Update on Nanofillers in Nanocomposites: From Introduction to Application Akbar K. Haghi and Gennady E. Zaikov A Smithers Group Company Shawbury, Shrewsbury, Shropshire, SY4 4NR, United Kingdom Telephone: +44 (0)1939 250383 Fax: +44 (0)1939 251118 http://www.polymer-books.com First Published in 2013 by Smithers Rapra Technology Ltd Shawbury, Shrewsbury, Shropshire, SY4 4NR, UK © 2013, Smithers Rapra Technology Ltd All rights reserved. Except as permitted under current legislation no partof this publication may be photocopied, reproduced or distributed in anyform or by any means or stored in a database or retrieval system, without the prior permission from the copyright holder. A catalogue record for this book is available from the British Library. Every effort has been made to contact copyright holders of any material reproduced within the text and the authors and publishers apologise if any have been overlooked. ISBN: 978-1-90903-019-0 (hardback) 978-1-90903-020-6 (ebook) Typeset by Integra Software Services Pvt. Ltd. P reface Technical and technological development demands the creation of new materials, which are stronger, more reliable and more durable, i.e., materials with new properties. Up-to-date projects in the creation of new materials tend to use nanotechnology. Nanotechnology can be referred to as a new era in human progress. This is a wide concept, which can affect many other areas: information technologies, medicine, military equipment, robotics and so on. In this book the concept of nanotechnology is quite narrow and is considered with the reference to polymeric materials including composites. The prefix nano means a billionth and is usually referred to as 10-9. It is usually used for prefixing units of time and length. As fantastic as it may sound, scientific research reached the nanolevel a long time ago. Unfortunately, at the moment everything connected with such developments and technologies is impossible to apply to mass production because of the low productivity and high cost, so more research needs to be done on this. That means that nanotechnology and nanomaterials are only accessible in research laboratories for now, but it is only a matter of time before they become mainstream. What sort of benefits and advantages will the manufacturers have after the implementation of nanotechnology and once they start to use nanomaterials? Nanoparticles of any material have very different properties compared to those of micro-or macro-particles. This results from the fact that as well as a reduction of the particles’ sizes of the materials to nanometres, the physical properties of a substance change too. For example, the transition of v Update on Nanofillers in Nanocomposites palladium to nanocrystals leads to an increase in its thermal capacity of more than 1.5 times. It causes the increase of solubility of bismuth in copper to 4000 times and the self-diffusion coefficient of copper at room temperature increases by 21 times. Such changes in the properties of substances are explained by the quantitative change of surface and volume atoms’ ratio of individual particles, i.e., by the high-surface area. Insertion of such nanoparticles into a polymeric matrix of an old and known material gives them new properties and hence, new possibilities for their use. Nanocomposites based on thermoplastic matrix and containing natural, laminated inorganic structures are referred to as laminated nanocomposites. Such materials are based on ceramics and polymers, however, they can be created using natural laminated inorganic structures such as montmorillonite or vermiculite which are present, for example, in clays. A layer of filler ~1 nm thick is saturated with monomer solution and later polymerised. The laminated nanocomposites in comparison with initial polymeric matrix possess much smaller permeability for liquids and gases. These properties mean they can be applied to the medical and food-processing industries. Such materials can be used in the manufacture of pipes and containers for carbonated beverages. These composite materials are eco-friendly, absolutely harmless to humans and possess fire-resistant properties. The derived thermoplastic laboratory samples have been tested and to confirm these statements. It should be noted that the manufacturing technique of thermoplastic materials causes difficulties, notably the dispersion of silicate nanoparticles in the monomer solution. To solve this problem it is necessary to develop a dispersion technique, which could be transferred from laboratory conditions into industrial ones. The advantages the manufacturers can have, if they decide to reorganise their manufacture processes to use such materials, can be predicted even today. As these materials possess more mechanical vi Preface and gas-barrier potential in comparison with the initial thermoplastic materials, then their application in the manufacture of plastic containers or pipes will lead to a saving in the cost of raw materials by being able to reduce the product thickness. On the other hand, the improvement of physical and mechanical properties allows application of nanocomposite products under higher pressures and temperatures. For example, the problem of thermal treatment of plastic containers can be solved. Another example of the application of the valuable