Archive for the ‘Uncategorised’ Category

Associate Editor Spotlight – Susan Habas

How do we discover new energy solutions? EES Catalysis delivers the same impact and influence that researchers associate with our Energy & Environmental Science brand. As a multidisciplinary platform, the journal covers catalysis in all subject areas like chemistry, materials science and engineering. At its core, EES Catalysis aligns with the UN’s Sustainable Development Goal (SDG 7) – to ensure access to affordable, reliable and modern energy for all.

To hear more about EES Catalysis, as well as the future news and issue alerts, sign up for e-alerts here.

Editor Spotlight: Susan Habas

Susan Habas, at the National Renewable Energy Laboratory, USA, is one of our Associate Editors handling the peer review of submitted manuscripts. Her research has focused on developing new catalyst materials with tailored active sites and understanding the evolution of these sites under realistic operating conditions. The growing importance of translating innovative catalytic technologies for renewable products to industry, highlights the need for this level of understanding in scalable catalyst materials and integrated systems. In her opinion, designing catalysts that can be readily incorporated into real systems, and understanding and mitigating catalyst deactivation in the presence of common contaminants, will help accelerate adoption of these new technologies.

As such, she is always excited to handle papers that address the design of new materials for thermocatalytic and electrocatalytic applications, as well as multi-scale characterization of integrated catalytic systems for the journal. Her vision is that EES Catalysis becomes the go-to source for fundamental studies that enable the transition to applied catalysis.

Publish with EES Catalysis and receive a number of benefits including:

  • Free Gold Open Access publication – all article processing charges are waived until mid-2025
  • Rapid times to publication – our average time to decision for peer-reviewed manuscripts is just 24 days
  • Flexible article types with no word count restrictions or colour changes
  • Broad readership: our global audience provides maximum exposure for your work
  • Publicity on Twitter and WeChat for featured articles

 

We would be delighted to hear from you if you are interested in submitting to the journal or if you would like any further information. If you are interested in publishing your next paper with us, please contact the journal directly so that we can send you an invited submission link.

Realising the Double Benefit of Selective Ethane Activation

Realising the Double Benefit of Selective Ethane Activation

Descriptor-based identification of bimetallic-derived catalysts for selective activation of ethane with CO2

Haoyue Guo, Zhenhua Xie, Xuelong Wang, Jingguang G. Chen and Ping Liu

EES. Catal., 2023,1, 17-25 DOI D2EY00051B

 

 

An interview with the authors

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

For simultaneously upgrading CO2 and C2 light alkanes into different types of important industrial feedstocks, it is important to control the selective scission of C-H/C-C bonds in alkanes. It is challenging due to the structural complexity of catalysts. By using combined approaches of in situ characterization and DFT calculations, our research can lead to the discovery of active sites for effective catalysts for CO2-assisted alkane activation.

 

How do you feel about EES Catalysis as a place to publish research on this topic?

As a new EES journal with a focus on catalysis, EES Catalysis is an ideal journal to share cutting edge research for catalysis related to energy and environment.

Novel Catalyst for Efficient Hydrogen Production from Formic Acid

Novel Catalyst for Efficient Hydrogen Production from Formic Acid

Boosting the activity of PdAg alloy nanoparticles during H2 production from formic acid induced by CrOx as an inorganic interface modifier

Kohsuke Mori, Tatsuya Fujita and Hiromi Yamashita

EES. Catal., 2023,1, 84-93 DOI D2EY00049K

 

 

Meet the authors

 

 

Kohsuke Mori received his PhD degree from the Graduate School of Engineering Science at Osaka University in 2003. In 2004, he joined at University of California, Berkeley, as a postdoctoral fellow. He moved to the current faculty in 2005 and then became an associate professor in 2009. His current research interests focus on metal and alloy nanoparticle catalysts to establish clean and environmentally-friendly carbon-neural processes, hybrid photocatalysts based on visible-light-responsible MOF, and the fabrication of catalytic reactor by 3D printing technique.

