Search

Your search keyword '"Karn, Barbara"' showing total 12 results
Start Over Author "Karn, Barbara" Database Complementary Index
12 results on '"Karn, Barbara"'

3. The National Nanotechnology Initiative Approach to Environment, Health, and Safety: A Model for Future Science Investments.

Author

Schottel, Brandi L. and Karn, Barbara

Subjects
NANOTECHNOLOGY, HISTORY
Abstract

The article examines the U.S.' National Nanotechnology Initiative proposed by scientist Mihail Roco and endorsed by President Bill Clinton, dealing with topics including the efforts to incorporate environment, health, and safety procedures at various development stages and nanotechnology's history.

Published
2016

4. Viable methodologies for the synthesis of high-quality nanostructures.

Author

Patete, Jonathan M., PengThese authors contributed equally to this work., Xiaohui, Koenigsmann, Christopher, Xu, Yan, Karn, Barbara, and Wong, Stanislaus S.

Subjects
NANOSTRUCTURED materials, IRRADIATION, ULTRASONICS, SULFIDES, FLUORIDES, METALLIC oxides, SELENIDES, PHOSPHATES
Abstract

The development of environmentally benign methods for the synthesis of nanomaterials has become increasingly relevant as chemists look to shape a more sustainable future. In this critical review, we present current work towards developing alternative methods for synthesizing a wide range of high-quality nanomaterials with predictable and controllable size, shape, composition, morphology and crystallinity. In particular, we focus on the inherent advantages of utilizing porous membrane templates, ultrasonic and microwave irradiation, alternative solvent systems, as well as biologically-inspired reagents as reasonably cost-effective, environmentally responsible methods to generate metal, metal oxide, fluoride, sulfide, selenide and phosphate nanomaterials. [ABSTRACT FROM AUTHOR]

Published
2011
Full Text
View/download PDF

5. Viable methodologies for the synthesis of high-quality nanostructures.

Author

Patete, Jonathan M., Peng, Xiaohui, Koenigsmann, Christopher, Xu, Yan, Karn, Barbara, and Wong, Stanislaus S.

Subjects
CHEMICAL synthesis, NANOSTRUCTURED materials, CHEMISTS, SUSTAINABLE development, CRYSTALLINITY, METALLIC oxides
Abstract

The development of environmentally benign methods for the synthesis of nanomaterials has become increasingly relevant as chemists look to shape a more sustainable future. In this critical review, we present current work towards developing alternative methods for synthesizing a wide range of high-quality nanomaterials with predictable and controllable size, shape, composition, morphology and crystallinity. In particular, we focus on the inherent advantages of utilizing porous membrane templates, ultrasonic and microwave irradiation, alternative solvent systems, as well as biologically-inspired reagents as reasonably cost-effective, environmentally responsible methods to generate metal, metal oxide, fluoride, sulfide, selenide and phosphate nanomaterials. [ABSTRACT FROM AUTHOR]

Published
2011
Full Text
View/download PDF

6. Nanotechnology and in Situ Remediation: A Review of the Benefits and Potential Risks.

Author

Karn, Barbara, Kuiken, Todd, and Otto, Martha

Subjects
NANOTECHNOLOGY, SEMICONDUCTORS, ENVIRONMENTAL remediation, PHOTONICS, BIOTECHNOLOGY
Abstract

Objective: Although industrial sectors involving semiconductors; memory and storage technologies; display, optical, and photonic technologies; energy; biotechnology; and health care produce the most products that contain nanomaterials, nanotechnology is also used as an environmental technology to protect the environment through pollution prevention, treatment, and cleanup. In this review, we focus on environmental cleanup and provide a background and overview of current practice; research findings; societal issues; potential environment, health, and safety implications; and future directions for nanoremediation. We do not present an exhaustive review of chemistry/engineering methods of the technology but rather an introduction and summary of the applications of nanotechnology in remediation. We also discuss nanoscale zero-valent iron in detail. Data sources: We searched the Web of Science for research studies and accessed recent publicly available reports from the U.S. Environmental Protection Agency and other agencies and organizations that addressed the applications and implications associated with nanoremediation techniques. We also conducted personal interviews with practitioners about specific site remediations. Data synthesis: We aggregated information from 45 sites, a representative portion of the total projects under way, to show nanomaterials used, types of pollutants addressed, and organizations responsible for each site. Conclusions: Nanoremediation has the potential not only to reduce the overall costs of cleaning up large-scale contaminated sites but also to reduce cleanup time, eliminate the need for treatment and disposal of contaminated soil, and reduce some contaminant concentrations to near zero-all in situ. Proper evaluation of nanoremediation, particularly full-scale ecosystem-wide studies, needs to be conducted to prevent any potential adverse environmental impacts. [ABSTRACT FROM AUTHOR]

