Author Archive

Modelling in Environmental Nanotechnology

We are delighted to announce the publication of a themed collection on Modelling in Environmental Nanotechnology, guest edited by Mohammed Baalousha (University of South Carolina, US), Panos Georgopoulos (Rutgers University, US), Jamie Lead (University of South Carolina, US) and Dave Spurgeon (Centre for Ecology & Hydrology, UK).

This collection of papers presents state-of-the-art models for the fate, behaviour, exposure, uptake and toxicity of nanomaterials in the environment and in organisms, as well as a wide range of model types for environmental and biological processes affecting nanomaterial behaviour.

Read the full collection today: http://rsc.li/modelling

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Insights from SNO 2014 Annual Conference

In November 2014, the Sustainable Nanotechnology Organization (SNO), a non-profit, international, professional society, held its 3rd annual conference in Boston with over 220 participants in attendance. Drs. Jackie Isaacs of Northeastern University and Philp Demokritou of Harvard University co-chaired the meeting. SNO is dedicated to advancing sustainable nanotechnology around the world through education, research, and responsible growth of nanotechnology.

This themed collection is the summary of representative research papers presented at the Boston conference. Seven eminent scientists and engineers in the field of sustainable nanotechnology gave plenary lectures attended by participants from almost every U.S. state as well as many other countries. About 45% of participants were students, indicative of the recentness of the field.

Selected papers from the conference highlight how sustainable nanotechnology is leading the way to address economic development, global food supplies, as well as energy and water challenges while leaving minimal footprints that can give rise to environmental degradation.

Some of the papers represent the core aspects of sustainable nanotechnology, including biomedical applications, water treatment, green synthesis, life cycle assessments (LCA) and NanoEHS issues. Demokritou et al. present an integrated methodology for the assessment of environmental health implications during thermal decomposition of nano-enabled products.

Demokritou et al., DOI: 10.1039/C4EN00210E

An article by Vicki Grassian et al. reports an important finding that simple nanoscale materials can be complex when considering NanoEHS implications. A number of the fundamental research areas to address NanoEHS needs are suggested.

Grassian et al.

Grassian et al., DOI: 10.1039/C5EN00112A

In a review article by Gilbertson, Wender, Zimmerman, and co-workers, the authors summarize recent advances in human and aquatic ecotoxicity life cycle impact assessment for engineered nanomaterials (ENMs) and call for greater coordination between LCA modelers and experimentalists, including those who study fate and transport, environmental transformations, occupational exposure, and toxicology, to inform responsible development of nanotechnology, enabling the technology to reach its full potential.

Gilbertson et al.

Gilbertson et al., DOI: 10.1039/C5EN00097A

The development of nanomaterials and nano-enabled products in a “greener” manner will minimize any EHS implications while maximizing the societal benefits.  Companies working with engineered nanomaterials are expected to make tradeoffs on the costs associated with increased levels of occupational safety and potential environmental impacts. For example, Isaacs et al. present a paper on the economic analysis of carbon nanotube (CNT) lithium-ion battery manufacturing. These authors present a stochastic process-based cost model to investigate the cost drivers for the manufacture of multi-walled CNT nickel manganese cobalt batteries that are targeted for satellite and computer applications. Among other things their results underscore the need for safer manufacturing practices for CNT lithium-ion batteries for application in low and high production volume products such as satellites and portable computers, respectively.

Isaacs et al.

Isaacs et al., DOI: 10.1039/C5EN00078E

Greener nanotechnology can be the “role model” for industrial development in the 21st century. Sadik et al. demonstrate that a one-pot synthesis of silver and gold nanoparticles is possible using conductive, electroactive, and biodegradable polymers. In addition to modest cytotoxicity against non-cancerous, immortalized and cancerous cell lines, the synthesized nanoparticles exhibit excellent antibacterial activity against gram negative and gram positive bacteria.

Sadik et al.

