DOCSLIB.ORG

The 12Th Pacific Rim Conference On

Total Page:16

File Type:pdf, Size:1020Kb

Download full-text PDF Read full-text
The 12Th Pacific Rim Conference On Hilton Waikoloa Village | Waikoloa, Hawaii, USA rld of Scie o nc Scan for meeting app. W e A CONFERENCE PROGRAM PACRIM a nd gy Technolo The 12th Pacific Rim Conference on Ceramic and Glass Technology including – Glass & Optical Materials Division Annual Meeting (GOMD 2017) May 21 – 26, 2017 PACRIM Partner Societies: The American Ceramic Society The Australian Ceramic Society The Ceramic Society of Japan The Chinese Ceramic Society ceramics.org/pacrim12 The Korean Ceramic Society Join Wiley and The American Ceramic Society at the 12th Pacific Rim Conference Including the Glass & Optical Materials Division Meeting JACerS Throughout 2017, we are celebrating the 100th anniversary of Celebrating the Journal of the American Ceramic Society. The most 100 Years of highly-respected global source for scholarly articles on ceramic Excellence materials research is enjoying its Centennial year and you can in 2017! JACerS: 1918–2017... learn all about it at wileyonlinelibrary.com/jacers100. and beyond This year at PACRIM/GOMD, take advantage of all these great offerings, plus more: • “So You Want to Get Published: A workshop for graduate students and young professionals” - led by Bill Fahrenholtz, Editor-in-Chief, Journal of the American Ceramic Society. - Monday, May 22, 2017, noon to 1:15 pm • Special Centennial Issue of JACerS available with unique articles and features picked by the editors • FREE sample copies of all 3 journals of the American Ceramic Society • Enjoy a 35% discount on all purchases at the Wiley booth • Meet with Wiley and ACerS journal editors to discuss the benefits of publishing with us • Sign up for special alerts on all that is new in Materials Science and Ceramics Visit wileyonlinelibrary.com/jacers100 for all Centennial features You can join or renew your ACerS 276812 membership at www.ceramics.org Wiley/ACerS Online Bookstore at wiley.com/go/ceramics rld of Scie o nc W e A WELCOME PACRIM a nd gy Technolo It is my honor to welcome you to the 12th Pacific Rim Conference on Ceramic and Glass Technology (PACRIM 12)! The Pacific Rim Conference on Ceramic and Glass Technology is a bi-an- nual conference held in collaboration with the ceramic societies of the Pacific Rim countries - The American Ceramic Society, The Ceramic Society of Japan, The Chinese Ceramic Society, The Korean Ceramic Society, and the Australian Ceramic Society. The 1st PACRIM conference was hosted by The American Ceramic Society (ACerS) at Honululu, Hawaii, in 1993. After almost 25 years, it is befitting to return to another Hawaian Island for the 12th PacRim conference. The comprehensive PACRIM 12 technical program covers a variety of topics that identify global challenges and opportunities for various ceramic technologies and is sure to foster discussions on the future of specific areas of ceramics science and engineering. The conference will also provide an excellent forum for interactions and friendships with participants from various continents. I highly encourage you to join your colleagues for the Plenary Session on Monday morning. The key note talks feature Mike Murray, Morgan Advanced Materials, Donald Hillebrand, Argonne National Laboratory, Gisele Maxwell, Shasta Crystals Inc., and Zhengyi Fu, Wuhan University of Technology. The talks will center around the theme of materials and manufacturing technologies for sustainable development. PACRIM 12 also includes the important topics covered in the Glass and Optical Materials Division (GOMD) Annual Meeting, including five award lectures and a student poster competition. Please refer to the GOMD section of this program for all the details. Finally, we appreciate the support of our sponsors for their generosity. Please refer to this pro- gram for the full list of sponsors. Organizing Chair: We sincerely hope you take advantage of all the opportunities PACRIM12 offers and that you enjoy your time on the beautiful Big Island of Hawaii. Dileep Singh, Argonne National Laboratory P.S. Please be reminded that no photography, audio recording, or videotaping of presenters in oral sessions is permitted. See policy on pg iv. The 12th Pacific Rim Conference on Ceramic and Glass Technology i rld of Scie o nc W e A TABLE of PACRIM CONTENTS a nd gy Technolo PACRIM Sponsors . iii Regulations ........................................................................... iv Special Events ......................................................................... v Floorplan . vi Schedule at a glance . vii Plenary speakers . viii Sessions by symposia/symposia list .................................................. ix – xvii GOMD Annual Meeting Welcome and special events . xviii Award lectures ....................................................................... xx Sessions by symposia/symposia list ................................................ xxi – xxiv Combined Final Program by Day Presenter listing ................................................................... 2 – 12 Monday morning ...................................................................... 12 Monday afternoon ................................................................ 12 – 24 Tuesday morning . 24 – 32 Tuesday afternoon ................................................................ 32 – 43 Poster sessions ................................................................... 44 – 53 Wednesday morning . 53 – 62 Wednesday afternoon ............................................................. 62 – 73 Thursday morning . 74 – 83 Thursday afternoon ............................................................... 83 – 93 Friday morning ................................................................... 93 – 99 SOCIETY PARTNERS Ceramic Society of Japan ii The 12th Pacific Rim Conference on Ceramic and Glass Technology SPONSORS Special thanks to our sponsors for their generosity Platinum Sponsor Gold Sponsor Silver Sponsors Additional Sponsors The 12th Pacific Rim Conference on Ceramic and Glass Technology iii rld of Scie o nc W e A MEETING REGULATIONS PACRIM a nd gy Technolo No photography/recording Cell phones silent During oral sessions conducted during Society meetings, unauthorized photography, videotaping, and audio recording is strictly prohibited for two reasons: (1) conference presentations are the intellectual property of the presenting authors and as such are protected, and (2) engaging in photography, videotaping, or audio recording is disruptive to the presenter and the audience. Failure to comply may result in the removal of the offender from the session or from the remainder of the meeting. Note: The Society may engage photographers to photograph sessions for marketing and promotional purposes. MEETING REGULATIONS The American Ceramic Society is a nonprofit scientific organization that facilitates website. By participating in the conference, you grant The American Ceramic Society the exchange of knowledge meetings and publication of papers for future reference. the right to use your name and photograph for such purposes. All postings become The Society owns and retains full right to control its publications and its meetings. the property of The American Ceramic Society. The Society has an obligation to protect its members and meetings from intrusion by others who may wish to use the meetings for their own private promotion purpose. During oral sessions conducted during Society meetings, unauthorized Literature found not to be in agreement with the Society’s goals, in competition with photography, videotaping and audio recording is prohibited. Failure to comply Society services or of an offensive nature will not be displayed anywhere in the vicinity may result in the removal of the offender from the session or from the remainder of of the meeting. Promotional literature of any kind may not be displayed without the the meeting. Society’s permission and unless the Society provides tables for this purpose. Literature not conforming to this policy or displayed in other than designated areas will be Registration Requirements: Attendance at any meeting of the Society shall be disposed. The Society will not permit unauthorized scheduling of activities during limited to duly registered persons. its meeting by any person or group when those activities are conducted at its meeting Disclaimer: Statements of fact and opinion are the responsibility of the authors place in interference with its programs and scheduled activities. The Society does not alone and do not imply an opinion on the part of the officers, staff or members of The object to appropriate activities by others during its meetings if it is consulted with American Ceramic Society. The American Ceramic Society assumes no responsibility regard to time, place, and suitability. Any person or group wishing to conduct any for the statements and opinions advanced by the contributors to its publications or activity at the time and location of the Society meeting must obtain permission from by the speakers at its programs; nor does The American Ceramic Society assume the Executive Director or Director of Meetings, giving full details regarding desired any liability for losses or injuries suffered by attendees at its meetings. Registered time, place and nature of activity. names and trademarks, etc. used in its publications, even without specific indications Diversity Statement: The American Ceramic Society values diverse and inclusive thereof, are not to be considered unprotected by the law. Mention of trade names of participation within the field of ceramic science and engineering.