 

 

 

 

 

Tatsuya Fujita received his bachelor’s degree from the School of Engineering at Osaka University in 2022. He is now a first grade of master course student in Graduate School of Engineering at Osaka University. His research topic is the development of highly efficient heterogeneous catalysts for the use of formic acid as a promising hydrogen energy carrier.

 

 

 

 

 

 

 

Hiromi Yamashita has been a professor at Osaka University since 2004. He received a PhD degree from Kyoto University in 1987. He was an assistant professor at Tohoku University and an associate professor at Osaka Prefecture University. He was also a visiting research fellow at the California Institute of Technology. He is now the president of Catalysis Society of Japan (2019–2020) and the president of Asia-Pacific Association of Catalysis Societies (2019–2022). His research interests include the design of single-site photocatalysts and nanostructured catalysts.

 

 

 

 

An interview with the authors

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

The most exciting thing is to discover something unexpected but really new, and the most difficult thing is to observe the actual catalytic reaction and imagine what is true.

 

How do you feel about EES Catalysis as a place to publish research on this topic?

We believe EES Catalysis will provide a powerful platform for presenting cutting-edge research in this fascinating area.

 

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

To do what you want and trust your intuition no matter what.

A Promising Strategy for the Synthesis of Energy Efficient Syngas

A Promising Strategy for the Synthesis of Energy Efficient Syngas

Direct carbonate electrolysis into pure syngas

Yurou Celine Xiao, Christine M. Gabardo, Shijie Liu, Geonhui Lee, Yong Zhao, Colin P. O’Brien, Rui Kai Miao, Yi Xu, Jonathan P. Edwards, Mengyang Fan, Jianan Erick Huang, Jun Li, Panagiotis Papangelakis, Tartela Alkayyali, Armin Sedighian Rasouli, Jinqiang Zhang, Edward H. Sargent and David Sinton.

EES. Catal., 2023,1, 54-61 DOI D2EY00046F

 

Meet the authors

 

 

David Sinton is a Professor in the Department of Mechanical & Industrial Engineering at the University of Toronto and Canada Research Chair. The Sinton group develops fluid systems for applications in energy and analysis. The group is application-driven and is currently developing fluid systems to produce renewable fuels from CO2 and to develop energy efficient industrial working fluids. Dr. Sinton is a Fellow of the Canadian Society for Mechanical Engineering, American Society of Mechanical Engineers, Engineering Institute of Canada, American Association for the Advancement of Science, Canadian Academy of Engineering, and Royal Society of Canada.

 

 

 

 

 

Yurou Celine Xiao is a Ph.D. candidate in the Department of Mechanical & Industrial Engineering at the University of Toronto. Celine’s research is focused on systems design for energy efficient carbon dioxide capture and utilization. She is a recipient of the Hatch Graduate Scholarship for Sustainable Energy Research and the Bert Wasmund Graduate Fellowships in Sustainable Energy Research.

Watch back: EES Catalysis First Issue Webinar

Missed our EES Catalysis First Issue webinar? Watch it back here as our authors and board members discuss the work published in our first issue.

 

 

Find out more about EES Catalysis on our webpage and submit your manuscript here.

Hear from authors and editors in our first issue webinar

Discover the first issue: EES Catalysis

2 March 2023, 13:00 (UK time)

Our upcoming webinar is your chance to discover EES Catalysis. Whether you’re curious about the energy and environmental catalysis research contained in our first issue, or are looking for the right place to publish your own discoveries, join us on 2 March to hear from the authors, researchers and editorial board members.

 

Tune in to the webinar on YouTube or LinkedIn!

 

What will the webinar cover?

Join the people behind the first issue of EES Catalysis to:

  • hear our inaugural editorial board present their highlights from issue one
  • see interviews with the authors, including Professor Kazunari Domen, Professor Kazuhide Kamiya and Ms Celine Xiao
  • find out more about EES Catalysis – and discover a home for your own exceptional research

 

Start exploring EES Catalysis

The first issue of EES Catalysis is ready for you to discover. You’ll find excellent, innovative research on photo-, thermal and electrocatalysis, with great significance towards achieving energy security and zero carbon emission – all free to read online. Read the first issue here.

 

We look forward you joining us.