Sadik et al., DOI: 10.1039/C5EN00053J

Pourzahedi et al. apply green chemistry and sustainable manufacturing to nanomaterial synthesis, with the goal of reducing life cycle energy use and environmental impacts. The authors use LCA to analyze and compare the environmental impacts of AgNPs produced through seven different synthesis routes (cradle-to-gate). LCA reveals both direct and indirect or upstream impacts associated with AgNPs. Results show that across synthesis routes, impacts associated with the upstream production of bulk silver itself are dominant for nearly every category of environmental impact, contributing to over 90% of life cycle burdens in some cases. The bio-based chemical reduction route has important tradeoffs in ozone depletion potential and ecotoxicity.

Pourzahedi et al.

Pourzahedi et al., DOI: 10.1039/C5EN00075K

The release of ENMs into the environment has led to concerns about the potential risks to food safety and human health. Ebbs et al. describe the extent of ENM uptake into plant foods. The authors focus on the accumulation of zinc, copper, or cerium in carrot exposed to metal oxide nanoparticles and metal ions. They demonstrate that ENMs are no more toxic than the ionic treatments and show a reduced accumulation in the edible tissues of carrot. The results demonstrate that the understanding of ionic metal transport in plants may not accurately predict ENM transport and that an additional comparative study is needed for this and other crop plants.

Ebbs et al.

Ebbs et al., DOI: 10.1039/C5EN00161G

Rodrigues et al. provide an assessment of the toxicity of exfoliated-MoS2 and annealed exfoliated-MoS2 towards planktonic cells, biofilms, and mammalian cells in the presence of electron donor.

Rodrigues et al.

Rodrigues et al., DOI: 10.1039/C5EN00031A

Lee et al. report the development of precisely engineered manganese oxide nanoscale particles for the sorption of uranium as uranyl in water. They synthesize nanoparticles via thermal decomposition of manganese oleate and then phase-transfer the particles into water using ligand exchange and bilayer stabilization methods. The resulting monodisperse suspensions demonstrate significantly enhanced uranyl adsorption as a function of size, surface coating chemistries, and solution pH.

Lee et al.

Lee et al., DOI: 10.1039/C5EN00010F

The fate of dysprosium oxide nanoparticles (Dy2O3) and their effects on natural biological systems are a growing concern. Oyanedel-Craver et al. have assessed the toxicity of nDy2O3 on Escherichia coli for concentrations between 0.02 and 2 mg/L exposed to three concentrations of NaCl and three glucose concentrations. Toxicity measurement of Dysprosium ion Dy(+3) suggest that it is the main contributor to the overall toxicity.

Oyanedel-Craver et al.

Oyanedel-Craver et al., DOI: 10.1039/C5EN00074B

Among other applications, engineered superparamagnetic nanoparticles have broad potential in biotechnologies, high contrast magnetic resonance imaging, and advanced environmental sensing and remediation technologies. Fortner et al. present the flexible surface design strategies for a variety of superparamagnetic iron oxide nanoparticles for applications in aqueous systems.

Fortner et al.

Fortner et al., DOI: 10.1039/C5EN00089K

Chen et al. describe the aggregation and interactions of chemical mechanical planarization nanoparticles with model biological membranes, focusing on the role of phosphate adsorption.

Loon Chen et al.

Chen et al., DOI: 10.1039/C5EN00176E

The difficulty of meeting the world’s energy demand is compounded by the growing need to protect human health and the environment. Nanotechnology will play a major role in the development of clean, affordable, and renewable energy sources. Soroush et al. demonstrate that silver nanoparticle (AgNPs)-decorated graphene oxide (GO) functionalized membranes exhibit super-hydrophilic properties with contact angles below 25°. The membranes also exhibit significant E. coli inactivation without adversely affecting the membrane transport properties. Such membrane could be employed as composites of forward osmosis and seawater desalination because of its energy efficiency.

Soroush et al.