Load more

Recommended publications
  • Preparation and Characterization of Magnetic Hollow Glass Microspheres by Electroless Plating
    id4520328 pdfMachine by Broadgun Software - a great PDF writer! - a great PDF creator! - http://www.pdfmachine.com http://www.broadgun.com March 2010 ISSN : 0974 - 7486 Volume 6 Issue 1 An Indian Journal Trade Science Inc. MMaatteerriiaallss SScciieennccee Full Paper MSAIJ, 6(1), 2010 [47-51] Preparation and characterization of magnetic hollow glass microspheres by electroless plating Wen-Bin Yang*, Xiao-Hong Tang, Xiao-Ping Hu, Chao Wang, Yuan-Lin Zhou School of Materials Science and Engineering, Southwest University of Science and Technology, Mianyang 621010, (P. R. CHINA) E-mail : [email protected] Received: 7th January, 2010 ; Accepted: 17th January, 2010 ABSTRACT KEYWORDS Magnetic hollow glass microspheres (HGM) were prepared by electroless Hollow glass microsphere; plating technique. Morphology, composition, structure, infrared radiation Electroless plating; and magnetic property of hollow glass microspheres before and after plat- Magnetic; ing were characterized by SEM, EDS, XPS, XRD, IR and VSM, respectively. Preparation; ìm The results showed that Ni-P plating, composed of particles of 1~2 Characterization. diameters, was uniformly coated on surfaces of HGM. Because of the exist- ence of Ni-P plating, peak intensity of the plated HGM in IR and XRD were lower than those before. Since the plated HGM own anti-infrared radiation and magnetic property, they are useful in some special areas. 2010 Trade Science Inc. - INDIA INTRODUCTION ing[8-12]. Due to spheric shape and low density of HGMs, it is very difficult to deposit a continuous and uniform Hollow glass microsphere (HGM) is a kind of ma- coating on the surface of HGMs. terial with many advantages, such as low density, huge Electroless plating owns many advantages, such as surface area, excellent thermal resistance, high wearing low cost, easy formation of continuous and uniform resistance and fine fluidity, so it has been widely used in coating on surface of substrate with complex shape, plastic, rubber, paint and coating systems[1-4].
    [Show full text]
  • Chemical Analysis of Extracting Transition Metal Oxides from Polymetallic Ore by Sulphate Process
    EPJ Web of Conferences 140, 13004 (2017) DOI: 10.1051/ epjconf/201714013004 Powders & Grains 2017 Chemical analysis of extracting transition metal oxides from polymetallic ore by sulphate process Otgon-Uul Enkh-Uyanga1, Baatar Munkhtsetseg 1*, Urtnasan Urangoo2, Enkhtur Tserendulam1 and Davaadorj Agiimaa1 1 Chemistry Department, Ulaanbaatar State University, 13343, U1aanbaatar , Mongolia 2 Charles Sturt University, Canberra 2602 ACT, Australia Abstract. In this research work we attempt to improve the purity of polymetallic ores in Mongolia whilst developing practical applications of its refinement processes and this paper presents the results of chemical research of extracting transition metal titanium oxides, ferrous oxide and rare earth oxides from polymetallic ore. Thereby, chemical and mineral analysis of polymetallic ore is carried out basis of responses to the support process at various degrees of water whereas transition metal sulphates solubility differ. As a result of sulphate and resulphurization process we have extracted anatase with 62.5 percent titanium dioxide and brookite mineral with 89.6 percent of titanium dioxide as well as mineral with 83.8 percent of ferrous oxide hematite and rare earth oxides with 57.6 percent of cerium oxide. These oxides are identified under various conditions in the thermal processing. The morphology structure and chemical content compound of the mineral has been verified as a result of the XRF, XRD, SEM-EDX analysis. Keywords: polymetallic ore, anatase, brookite, hematite, rare earth oxides Introduction: Mongolia is a country rich in process at various degrees of water whereas transition polymetallic ores. There is an increased demand for metal sulphates solubility differ. research of the processing polymetallic ores by removing There are certain solutes, which have independently fair impurities and forming refined minerals as transition degree of solubility to temperature change.