Published
2009
Full Text
View/download PDF

7. The Road to Green Nanotechnology.

Author

Karn, Barbara

Subjects
GREEN products, NANOTECHNOLOGY & the environment, SUSTAINABLE development, NANOSTRUCTURED materials, ENVIRONMENTALISM, PRODUCT life cycle
Abstract

The article considers sustainability issues involved in using green nanotechnology. The U.S. previously addressed environmental, health and safety (EHS) issues associated with using nanotechnology in 2006. The result was the emergence of the concept of green nanotechnology, which attempts to produce nanomaterials and products that do not harm the environment or human health, as well as to produce nanoproducts that provide solutions to environmental challenges. A key aspect to achieving these goals is ensuring sustainability in all stages of the life cycle.

Published
2008
Full Text
View/download PDF

8. Principles for characterizing the potential human health effects from exposure to nanomaterials: elements of a screening strategy.

Author

Oberdörster, Günter, Maynard, Andrew, Donaldson, Ken, Castranova, Vincent, Fitzpatrick, Julie, Ausman, Kevin, Carter, Janet, Karn, Barbara, Kreyling, Wolfgang, Lai, David, Olin, Stephen, Monteiro-Riviere, Nancy, Warheit, David, and Hong Yang

Subjects
RISK assessment, TOXICITY testing, EXPERIMENTAL toxicology, NANOPARTICLES, POROSITY, BIOLOGICAL membranes
Abstract

The rapid proliferation of many different engineered nanomaterials (defined as materials designed and produced to have structural features with at least one dimension of 100 nanometers or less) presents a dilemma to regulators regarding hazard identification. The International Life Sciences Institute Research Foundation/Risk Science Institute convened an expert working group to develop a screening strategy for the hazard identification of engineered nanomaterials. The working group report presents the elements of a screening strategy rather than a detailed testing protocol. Based on an evaluation of the limited data currently available, the report presents a broad data gathering strategy applicable to this early stage in the development of a risk assessment process for nanomaterials. Oral, dermal, inhalation, and injection routes of exposure are included recognizing that, depending on use patterns, exposure to nanomaterials may occur by any of these routes. The three key elements of the toxicity screening strategy are: Physicochemical Characteristics, In Vitro Assays (cellular and non-cellular), and In Vivo Assays. There is a strong likelihood that biological activity of nanoparticles will depend on physicochemical parameters not routinely considered in toxicity screening studies. Physicochemical properties that may be important in understanding the toxic effects of test materials include particle size and size distribution, agglomeration state, shape, crystal structure, chemical composition, surface area, surface chemistry, surface charge, and porosity. In vitro techniques allow specific biological and mechanistic pathways to be isolated and tested under controlled conditions, in ways that are not feasible in in vivo tests. Tests are suggested for portal-of-entry toxicity for lungs, skin, and the mucosal membranes, and target organ toxicity for endothelium, blood, spleen, liver, nervous system, heart, and kidney. Non-cellular assessment of nanoparticle durability, protein interactions, complement activation, and pro-oxidant activity is also considered. Tier 1 in vivo assays are proposed for pulmonary, oral, skin and injection exposures, and Tier 2 evaluations for pulmonary exposures are also proposed. Tier 1 evaluations include markers of inflammation, oxidant stress, and cell proliferation in portal-of-entry and selected remote organs and tissues. Tier 2 evaluations for pulmonary exposures could include deposition, translocation, and toxicokinetics and biopersistence studies; effects of multiple exposures; potential effects on the reproductive system, placenta, and fetus; alternative animal models; and mechanistic studies. [ABSTRACT FROM AUTHOR]

Published
2005
Full Text
View/download PDF

9. Green Nanotechnology: Straddling Promise and Uncertainty.

Author

Karn, Barbara P. and Bergeson, Lynn L.

Subjects
NANOTECHNOLOGY, GREEN technology, INDUSTRIAL revolution, TECHNOLOGICAL innovations, ENVIRONMENTAL protection
Abstract

The article discusses green nanotechnology, which is being considered as the second Industrial Revolution. It explains the reasons why green nanotechnology is capable to serve as an alternative approach to chemicals assessment when applied to nanomaterials. It also outlines some initiatives to further the purpose of green nanotechnology.