Soroush et al., DOI: 10.1039/C5EN00086F

We hope you enjoy this issue which represents a snapshot of the wider conversation on the topic of sustainable nanotechnology. We also invite you to visit us at www.susnano.org as we develop a framework for using nanotechnology to address grand global challenges in the energy, water, and food sectors while maintaining a balance between the economic, environmental, and societal issues.

Enjoy this issue!

Wunmi Sadik, President & Co-founder
Barbara Karn, Executive Director & Co-founder
Jacqueline Isaacs and Philip Demokritou, SNO 2014 Co-Chairs

Read the full collection online today: http://rsc.li/sno

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Vicki Grassian moves to UC San Diego

We are delighted to share with our community that our Editor-in-Chief Professor Vicki Grassian has joined the Departments of Chemistry and Biochemistry, Nanoengineering and Scripps Institution of Oceanography at UC San Diego, USA.

Vicki Grassian, Distinguished Professor and Distinguished Chair of Physical Chemistry, left the University of Iowa, where she held appointments in the Departments of Chemistry, Chemical and Biochemical Engineering, and Occupational and Environmental Health.

Prof Grassian’s research focuses on fundamental molecular-based laboratory studies that provide a better molecular understanding of the surface chemistry of complex environmental interfaces.

Her projects include understanding the molecular level details of the heterogeneous chemistry of trace gases with particulate matter such as mineral dust in the atmosphere, dissolution and mobilization of Fe-containing particles, optical properties of atmospheric aerosol and applications and implications of nanoscience and nanotechnology in environmental processes and human health.

In the past five years, Vicki has received several awards for her research including the American Chemical Society National Award for Creative Advances in Environmental Science and Technology (2012), the Midwest American Chemical Society Award (2014) and the Royal Society of Chemistry John Jeyes Award (2014).

Her appointment at UC San Diego began on the 1st January 2016.

Please join us in wishing Vicki all the best in her new position in UC San Diego!

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2015 SNO Emerging Investigator

The SNO Emerging Investigator gives recognition to emerging scientists and engineers working in the area of Sustainable Nanotechnology. Given the high quality of the nominations received, this year we made an exception with two winners being presented with the prize, each receiving US$1500.

Environmental Science: Nano is pleased to announce the recipients of this honour are Professors Navid Saleh and John Fortner.

Winners of the SNO 2015 Award

The picture shows Navid Saleh (SNO2015 Winner, University of Texas at Austin), Sarah Ruthven (Executive Editor, Environmental Science: Nano) and John Fortner (SNO2015 Winner, Washington University in Saint Louis)


Dr. Navid Saleh, Assistant Professor, University of Texas at Austin

Navid Saleh

Dr. Saleh’s research focuses on both the environmental applications and implications of nanomaterials. He has recently made a breakthrough by successfully up-converting microwave radiation to ultra-violet energy using novel metal-oxide/nanotube nanohybrids materials. In addition, his group has enumerated the mechanisms of heteroaggregation in fresh and saline water environments under a wide range of environmental conditions. He has also developed nanomaterial characterisation techniques in complex biological fluids that enabled discerning the underlying mechanisms of nanotoxicity.

Besides his outstanding scientific contributions, Dr. Saleh is a model mentor and advocate for students. His research provides an excellent platform for engaging students and stimulating awareness of nanotechnology and related advancements and challenges in the field. Students on many levels are afforded opportunities to engage in nanotechnology research including graduate, undergraduate and high school students. He has developed nanotechnology education programs at the undergraduate level using problem-based pedagogical techniques.

Editor-in-Chief Vicki Grassian says that Professor Saleh was selected “because of his pioneering research contributions and his commitment to educating and engaging students in the field of sustainable nanotechnology.”


Dr. John Fortner, Assistant Professor, Washington University in St. Louis

John FortnerDr. Fortner’s research focuses on a combination of nanomaterial design, synthesis, and applications.  He developed many applications with nanomaterials, including heavy metal sorption, separation and sensing in water, carbon dioxide capture, and photocatalysts for hydrogen production. As an independent investigator, he has received numerous awards including a prestigious US-National Science Foundation CAREER award.