    [Show full text]
  • Beads from the Hudson's Bay Company's Principal Depot, York Factory, Manitoba, Canada
    BEADS: Journal of the Society of Bead Researchers Volume 25 Volume 25 (2013) Article 6 1-1-2013 Beads from the Hudson's Bay Company's Principal Depot, York Factory, Manitoba, Canada Karlis Karklins Gary F. Adams Follow this and additional works at: https://surface.syr.edu/beads Part of the Archaeological Anthropology Commons, History of Art, Architecture, and Archaeology Commons, Science and Technology Studies Commons, and the Social and Cultural Anthropology Commons Repository Citation Karklins, Karlis and Adams, Gary F. (2013). "Beads from the Hudson's Bay Company's Principal Depot, York Factory, Manitoba, Canada." BEADS: Journal of the Society of Bead Researchers 25: 72-100. Available at: https://surface.syr.edu/beads/vol25/iss1/6 This Article is brought to you for free and open access by SURFACE. It has been accepted for inclusion in BEADS: Journal of the Society of Bead Researchers by an authorized editor of SURFACE. For more information, please contact [email protected]. BEADS FROM THE HUDSON’S BAY COMPANY’S PRINCIPAL DEPOT, YORK FACTORY, MANITOBA, CANADA Karlis Karklins and Gary F. Adams There is no other North American fur trade establishment whose half a dozen times in two separate international conflicts. longevity and historical significance can rival that of York Factory. It witnessed a naval engagement and suffered three direct Located in northern Manitoba, Canada, at the base of Hudson Bay, attacks. The factory was rebuilt seven times and was the it was the Hudson’s Bay Company’s principal Bay-side trading base of operations for such fur trade personalities as Pierre post and depot for over 250 years.
    [Show full text]
  • Hollow Polymer Microcapsule Embedded Transparent and Heat-Insulating film† Cite This: RSC Adv.,2018,8, 9480 Chae Bin Kim, Nam-Ho You and Munju Goh *
    RSC Advances View Article Online PAPER View Journal | View Issue Hollow polymer microcapsule embedded transparent and heat-insulating film† Cite this: RSC Adv.,2018,8, 9480 Chae Bin Kim, Nam-Ho You and Munju Goh * We herein report a facile and scalable approach to manufacturing optically transparent and heat-insulating films by incorporating hollow poly(methyl methacrylate) microcapsules into a transparent polymeric matrix. The microcapsule was prepared via emulsion polymerization. The size of the microcapsules could be easily controlled from 1to3mm by varying the polymerization time in a narrow size distribution. The microcapsules were then mixed with a UV-curable transparent liquid resin and cured by a subsequent light irradiation. The current approach could enhance the thermal barrier property of the films without a significant reduction in the optical transparency. The solid film possessing 30 wt% microcapsules, for Received 26th January 2018 example, exhibited a high visible light transmittance (80% as measured by UV-vis spectroscopy) and the Accepted 27th February 2018 thermal conductivity was reduced to 0.06 W mKÀ1, corresponding to 46% of the capsule free film. To DOI: 10.1039/c8ra00801a quantify and verify this result, theoretical models describing a heat transfer in a hollow microsphere Creative Commons Attribution 3.0 Unported Licence. rsc.li/rsc-advances composite were used, and the model showed a good agreement with our experimental observations. 1. Introduction process ow including adjustment of the gas mixture securely is somewhat complicated and uneconomical.5 Also, the glazed To safely accommodate global increases in population and per windows may form cracks due to a thermal stress during the capita energy consumption, a signicant need for immediate usage.
    [Show full text]
  • Glass Microspheres for Hydrogen Storage
    Glass Microspheres for Hydrogen Storage James Shelby and Matthew Hall Alfred University Wed, May 25 Project ID # This presentation does not contain any proprietary or confidential information STP47 HOLLOW GLASS MICROSPHERES The concept of using hollow glass microspheres (HGM) as a hydrogen storage medium has been known for some time. Hydrogen diffuses through the thin wall of the HGM at elevated temperatures and pressures. The gas is then trapped upon cooling to room temperature. The ability of HGM to safely store compressed hydrogen gas is a major HYDROGEN-FILLED HOLLOW advantage. However, a traditional GLASS MICROSPHERE limitation of HGM has been the poor thermal conductivity of a packed bed of HGM; poor conduction of heat translates to unsuitably low release rates