Published
2009

10. NANO PARTICLES.

Author

Karn, Barbara and Matthews, H. Scott

Subjects
NANOTECHNOLOGY, POLLUTION, NANOPARTICLES, POLLUTION prevention, HAZARDOUS substances, HAZARDOUS wastes, ENVIRONMENTAL protection, NANOTECHNOLOGY & the environment
Abstract

The article discusses how to clean up the possible threats caused by nanotechnology to the environment. The authors mentioned that nanotechnology was slowly incorporated into mainstream products over the years. A lot of manufactured goods today were said to have some kind of nanotechnology in their composition. Still, it was inferred that there may be possible hazardous effect of using the chemicals and related substances of the technology if not treated properly. The authors also reported that the electronics industry launched an initiative called the Green Nanotechnology pioneered by the Environmental Protection Agency (EPA) and the Woodrow Wilson International Center for Scholars that recommend practices that limit the manufacturing of products containing harmful nanomaterials.

Published
2007
Full Text
View/download PDF

11. Ensuring sustainability with green nanotechnology.

Author

Wong, Stanislaus and Karn, Barbara

Subjects
NANOSTRUCTURED materials industry, TECHNOLOGICAL innovations, PRODUCT quality, NANOTECHNOLOGY, THERAPEUTIC nanotechnology, NANOTECHNOLOGY & the environment, ECONOMICS
Abstract

Nanotechnology offers immense promise for developing new technologies that are more sustainable than current technologies. All major industrial sectors have felt nanotechnology's impact, mainly from the incorporation of nanomaterials into their products. For example, nanotechnology has improved the design and performance of products in areas as diverse as electronics, medicine and medical devices, food and agriculture, cosmetics, chemicals, materials, coatings, energy, as well as many others. Moreover, the revenues from nanotechnology-enabled products are not trivial. For instance, Lux Research maintains that commercial sales in both Europe and the USA will attain revenues of over $1 trillion from nano-enabled products by 2015. The manufacturing of the nanomaterials for these products uses many processes equivalent to chemical manufacturing processes. As a result, manufacturing nanomaterials can produce either harmful pollutants or adverse environmental impacts similar to those from chemical manufacturing. Unlike the chemical industry, however, those same processes are not ingrained in the manufacturing of nanomaterials, and the opportunity exists at the initial design stage to purposely account for and mitigate out potentially harmful environmental impacts. While prevention has not been a priority in current industries, it can become a main concern for the new and future industries that manufacture nanomaterials on a bulk commercial scale. This is where green nanotechnology comes in. Green nanotechnology involves deliberate efforts aimed at developing meaningful and reasonable protocols for generating products and their associated production processes in a benign fashion. The goal is a conscious minimization of risks associated with the products of nanoscience. The green products of nanotechnology are those that are used in either direct or indirect environmental applications. Direct environmental applications provide benefits such as monitoring using nano-enabled sensors, remediation of hazardous waste sites with nanomaterials, or treatment of wastewater and drinking water with nanomaterials. Indirect environmental applications include, for example, the saved energy associated with either lighter nanocomposite materials in transport vehicles or reduced waste from smaller products. The production and process aspects of green nanotechnology involve both making nanomaterials in a more environmentally benign fashion and using nanomaterials to make current chemical processes more environmentally acceptable. Examples of producing nanomaterials in a 'greener manner' could involve but are not limited to the use of supercritical CO2, water, or ionic liquids to replace a volatile organic solvent. Either self-assembly or templating might also be used to eliminate waste in manufacturing. Renewables could be utilized as replacements for either nonrenewable and/or toxic starting materials. Microwave techniques might potentially help to conserve energy, as could both facile thermal and hydrothermal processes. Catalytic and photocatalytic reactions could also increase efficiency and decrease the formation of harmful byproducts. In addition, engineered nanomaterials themselves can be used as catalysts in current chemical processes and as separation membranes to aid in the efficiency of these operations. Furthermore, in order to be truly green, these products and processes must be considered within a lifecycle framework. The papers in this special issue are but a small sampling of the myriad of possibilities that green nanotechnology holds. In the nascent nanotechnology industry, green nanotechnology offers the opportunity to get it right in the first place. It is not too late to take Ben Franklin's words to heart, 'an ounce of prevention is worth a pound of cure'. [ABSTRACT FROM AUTHOR]

Published
2012
Full Text
View/download PDF

Catalog

Books, media, physical & digital resources
See catalog results