Besides his outstanding scientific contributions, Dr. Fortner is also a leader training the next generation of scientists and engineers in the field of sustainable nanotechnology. As an Assistant Professor, he has mentored nearly 30 undergraduates students. He has also played a substantial role in the professional community as well. For example he served as session organizer at the 2015 Environmental Nanotechnology Gordon Research Conference, at the 2015 Global Congress on NanoEngineering for Medicine and Biology and the 2014 Sustainable Nanotechnology Organization meeting.

Editor-in-Chief Vicki Grassian says that Dr. Fortner was selected because of “his excellence in research in sustainable nanotechnology and his commitment to mentoring students at all levels.”


Many congratulations from the Environmental Science: Nano team!

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2015 SNO Emerging Investigator

The SNO Emerging Investigator designation gives recognition to emerging scientists and engineers working in the area of sustainable nanotechnology.  In recognition of this designation, a certificate and a US$1500 prize will be presented at the 2015 SNO Conference.

Criteria and eligibility include:

  1. Investigators who are within the first 10 years post Ph.D.
  2. An impactful body of independent work and publications in the area of sustainable nanotechnology: environmental, societal, or economic.
  3. Attendance at the 2015 SNO Conference in Portland, Oregon November 8th – 10th 2015 and a high quality paper submission to Environmental Science: Nano within one year after receiving the award.

The nomination consists of a single (1-page max) nomination letter, a second (1-page max) support letter and a 2-page CV (self-nominations are not accepted). The nomination letter should describe how the nominee’s research impacts the field of sustainable nanotechnology.

The support letter should focus on the nominee’s teaching, service and leadership in the field of sustainable nanotechnology. Both the nomination and support letters can be made by SNO members and Environmental Science: Nano Editorial and Advisory  Board members.  Nominations are not restricted to the US or UK.

Letters and CVs are due to Environmental Science: Nano Editor-in-Chief Vicki H. Grassian (vicki-grassian@uiowa.edu) by September 15, 2015.

The selected Emerging Investigator will be honored at the SNO Awards dinner on Sunday November 8, 2015.

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2nd National Environmental Eco-Toxicology Conference

The 2nd National Environmental Eco-Toxicology Conference was held in Xiamen, China, 25th-28th of April, 2015.

This exciting conference was jointly organised by the Research Center for Eco-environmental Sciences of the Chinese Academy of Sciences (CAS), Xiamen University and the Institute of Urban Environment of CAS.

More than 700 attendees shared new ideas and recent development on the are six topics discussed during this conference:

  • Screening and assessment of high risk chemical contaminants
  • Transfer and distribution of chemical contaminants in the environment and organisms
  • Chemical hazards evaluation
  • Toxicology mechanism of chemical ecology
  • Toxicological mechanism of chemical health effects
  • Chemical risk management


During the conference, the Environmental Science (ES) journals sponsored three poster prizes. Let’s introduce the winners!

Environmental Science: Processes & Impacts: ‘Study on the toxicity behavior of organic phosphate ester flame retardant to pattern fish’, by Liwei Sun (Zhejiang Institute of Technology)

Environmental Science: Water Research & Technology: ‘Bioaccumulation behaviour of short chain chlorinated paraffins in Antarctic ecosystem’, by Huijuan Li and Aiqian Zhang (Research Center for Eco-Environmental Sciences)

Environmental Science: Nano: ‘Proinflammatory effects of silver nanoparticles and silver ions on human skin keratinocytes’, by Yang Di, Wei Hong-ying, Wang Bin, Fan Jing-pu, Qin Yu, Liu Yue, Guo Xin-biao and Deng Fu-rong (Peking Universty)

Congratulations to all the winners!

The judges of the prize thought the quality of the posters was really high and, from the Environmental Science team, we would like to thank all the researchers that attended or presented at the conference.