of hydrogen gas. 2 HOLLOW GLASS MICROSPHERES Previous work by Rapp and Shelby demonstrated that the release rate of hydrogen from a monolithic glass plate could be greatly accelerated by the radiation emitted from an infrared lamp. In order to effect this “photo-enhanced” outgassing, the glass was doped with an optically active element; in this case, 0.5 wt% Fe3O4 was used 3 OVERVIEW Timeline Barriers • Estimated start date: • Barriers addressed: May 2005 – Cost: HGM are currently made in tonnage quantities from low- cost raw materials Budget – Weight and volume: HGM are an ideal storage medium from • Total project funding the standpoint of weight – Durability: Provided that the for FY 05 glass membrane is not broken, HGM may be indefinitely used – AU: $50k for hydrogen storage
    [Show full text]
  • Crystallization Kinetics of Chalcogenide Glasses
    2 Crystallization Kinetics of Chalcogenide Glasses Abhay Kumar Singh Department of Physics, Banaras Hindu University, Varanasi, India 1. Introduction 1.1 Background of chalcogenides Chalcogenide glasses are disordered non crystalline materials which have pronounced tendency their atoms to link together to form link chain. Chalcogenide glasses can be obtained by mixing the chalcogen elements, viz, S, Se and Te with elements of the periodic table such as Ga, In, Si, Ge, Sn, As, Sb and Bi, Ag, Cd, Zn etc. In these glasses, short-range inter-atomic forces are predominantly covalent: strong in magnitude and highly directional, whereas weak van der Waals' forces contribute significantly to the medium-range order. The atomic bonding structure is, in general more rigid than that of organic polymers and more flexible than that of oxide glasses. Accordingly, the glass-transition temperatures and elastic properties lay in between those of these materials. Some metallic element containing chalcogenide glasses behave as (super) ionic conductors. These glasses also behave as semiconductors or, more strictly, they are a kind of amorphous semi-conductors with band gap energies of 1±3eV (Fritzsche, 1971). Commonly, chalcogenide glasses have much lower mechanical strength and thermal stability as compared to existing oxide glasses, but they have higher thermal expansion, refractive index, larger range of infrared transparency and higher order of optical non-linearity. It is difficult to define with accuracy when mankind first fabricated its own glass but sources demonstrate that it discovered 10,000 years back in time. It is also difficult to point in time, when the field of chalcogenide glasses started.
    [Show full text]
  • Semester –I Chapter 4: Redox Titrations
    Semester –I Chapter 4: Redox Titrations SHREE H. N. SHUKLA INSTITUTE OF PHARMACEUTICAL EDUCATION AND RESEARCH B.PHRAM (SEMESTER –I) SUBJECT NAME: PHARMACEUTICAL ANALYSIS -I SUBJECT CODE: BP102TP CHAPTER 4: REDOX TITRATIONS H.N. Shukla Institute of Pharmaceutical Education and Research Page 1 Semester –I Chapter 4: Redox Titrations Content Redox titrations: (a) Concepts of oxidation and reduction (b) Types of redox titrations (Principles and applications) Cerimetry, Iodimetry, Iodometry, Bromatometry, Dichrometry, Titration with potassium iodate INTRODUCTION Concept of oxidation and reduction As discussed before, in titrimetric analysis we can find out the quantity of pure component based on measurement of volume of standard solution that reacts completely with the analyte. This measurement of standard solution can be possible in different reactions, and if the reaction involved in this measurement is oxidation-reduction reaction, that method is called ns "oxidation reduction titration" or "Redox titration. In Redox titration oxidation & Reduction reaction occurs simultaneously. Oxidation Combination of the substance with oxygen is termed as oxidation. C (s) + O2 (g) CO2 (g) Removal of Hydrogen H2S + O S + H2O Loss of electron(s) is known as oxidation. By loosing electron positive valency of element increases and negative valency of element decreases. Fe2+ Fe3+ + e- Increase in oxidation number Reduction Removal of Oxygen from substance CuO + 2H Cu + H2O Additon of Hydrogen C2H2 + 2H C2H4 Gain of electron, by taking on electron positive valency is decreased and negative valency is increased. Fe3+ + e- Fe2+ Decrease in Oxidation number. H.N. Shukla Institute of Pharmaceutical Education and Research Page 2 Semester –I Chapter 4: Redox Titrations Oxidation-Reduction Reaction Oxidation-reduction reactions are the chemical processes in which a change in the valency of reacting elements or ions takes place.
