Mechanochemical Fabrication and Characterization of Novel Low-dimensional Materials

Huitink, David Ryan

2011 August 1900

In this research, for the first time, a novel nanofabrication process is developed to produce graphene-based nanoparticles using mechanochemical principles. Utilizing strain energy at the interface of Si and graphite via the use of a tribometer, a reaction between nanometer sized graphite particles with a reducing agent (hydrazine) was initiated. This simple method demonstrated the synthesis of lamellar platelets (lamellae of ~2nm) with diameters greater than 100 micrometers and thicknesses less than 30 nm directly on the surface of a substrate under rubbing conditions. Spectroscopic evaluation of the particles verified them to be graphene-based platelets, with functionalized molecules including C-N and C-Si bonding. Furthermore, the size of the particles was shown to be highly correlated to the applied pressure at the point of contact, such that three-body friction (with intermediate particles) was shown to enhance the size effect, though with greater variation in size among a single test sample. A chemical rate equation model was developed to help explain the formation of the chemically modified graphene platelets, wherein the pressure applied at the surface can be used to explain the net energy supplied in terms of local flash temperature and strain energy. The activation energy calculated as a result of this method (~42kJ/mol) was found to be extraordinarily close to the difference in bond enthalpies for C-O and the C-N, and C-Si bonds, indicating the input energy required to form the platelets is equivalent to the energy required to replace one chemical bond with another, which follows nicely with the laws of thermodynamics. The ability to produce graphene-based materials using a tribochemical approach is a simple, one-step process that does not necessarily require specialized equipment. This development could potentially be translated into a direct-write nanopatterning procedure for graphene-based technologies, which promise to make electronics faster, cheaper and more reliable. The tribochemical model proposed provides insight into nanomanufacturing using a tribochemical approach, and suggests that further progress can be accomplished through the reduction of the activation energy required for graphene formation.

mechanochemistry

graphene

tribochemistry

nanoparticle synthesis

PHYTOTOXICITY OF SILVER NANOPARTICLES TO ARABIDOPSIS THALIANA IN HYDROPONIC AND SOIL SYSTEMS

Wang, Qiang

01 May 2011

With the recent development of nanotechnology, there has been increased production of engineered nanomaterials but limited containment strategies, resulting in inevitable release of a large amount of engineered nanoparticles (ENPs) in the environment. Many ENPs have potential adverse impacts on the environment, and one of the most commonly used ENPs, silver nanoparticle (AgNP), has attracted increased global concern. The current study focused on phytotoxicity of AgNPs to a model plant, Arabidopsis thaliana. Silver nanoparticles were introduced into the growth medium for the wild type A. thaliana plants and root uptake and translocation of AgNPs were examined in hydroponic growth condition. We also conducted growth stage based phenotypic analysis by growing A. thaliana throughout its life cycle in soil. The result indicated that: (1) wild type seeds germination was not affected by either AgNPs or their dissolved Ag+ ions; (2) AgNPs exposure resulted in a concentration- and size- dependent inhibition effect to the root elongation; (3) confocal and electron microscopy indicated that AgNPs could be taken up by seedling roots, yet most of AgNPs attached to the surface of seedling root cap; (4) AgNPs and their dissolved Ag+ ions at tested concentrations had little influence on the vegetative growth of A. thaliana, but they accelerated the floral development; and (5) the effect on the floral development stage reduced the quality of second-generation (F1) seeds, as indicated by their lower germination rate. In conclusion, AgNPs displayed both acute and chronic phytotoxicity to A. thaliana.

Arabidopsis thaliana

phytotoxicity

silver nanoparticle

Silver Nanocomposite Material as Antibacterial Coating on Indwelling Medical Devices-Based Biomaterials

Khatoon, Zohra

12 December 2018

The most common type of adverse events in healthcare in Canada reported by the Canadian Institute for Health Information (CIHI) are nosocomial infections. Amongst nosocomial infections, implant associated infections have been reported to be most common. Despite having the implantation surgeries carefully performed, a small, but still considerable number of devices gets colonized by bacteria resulting in implant associated infections and/or surgical site infections. The patients are then started on high dose antibiotics, which if ineffective, is followed by reimplantation surgeries that leads to long hospital stays and detrimental effects in their lives. Due to this, an alternative to antibiotics is required which could prevent and/or treat bacterial colonization on implants. The main objective of this thesis was to demonstrate the effectiveness of an antimicrobial based CLKRS peptide capped silver nanoparticle coating on a metallic and polymeric based biomaterial used in various implantable medical devices. The CLKRS peptide capped silver nanoparticle formulation was specifically engineered and tested for its antibacterial and antibiofilm properties. Silver nanoparticles were synthesised by photochemical reduction of silver ions upon photocleavage of the photoinitiator I-2959. The metal nanostructure surfaces were protected with the CLKRS peptide and tested on planktonic and biofilms of P. aeruginosa, S. aureus and S. epidermidis. The bacterial quantification was done by survival colony counting. The cytotoxicity of the silver nanoparticle formulation was also tested on human dermal fibroblast, mouse bone marrow derived macrophages, and human epithelial cells by cell proliferation assay. Results show the formation of a nanometric layer of nanosilver on the surface of the material inhibiting the growth of bacteria and eradicating pre-existing biofilms with no significant cell toxicity suggesting the prepared formulation could be a useful tool in preventing and controlling infections on implants during surgery and post implantation. This technology thus could serve as an alternative therapy for surgical site infections and/or implant associated infections.