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Halloysite: finally a promising natural nanomaterial?

Halloysite nanotubes (HNT) are products of nature. In chemical composition they are similar to kaolin and can be considered as rolled kaolin sheets with inner diameter of 10-20 nm, outer diameter of 40-70 nm and a length of 500-1500 nm. The internal side of halloysite is composed of Al2O3 while the external is mainly SiO2.

These clay tubes are excavated from mines as stone minerals and processed by milling to form fine power of tubes, which is then used to dope a variety of polymers. The polymer doping has been observed to enhance various properties of these polymers including strength, adhesivity and flame retardancy. In addition, the large surface area and oppositely charged inner and out diameter facilitate loading a variety of biomolecules useful in medical applications. Given this wide range of applications there is an inevitable release of these materials back to the environment in this refined forms.

Despite the many reports on in vitro toxicity of HNTs, there is only limited information available with regard to its in vivo toxicity. Therefore, to shed light on this matter., Professor Fakhrullin and colleagues at Kazan Federal University investigated for the first time the in vivo toxicity of HNT using Caenorhabditis elegans nematode as a model organism. The C. elegans are an important tool in molecular biology because its fully sequenced genome is closely homologous to the human genome.

The findings of this research has shown that the primary pathway of the HNT entry into the organism is the intestinal uptake. The toxic effects of HNT uptake was then investigated by comparing the body size, fertility (or the number of eggs laid in other words) and longevity of the nematodes.

These comparisons did not give statistically significant differences between the controls, which suggests that these are potentially environmentally safe materials to work with. This is in fact is in contrast to the toxicities observed with other nanomaterials such as single walled carbon nanotubes (SWCNTS), graphene oxides, TiO2 nanoparticles and platinum nanoparticles.

Even coating the nematode eggs with the HNT did not result in any significant deviations from the control nematodes. At extremely high doses of HNT did inflict some mechanical stress on the alimentary systems but these levels are highly unlikely to be encountered under environmentally relevant conditions.


To access the full article, download a copy for free* by clicking the link below.

Toxicity of halloysite clay nanotubes in vivo: A Caenorhabditis elegans study
Gölnur I. Fakhrullina, Farida S. Akhatova, Yuri M. Lvov and Rawil F. Fakhrullin
Environ. Sci.: Nano, 2015, 2, 54-59
DOI: 10.1039/C4EN00135D

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About the webwriter

Imali Mudunkotuwa is a Postdoctoral Scholar and Research Assistant at The University of Iowa. She is interested in nanoscience, physical and surface chemistry. You can find more articles by Imali in her author archive .

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*Access is free through a registered RSC account.

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Introducing Advisory Board Member, Omowunmi Sadik

We are delighted to introduce Omowunmi Sadik as an Advisory Board Member for our journal Environmental Science: Nano.

Omowunmi Sadik

Wunmi is a Professor of Chemistry at the State University of New York at Binghamton, Director of the Center for Advanced Sensors & Environmental Systems and President of the Sustainable Nanotechnology Organization.

Professor Sadik received her Ph.D. in Chemistry from the University of Wollongong in Australia and did her postdoctoral research at the US Environmental Protection Agency in Las Vegas, Nevada. She has held appointments at Harvard University, Cornell University and Naval Research Laboratories in Washington, DC.

Sadik’s research currently centers on the interfacial molecular recognition processes, sensors and biomaterials, and immunochemistry with tandem instrumental techniques. Her work utilizes electrochemical and spectroscopic techniques to study human exposure assessment, endocrine disrupters, and toxicity of naturally occurring chemical compounds.

Wunmi’s research:

The driving force behind my biosensor research is the need to build sensor systems that quantitatively measure target species in a complex system.

Omowunmi Sadik, Advisory Board Member, Environmental Science: Nano

Make sure you don’t miss out on the latest journal news by registering your details to receive the regular Environmental Science: Nano e-alerts.

Follow us on Twitter @EnvSciRSC.