properties of laminated nanocomposites concerns the motor industry. As mentioned earlier, another group of materials is the metal containing nanocomposites. Thanks to the ability of metal particles to create the ordered structures (clusters), metal containing nanocomposites can possess a variety of valuable properties. The typical sizes of metal clusters from 1 to 10 nm corresponds to their huge specific surface area. Such nanocomposites demonstrate the property of superparamagnetism and catalytic properties, therefore, they can be used for manufacturing semiconductors, catalysts, optical and luminescent devices, and so on. Such valuable materials can be produced in several ways, for example, by means of chemical or electrochemical reactions to isolate metal particles from solutions. In this case, the major problem is not so much the problem of metal restoration but the preservation of its particles, i.e., the prevention of agglutination and formation of large metal pieces. For example under laboratory conditions metal is deposited in such a way on thin polymeric films capable of catching nano-sized particles. The metal can be evaporated by using high energy and nano-sized particles can be produced, which should then be preserved. Metal can be evaporated while using explosive energy, high-voltage electric discharge or simply high temperatures in special furnaces. The practical application of metal-containing nanocomposites (not giving details about high technologies) can involve the creation of vii Update on Nanofillers in Nanocomposites polymers possessing some valuable properties of metals. For example, a polyethylene plate containing 10% of palladium possesses very similar catalytic properties to a plate made of pure palladium. An example of applying metallic composite is the production of packing materials containing silver and possessing bactericidal properties. Some countries have already been using paints and the polymeric coverings containing silver nanoparticles. Owing to their bactericidal properties, they are applied to public facilities (painting of walls, coating of handrails and so on). The technology of polymeric nanocomposites manufacture is being developed to be simpler and the production processes of composite materials with nanoparticles in their structure are being researched to make them less expensive. However, the nanotechnologies develop at high rates, what seemed impossible yesterday, will be accessible commercially tomorrow. The prospects in the field of polymeric composite materials upgrading are retained by nanotechnologies. Ever-increasing demands manufacturers for new and superior materials stimulates the scientists to find new ways of solving tasks on the nano level. The fast implementation of nanomaterials in mass production, which is highly desirable, depends on the efficiency of cooperation between the scientists and the manufacturers in many respects. Today’s high technology problems in application of nanofillers are successfully solved by close co-operation of the scientific and business worlds. Nanocomposites are polymers containing nanofillers. The microstructure of nanocomposites has inhomogeneities in the nanometer range. Nanocomposite materials cover the range between inorganic glasses and organic polymers. Fillers of polymers have been used for a long time with the goal of enhanced performance of polymers, and especially of rubber. The number of nanofillers has increased over the years, as has the matrix in which they are used and their interactions with traditional viii Preface fillers. Nowadays, the development of polymer nanocomposites is one of the most active areas of development of nanomaterials. The properties imparted by the nanoparticles are various and focus particularly on strengthening the electrical conduction and barrier properties to temperature, gases and liquids as well as the possible improvement of fire behaviour. As a method, which consists of reinforcing polymer chains at the molecular scale in the same way that fibres are used as reinforcement at the macroscopic scale, nanocomposites represent the new generation of two-phased materials, associating a basic matrix to nanofillers inserted between polymer chains. Nanofillers can significantly improve or adjust the different properties of the materials into which they are incorporated. The properties of composite materials can be significantly impacted by the mixture ratio between the organic matrix and the nanofillers. Fillers play important roles in modifying the desirable properties of polymers and reducing the cost of their composites. In conventional polymer composites, many inorganic filers with dimensions in the micrometer range, e.g., calcium carbonate, glass beads and talc have been used extensively to enhance the mechanical properties of polymers. Such properties can indeed be tailored by changing the volume fraction, shape, and size of the filler particles. A further improvement of the mechanical properties can be achieved by using filler materials with a larger aspect ratio such as short glass fibres. It is logical to anticipate that the dispersion of fillers with dimensions in the nanometer level having a very large aspect ratio and stiffness in a polymer matrix could lead to even higher mechanical performances. These fillers include layered silicates