Professor Susan Habas joins EES Catalysis as an Associate Editor

We are delighted to welcome Professor Susan Habas from the National Renewable Energy Laboratory (NREL), USA, as an Associate Editor for EES Catalysis, a new open access journal publishing high-quality research on energy and environmental catalysis.

 

 

Learn more about our new Associate Editor

Susan Habas is a Senior Scientist and Distinguished Member of Research Staff in the Catalytic Carbon Transformation and Scale-up Center at the National Renewable Energy Laboratory (NREL). She received her Ph.D. in Chemistry from the University of California, Berkeley with Prof. Peidong Yang in 2008. Following her postdoctoral research at Lawrence Berkeley National Laboratory and NREL, Susan joined the NREL research staff in 2012. Her current work focuses on the development of innovative catalysts for selective transformations of renewable and waste carbon sources to fuels and chemicals.

Her interests include the design and synthesis of nanostructured catalysts with tailored surface chemistry, continuous flow methods for scalable synthesis and discovery of catalytic materials, and non-thermal plasma catalysis. She is a Principal Investigator in the Chemical Catalysis for Bioenergy Consortium, leading a multi-national laboratory effort to advance new synthetic approaches and operando characterization capabilities for catalytic systems.

 

Read one of Susan’s papers published by RSC below:

An investigation into support cooperativity for the deoxygenation of guaiacol over nanoparticle Ni and Rh2P

Catal. Sci. Technol., 2017,7, 2954-2966

 

Please join us in welcoming Professor Habas to EES Catalysis.

 

EES Catalysis is open for submissions. Find out more on the journal webpagesign up for email alerts or submit your manuscript now.

Hear from the first authors of EES Catalysis

 

EES Catalysis has now published its first issue, which is available to read online. We are delighted to be sharing reflections from some of our first authors on their experience publishing with EES Catalysis and Open Access publishing.

 

Hear from our first authors:

 

Structural ordering enhances highly selective production of acetic acid from CO2 at ultra-low potential

Peter et al. EES. Catal., 2023, Advance Article, DOI: 10.1039/D2EY00081D

 

“The article I published was titled ‘Structural Ordering Enhances Highly Selective Production of Acetic Acid from CO2 at Ultra-Low Potential’, and it provides a novel strategy to improve electrochemical performance towards the formation of high value-added chemicals selectively at ultra-low potential.

This work was reviewed originally in EES, which later recommended to transfer to EES: Catalysis after receiving the reports from the reviewers. I chose to publish my work in your journal because I was confident that it would be well-received by your readers. EES Catalysis even though new it’s focus is predominantly capturing research in the field of catalysis which is presently one of the pivotal solutions to global warming and I was confident that if I submitted my work to you, it would be given the respect and attention it deserved. Furthermore, I was impressed by the range of topics covered by your journal, and felt that my work would fit in nicely with the other articles published in it.

 I am a strong advocate of open access publishing. I believe that everyone should have the right to access knowledge, regardless of their ability to pay. Open access publishing makes it possible for anyone to access information and research, which can help bridge the gap between those who have access to resources and those who do not. This is an important step in creating a more equitable society and I am proud to be part of a journal that supports open access publishing”.

 

 

Ultra-high-rate CO2 reduction reactions to multicarbon products with a current density of 1.7 A cm-2 in neutral electrolytes

Nakanishi, Kamiya et al., EES. Catal., 2023,1, 9-16, DOI: 10.1039/D2EY00035K

 

“In this paper, we have revealed the hidden potential of the standard catalyst for CO2RR through macroscale design. This novel insight provides us with a general guideline for designing novel materials, such as catalysts and electrodes, because our electrodes are only composed of standard components.

Our record work has significant implications for various researchers, such as chemists, physicists and energy economists. More importantly, our work clearly shows that materials chemists should be interested because we need to be careful about the macroscale structure even when synthesising nanoscale catalysts”.