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Introducing Advisory Board Member, Ki-Bum Kim

We are delighted to introduce Ki-Bum Kim as an Advisory Board Member for our journal Environmental Science: Nano.

Ki-Bum Kim
Professor Kim is the supervisor of the Nano Fabrication Laboratory in the Department of Materials Science and Engineering at Seoul National University.

Ki-Bum’s exciting research is focused on the fabrication of novel nanoscale materials and devices such as graphene, transparent conducting oxide, nanopore and nanochannel structures for manipulation of ions, biomolecules and DNA.

His team at the Nano Fabrication Laboratory has conducted a broad range of researches on thin film deposition, characterisation, nanoscale fabrication, and evaluation of emerging nanodevices, and they have particular interest in nanofluidic systems.

He has a broad interest on the structure and property relationship in thin film materials. In particular, he has actively worked on the development of metallisation processes for the next generation of Integrated Circuits (ICs), including the development of silicides, diffusion barriers, and interconnecting of materials and processes.

Ki Bum’s laboratory:

We are always open to creative research topics which give a new insight into novel emerging devices and nanoscale phenomena.

Ki-Bum Kim, Advisory Board Member, Environmental Science: Nano

Make sure you don’t miss out on the latest journal news by registering your details to receive the regular Environmental Science: Nano e-alerts.

Follow us on Twitter @EnvSciRSC.

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Quantum dots and a blocking model

Of all nanomaterials that I know and have studied in these past seven years working with environmental nanoscience, Quantum Dots (QDs) have by far been my favorites. They just sound so sci-fi. I mean, just listen to their name: Quantum dots [imagine a low, cinema narrator voice]. Also, they glow in neon multi-colors when exposed to UV light.

This interesting optical property of quantum dots is due to quantum confinement, a phenomenon that takes place when some semiconductor particles are so small that the trajectory of their electrons becomes confined. The level of confinement depends on the size of the particles, which is why QDs of different sizes emit different colors.

QDs present the potential for a wide variety of applications, such as solar cells, lasers, LEDs, medical imaging, and even quantum computing. They are just so cool!

One more thing I have learned in these few years working with environmental nanoscience is that anything with so many potential applications is bound to, somehow, end up in the environment.

Quantum dot dispersions hanging out and emitting their neon quantum confinement glow, no big deal.

A common type of QD is a nanohybrid made of a cadmium selenide (CdSe) core and a zinc sulfide (ZnS) shell (CdSe/ZnS), which has been shown to be toxic to organisms and is a known carcinogen to humans. So, it is important to understand the way in which these QDs will be transported through the environment.

QDs and other nanomaterials are often coated with surfactants or polymers to improve stability—to prevent nanoparticles from sticking to each other, which they love to do. The presence of coatings may deeply affect their interactions with the environment.

M. D. Becker and colleagues recently published a study to improve existing models for the transport of coated QDs through porous media, which is an idealized template for groundwater and soil.

They observed that QDs became increasingly stuck to the porous media as they were transported. Both the coating and the presence of other constituents in the environment (such as natural organic matter) may help QDs “slide” more easily through the porous media. But as these coatings are stripped off over time, particles end up getting stuck.

This behavior could not be explained by traditional nanoparticle transport models, so they developed a new transport model to account for the influence that coatings and other constituents may have in the transport of nanomaterials through porous media.


To access the full article, download a copy for free* by clicking the link below:

A multi-constituent site blocking model for nanoparticle and stabilizing agent transport in porous media
Matthew D. Becker, Yonggang Wang, Kurt D. Pennell and Linda M. Abriola
Environ. Sci
.: Nano, 2015, Advance Article
DOI: 10.1039/C4EN00176A


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About the webwriter

Marina is a PhD research scientist at Virginia Tech and Assoc. Director of @VTSuN. She is interested in air quality, nanotechnology and human health. You can find more information about her in her website mevance.com.

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* Access is free through a registered RSC account

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