and carbon nanotubes. Rigid inorganic nanoparticles with a smaller aspect ratio are also promising as reinforcing and/or toughening materials for the polymers. The dispersion of nanofillers in the polymers is rather poor due to their incompatibility with polymers and large surface-to-volume ratio. Therefore, organic surfactant and compatibiliser additions are needed in order to improve the dispersion of these nanofillers in polymeric matrices. For example, layered silicate surfaces are hydrophilic and proper modification of the clay surfaces through the use of organic surfactants is needed. The product obtained is known as ‘organoclay’. ix Update on Nanofillers in Nanocomposites In this context, organoclays can be readily delaminated into nanoscale platelets by the polymer molecules, leading to the formation of polymer–clay nanocomposites. These nanocomposites belong to an emerging class of organic–inorganic hybrid materials that exhibit improved mechanical properties at very low loading levels compared with conventional microcomposites. The behaviour of polymer–nanofiller composites is directly related to their hierarchical microstructures. Therefore, the mechanical properties of polymer–nanofiller composites are controlled by several microstructural parameters such as properties of the matrix, properties and distribution of the filler as well as interfacial bonding, and by the synthetic or processing methods. The interfaces may affect the effectiveness of load transfer from the polymer matrix to nanofillers. Thus, surface modification of nanofillers is needed to promote better dispersion of fillers and to enhance the interfacial adhesion between the matrix and fillers. Fabrication of homogeneous polymer nanocomposites and advanced computational techniques remains a major scientific challenge for materials scientists. Akbar K. Haghi University of Guilan, Rasht, Iran Gennady E. Zaikov Russian Academy of Sciences, Moscow, Russia 2013 x C ontents Preface ..........................................................................................v 1. Nanofillers and Nanocomposites: A New Outlook ...............1 1.1 Introduction .................................................................1 1.2 Experimental ................................................................5 1.3 Results and Discussion .................................................6 1.4 Concluding Remarks ..................................................33 References ..........................................................................35 2. Rheological Properties of Nanofiller Particles .....................39 2.1 Introduction ...............................................................39 2.2 Experimental ..............................................................41 2.3 Results and Discussion ...............................................42 2.4 Concluding Remarks ..................................................49 References ..........................................................................50 3. Particular filled Nanoclays in a Fibre-formed Matrix .........53 3.1 Introduction ...............................................................53 3.2 Experimental ..............................................................54 3.3 Results and Discussion ...............................................56 3.4 Concluding Remarks ..................................................61 References ..........................................................................62 iii Update on Nanofillers in Nanocomposites 4. Polymer/Organoclay Nanocomposite .................................67 4.1 Introduction ...............................................................67 4.2 Experimental ..............................................................69 4.3 Results and Discussion ...............................................69 4.4 Concluding Remarks ..................................................76 References ..........................................................................77 5. Application of Nanofiller Particles in Cement-based Composites .........................................................................79 5.1 Introduction ...............................................................79 5.2 Experimental ..............................................................80 5.3 Results and Discussion ...............................................83 5.4 Concluding Remarks ..................................................89 References ..........................................................................90 6. Nano-adhesion Effects of Nanofillers .................................95 6.1 Introduction ...............................................................95 6.2 Experimental ..............................................................95 6.3 Concluding Remarks ................................................113 References ........................................................................114 Appendix 1 ..............................................................................117 Appendix 2 ..............................................................................127 Abbreviations ...........................................................................133 Index ........................................................................................139 iv