 

 

ZSM-5 confined Cr1-O4 active sites boost methane direct oxidation to C1 oxygenates under mild conditions

Xiao-Ming Cao and Yang Lou et al. EES. Catal., 2023, Advance Article, DOI: 10.1039/D2EY00080F

 

Transforming methane to high-value oxygenated products (like CH3OH, HCCOH etc.) is highly attractive in the field of energy, environment and chemical engineering. Traditionally, methane conversion can be achieved through an indirect process that couples methane reforming and a Fischer-Tropsch synthesis but such an indirect route normally requires high pressures (up to 30 bar) and temperatures (1100-1300 K) with large energy inputs.

 In this present work, we report a ZSM-5 supported non-noble Cr single atom catalyst as a proof-of-concept catalyst (Cr1/ZSM-5 SAC) with a unique Cr1-O4 entity as the active site to selectively and efficiently convert methane to HCOOH and other value-added C1 oxygenates under mild conditions. The catalytic performance of Cr1/ZSM-5 SAC outperforms most reported state-of-the-art catalysts.

Energy & Environmental Science is an international and highly reputed journal in the field of energy and environmental catalysis. Hence, we believe that the newly launched EES Catalysis will be another highly reputed and international journal in this field. As a gold open access journal, we believe the published research work will be much more freely, easily and faster to spread in the research community, which will help create a barrierless innovation platform in the world.

 It was a very wonderful experience for publishing our work on EES Catalysis. The review period is very fast and the questions proposed by the peers are very professional. We believe that the open access publishing will be the new way to spread science to professional researchers and social publics”.

 

 

Boosting the activity of PdAG allow nanoparticles during H2 production from formic acid induced by CrOx as an inorganic interface modifier

Mori, Yamashita et al., EES. Catal., 2023,1, 84-93, DOI: 10.1039/D2EY00049K

 

“Boosting the activity of PdAg alloy nanoparticles during H2 production from formic acid induced by CrOx as an inorganic interface modifier. The interfacial modification of PdAg nanoparticles with highly dispersed CrOx boosts the dehydrogenation of formic acid with extremely high turnover number. We are sure that our findings are of immediate interest to catalysts design research readership aiming at realizing environmentally-friendly hydrogen release systems.

We are very happy to publish the latest research results in this memorable first volume. We believe EES Catalysis will provide a powerful platform for presenting cutting-edge research in this fascinating area. Being able to post links to open access articles on our home page is a very effective way to reach out to interested readers”.

EES Catalysis: first issue out now

Open to everyone. Impactful for all: our first issue is available to explore

How do we discover new energy and environmental catalysis solutions? Handpicked by our editors, the first issue of EES Catalysis, our new, gold open access journal, showcases high-quality research on energy and environmental catalysis. Read issue 1 now.

Issue 1 includes:

Introducing EES Catalysis

Shizhang Qiao

EES Catal. 2023, 1, 7-8, DOI: 10.1039/D2EY90001G

 

Ultra-high-rate CO2 reduction reactions to multicarbon products with a current density of 1.7 A cm-2 in neutral electrolytes

Asato Inoue, Takashi Harada, Shuji Nakanishi, Kazuhide Kamiya

EES Catal. 2023, 1, 9-16, DOI: 10.1039/D2EY00035K

 

Descriptor-based identification of bimetallic-derived catalysts for selective oxidation of ethane with CO2

Haoyue Guo, Zhenhua Xie, Xuelong Wang, Jingguang G. Chen, Ping Liu

EES Catal. 2023, 1, 17-25, DOI: 10.1039/D2EY00051B

 

Zr-doped BaTaO2N photocatalyst modified with Na-Pt cocatalyst for efficient hydrogen evolution and Z-scheme water splitting

Huihui Li, Junie Jhon M. Vequizo, Takashi Hisatomi, Mamiko Nakabayashi, Jiadong Xiao, Xiaoping Tao, Zhenhua Pang, Wenping Li, Shanshan Chen, Zheng Wang, Naoya Shibata, Akira Yamakata, Tsuyoshi Takata, Kazunari Domen

EES Catal. 2023, 1, 26-35, DOI: 10.1039/D2EY00031H

 

Pit-embellished low-valent metal active sites customise CO2 photoreduction to methanol

