treatment.

Read the full article here:

Ultra-small lipid–polymer hybrid nanoparticles for tumor-penetrating drug delivery

Diana Dehaini, Ronnie H. Fang, Brian T. Luk, Zhiqing Pang, Che-Ming J. Hu, Ashley V. Kroll, Chun Lai Yu,  Weiwei Gao and Liangfang Zhang*
Nanoscale, 2016, Advance Article

Susannah May is a guest web writer for the RSC Journal blogs. She currently works in the Publishing Department of the Royal Society of Chemistry, and has a keen interest in biology and biomedicine, and the frontiers of their intersection with chemistry. She can be found on Twitter using @SusannahCIMay.