Infection

Implants

Silver nanoparticle

Biomaterial

Functionalization of Organic-Inorganic Nano-Hybrids Utilizing Inorganic Nanoparticles / 無機ナノ粒子を利用した有機無機ナノハイブリッドの機能化

Otsuka, Takeshi

24 September 2010

Kyoto University (京都大学) / 0048 / 新制・課程博士 / 博士(工学) / 甲第15674号 / 工博第3332号 / 新制||工||1503(附属図書館) / 28211 / 京都大学大学院工学研究科高分子化学専攻 / (主査)教授 中條 善樹, 教授 澤本 光男, 教授 赤木 和夫 / 学位規則第4条第1項該当

Nanoparticle

Polymer

Hybrid

Functionalization

500

Controlled assembly of metal nanostructures and their application to sensitive molecular sensing / 金属ナノ構造の集積制御とその高感度分子センシングへの応用

Matsuoka, Tomoyo

25 March 2013

Kyoto University (京都大学) / 0048 / 新制・課程博士 / 博士(工学) / 甲第17583号 / 工博第3742号 / 新制||工||1570(附属図書館) / 30349 / 京都大学大学院工学研究科材料化学専攻 / (主査)教授 平尾 一之, 教授 田中 勝久, 教授 三浦 清貴 / 学位規則第4条第1項該当

Gold nanoparticle

patterning

SERS

500

Electrochemical investigation of platinum nanoparticles supported on carbon nanotubes as cathode electrocatalysts for direct methanol fuel cell

Ntlauzana, Asanda

January 2010

Magister Scientiae - MSc / The particles of the Pt metal were well dispersed on carbon nanotubes when EG was used and in isopropanol poor dispersion was observed and no further investigation was done on them. The platinum wt% on the supports observed from EDS was 21.8, 19.10 and 16.74wt% for Pt/EMWCNT, Pt/LPGCNT and Pt/ commercial CNT respectively. Pt/LPGMWCNT showed high electro-catalytic activity of 2.48 mA and active surface area of 76 m2/g, toward oxygen reduction, observed from cyclic voltammogram in iv sulfuric acid. Pt/LPGMWCNT also showed better tolerance toward methanol, however it was not highly active towards methanol, and hence the methanol oxidation peak current observed between 0.75 and 08 potential was the smallest. In this study a wide range of instruments was used to characterize the properties and behavior of Platinum nanoparticles on multi-wall carbon nanotubes. To add to the already mentioned, Scanning electrochemical microscopy (SEM), proton induced x-ray emission (PIXE), scanning electrochemical microscopy (SECM) and Brunauer-Emmett Tellar (BET) were also used. / South Africa

Electrochemistry

Electrochemical

Electrocatalysts

Platinum

Nanoparticle

The impact of nanoparticle surface chemistry on biological systems

Thorn, Angie Sue (Morris)