Wei Zhao, Miao Ding, Pengxin Yang, Qiang Wang, Kaifu Zhang, Xiaowen Zhan, Yu Yu, Qiquan Luo, Shan Gao, Jinlong Yang, Yi Xie

EES Catal. 2023, 1, 36-44, DOI: 10.1039/D2EY00029F

 

High-efficiency electrosynthesis of urea over bacterial cellulose regulated Pd-Cu bimetallic catalyst

Shengbo Zhang, Jing Geng, Zhong Zhao, Meng Jin, Wenyi Li, Yixing Ye, Ke Li, Guozhong Wang, Yunxia Zhang, Huajie Yin, Haimin Zhang, Huijun Zhao

EES Catal. 2023, 1, 45-53, DOI: 10.1039/D2EY00038E

 

Direct carbonate electrolysis into pure syngas

Yurou Celine Xiao, Christine M. Gabardo, Shijie Liu, Geonhui Lee, Yong Zhao, Colin P. O’Brien, Rui Kai Miao, Yi Xu, Jonathan P. Edwards, Mengyang Fan, Jianan Erick Huang, Jun Li, Panagiotis Papangelakis, Tartela Alkayyali, Armin Sedighian Rasouli, Jinqiang Zhang, Edward H. Sargent, David Sinton

EES Catal. 2023, 1, 54-61, DOI: 10.1039/D2EY00046F

 

Fe-N/C catalysts with tunable mesoporous structures and carbon layer numbers reveal the role of interlayer CO2 activation

Jinwoo Woo, June Sing Lim, Taejung Lim, Du San Baek, Jae Hyung Kim, Jong Hoon Lee, Hu Young Jeong, Chang Hyuck Choi, Sang Hoon Joo

EES Catal. 2023, 1, 62-73, DOI: 10.1039/D2EY00055E

 

Effect of charge selective contacts on the quai Fermi level splitting of CuGa3Se5 thin film photocathodes for hydrogen evolution and methylviologen reduction

Ye Cheng, Chengcan Xiao, Behzad Mahmoudi, Roland Scheer, A. Wouter Maijenburg, Frank E. Osterloh

EES Catal. 2023, 1, 74-83, DOI: 10.1039/D2EY00062H

 

Boosting the activity of PdAg alloy nanoparticles during H2 production from formic acid induced by CrOx as an inorganic interface modifier

Kohsuke Mori, Tatsuya Fujita, Hiromi Yamashita

EES Catal. 2023, 1, 84-93, DOI: 10.1039/D2EY00049K

 

Maximise the visibility of your research by publishing gold open access

All papers published in EES Catalysis will forever be free to read. We are waiving article processing charges (APCs) until mid-2025, so it is currently free to publish in for authors.

 

Submit your manuscript to EES Catalysis here!

COP27 satellite events – watch our webinars!

To celebrate the launch of our three new journals, RSC Sustainability, EES Catalysis, and Sustainable Food Technology,  earlier this year, we organised three satellite events that ran in parallel to this year’s COP27 meeting in Egypt.

 

Our new journals all address topics that align with several of the UN Sustainable Development Goals. Each journal hosted a webinar where the panels discussed some of the current challenges and opportunities in their respective fields through a mix of live speakers and pre-recorded contributions.

 

RSC Sustainability

Join RSC Sustainability board members Tom Welton and Fran Kerton, along with RSC’s Programme Manager for Net Zero John Broderick as they discuss the challenges and opportunities for sustainable chemistry.

Find out more about RSC Sustainability and read our first published articles.

 

 

EES Catalysis

Join the RSC’s Programme Manager for Net Zero John Broderick and Jonathan Oxley (CBI Humber Cluster project) as they share their thoughts about challenges and opportunities for hydrogen as a sustainable fuel source.

Find out more about EES Catalysis and read our first published articles.

 

 

Sustainable Food Technology

Join Sustainable Food Technology board members Jorge Barros Velázquez, Rekha Singhal, Umezuruike Linus Opara, and Indrawati Oey as they discuss the challenges and opportunities to make food production more sustainable for the future.

Find out more about Sustainable Food Technology and read our first published articles.

 

 

We hope you enjoy these webinars and reading the first articles in our new journals!