01 May 2017

The unique properties of nanomaterials, such as their small size and large surface area-to-volume ratios, have attracted tremendous interest in the scientific community over the last few decades. Thus, the synthesis and characterization of many different types of nanoparticles has been well defined and reported on in the literature. Current research efforts have redirected from the basic study of nanomaterial synthesis and their properties to more application-based studies where the development of functionally active materials is necessary. Today such nanoparticle-based systems exist for a range of biomedical applications including imaging, drug delivery and sensors. The inherent properties of the nanomaterial, although important, aren’t always ideal for specific applications. In order to optimize nanoparticles for biomedical applications it is often desirable to tune their surface properties. Researchers have shown that these surface properties (such as charge, hydrophobicity, or reactivity) play a direct role in the interactions between nanoparticles and biological systems can be altered by attaching molecules to the surface of nanoparticles. In this work, the effects of physicochemical properties of a wide variety of nanoparticles was investigated using in vitro and in vivo models. For example, copper oxide (CuO) nanoparticles were of interest due to their instability in biological media. These nanoparticles undergo dissolution when in an aqueous environment and tend to aggregate. Therefore, the cytotoxicity of two sizes of CuO NPs was evaluated in cultured cells to develop a better understanding of how these propertied effect toxicity outcomes in biological systems. From these studies, it was determined that CuO NPs are cytotoxic to lung cells in a size-dependent manner and that dissolved copper ions contribute to the cytotoxicity however it is not solely responsible for cell death. Moreover, silica nanoparticles are one of the most commonly used nanomaterials because they are easy to synthesize and their properties (such as size, porosity and surface chemistry) can be fine-tuned. Silica nanoparticles can be found in thousands of commercially available products such as toothpastes, cosmetics and detergents and are currently being developed for biomedical applications such as drug delivery and biomedical imaging. Our findings herein indicate that the surface chemistry of silica nanoparticles can have an effect on lung inflammation after exposure. Specifically, amine-modified silica NPs are considered to be less toxic compared to bare silica nanoparticles. Together, these studies provide insight into the role that material properties have on toxicity and allow for a better understanding of their impact on human and environmental health. The final aim of this thesis was to develop surface-modified nanoparticles for drug delivery applications. For this, biodegradable, polymeric NPs were used due to their inert nature and biocompatibility. Furthermore, polymeric NPs are excellent for loading drugs and using them as drug delivery vehicles. In this work, poly (lactic-co-glycolic acid) (PLGA) NPs were loaded with a therapeutic peptide. These NPs were then coated with chitosan (a mucoadhesive polymer) for the treatment of allergic asthma or coated with a small cationic mitochondrial targeting agent for the treatment of ischemia/reperfusion injury. Taken as a whole, this thesis sheds light on the impact of NPs on human health. First by providing useful toxological data for CuO and silica NPs as well as highlighting the potential of surface-modified polymeric NPs to be used in drug delivery-based applications.

Cell Culture

Nanoparticle

Toxicity

Chemistry

Transport, Stability, and Deposition of Gold Nanoparticles in Porous Media

Chan, Matthew Yunho

07 December 2011

Gold-nanoparticle (AuNP) transport in groundwater is heavily influenced by the intrinsic properties of the nanoparticles and the external parameters of the environment. Batch experimental data indicated that 15 nm AuNP coated by bovine serum albumin (BSA-AuNP) was more stable at high ionic strength compared to citrate-coated AuNP (cit-AuNP) of similar size. It was expected that the stability of these AuNP would be replicated in column studies. Column experiments with varying monovalent and divalent ion concentrations using both types of AuNP yielded breakthrough curves that both adhere and deviate from this hypothesis. BSA-AuNP was found to be more stable relative to cit-AuNP during porous media flow in the presence of increasing concentrations of CaCl2, but the opposite occurred with increasing NaCl concentration. Colloidal filtration theory (CFT) fails to predict and explain this discrepancy. DLVO calculations suggested pore-space destabilization occurred in these experiments that were not accounted by CFT. / Master of Science

Environment

Groundwater

Gold

Nanoparticle

Engineering

Dependency of Aluminum Nanoparticle Flash Ignition on Sample Internal Water Content and Aggregation

Stenger, Dillon Michael

January 2016

No description available.

Aerospace Engineering

Engineering

Nanoscience

Aluminum Nanoparticle Flash Ignition

Nanoparticle Aggregation

Nanoparticle Internal Water Content

Alternate Engine Ignition System

The virucidal properties of silver ion-exchange resins and metal-based nanoparticles and their potential use in water purification

Scott, Greg Michael

January 1900

Master of Science / Department of Biology / Peter P. Wong / Contamination of water with various disease causing agents such as bacteria and viruses leads to 4 billion cases of diarrheal disease and 1.8 million deaths per year worldwide. The World Health Organization estimates that 94% of these cases can be prevented by increasing the availability of clean and safe water to those at risk. They also claim that 1.1 billion individuals worldwide do not have access to clean water sources, and suggest the best way to improve this situation is to increase household water treatment and safe storage (HWTS). HWTS can dramatically improve water quality, leading to a significant reduction in diarrheal disease. Being able to produce a small and inexpensive device that can be used in a household to improve water quality will significantly aid in preventing diarrheal disease. Water purification systems have been manufactured in the past in order to turn potentially disease causing water into safe drinking water. The metal iodine has been used in some of these systems. However, iodine is known to leach off and become part of the drinking water, which can lead to non-infectious diseases such as hyperthyroidism. This project shows how the development of new water purification systems utilizing silver and other heavy metal nanoparticles may be used to help purify water and have the potential to prevent diarrheal disease. Various heavy metals, including silver nitrate, magnesium oxide, brominated magnesium oxide and titanium-silicon-manganese dioxide nanoparticles, are used in conjunction with ion-exchange resins to develop a biocidal column to sanitize water. A model virus from each of the following families is used: Reoviridae (rotavirus), Picornaviridae (enterovirus), and Caliciviridae (calicivirus). This research shows not only that some of these metals can be used to purify water by inactivating viruses, but also shows the mechanism of viral inactivation. This includes protein denaturation and destruction of viral RNA.

virus

silver

nanoparticle

water

Biology, Microbiology (0410)