    [Show full text]
  • Nanopatterning with Photonic Nanojets: Review and Perspectives in Biomedical Research
    micromachines Review Nanopatterning with Photonic Nanojets: Review and Perspectives in Biomedical Research Salvatore Surdo 1,* , Martí Duocastella 1,2,* and Alberto Diaspro 1,3,* 1 Nanoscopy, Istituto Italiano di Tecnologia, Via Enrico Melen 83, Building B, 16152 Genoa, Italy 2 Department of Applied Physics, University of Barcelona, C/Martí i Franquès 1, 08028 Barcelona, Spain 3 Department of Physics, University of Genoa, Via Dodecaneso 33, 16146 Genova, Italy * Correspondence: [email protected] (S.S.); [email protected] (M.D.); [email protected] (A.D.) Abstract: Nanostructured surfaces and devices offer astounding possibilities for biomedical re- search, including cellular and molecular biology, diagnostics, and therapeutics. However, the wide implementation of these systems is currently limited by the lack of cost-effective and easy-to-use nanopatterning tools. A promising solution is to use optical methods based on photonic nanojets, namely, needle-like beams featuring a nanometric width. In this review, we survey the physics, engi- neering strategies, and recent implementations of photonic nanojets for high-throughput generation of arbitrary nanopatterns, along with applications in optics, electronics, mechanics, and biosensing. An outlook of the potential impact of nanopatterning technologies based on photonic nanojets in several relevant biomedical areas is also provided. Keywords: nanotechnology; lithography; laser direct-write; near field; subwavelength Citation: Surdo, S.; Duocastella, M.; 1. Introduction Diaspro, A. Nanopatterning with The ability to pattern a surface with tailored nanostructures, such as trenches, pil- Photonic Nanojets: Review and lars, and spirals, has led to significant advances in the field of biomedical research [1–3]. Perspectives in Biomedical Research. Nanoscale features provide access to unique mechanical, optical, and electronic phenom- Micromachines 2021, 12, 256.
    [Show full text]
  • Redox Titrations
    REDOX TITRATIONS Redox titration is used to determine the oxidizing agent or reducing agent in a solution. In a redox titration, either the reducing or oxidizing agent will be used as the titrant against the other agent. The purpose of this titration is to determine the transfer of electrons from one substance to the other, similar to that of a redox reactions, in order to determine the reducing agent or oxidizing agent. The end point of such titrations can be determined by either a colour changing indicator or a potentiometer. There are many applications of redox titrations in chemistry, pharmaceutical preparations, environmental analysis, agriculture and many more. Redox titrations are important in many areas, for example, in food, pharmaceutical, and general industrial analyses. Titration of sulfite in wine using iodine is a common example. Alcohol can be determined based on its oxidation by potassium dichromate. Examples in clinical analysis are rare since most analyses involve trace determinations, but these titrations are still extremely useful for standardizing reagents. A reducing agent is the reactant that loses electrons in an oxidation-reduction reaction: Fe2+ → Fe3+ + e– An oxidizing agent is the reactant that gains electrons in an oxidation-reduction reaction: Ce4+ + e– → Ce3+ We can split any oxidation/reduction equation into two half-reactions that show which species gains electrons and which loses them. Fe2+ + Ce4+ → Fe3+ + Ce3+ Above reaction can be shown as two half-reactions- Ce4+ + e– → Ce3+ (reduction of Ce4+) Fe2+ → Fe3+ + e– (oxidation of Fe2+) Hence, ferrous sulphate can be estimated quantitatively by its reaction with ceric sulphate.
    [Show full text]
  • 19Th Century Glass Tade Beads
    19TH CENTURY GLASS TRADE BEADS From two Zulu royal residences Sharma Jeanette Saitowitz University of Cape Town The.sis presented to the University of Cape Town in fulfilment of the requirements for the degree of Master of Arts June 1990 The copyright of this thesis vests in the author. No quotation from it or information derived from it is to be published without full acknowledgement of the source. The thesis is to be used for private study or non- commercial research purposes only. Published by the University of Cape Town (UCT) in terms of the non-exclusive license granted to UCT by the author. University of Cape Town ABSTRACT This thesis is a formal analysis of beads from the two Zulu capitals of Mgungundlovu ( occupied by Dingane between 1829 and 1838) and Ondini (held by Cetshwayo between 1873 and 1879). It contains a set of procedures for producing a bead taxonomy, most of which has been adopted from work done in North America, bur some of which consists of analytical methods original to this study. The taxonomy is based on visual and physical screening of large collections, followed by chemical analysis. It provides a standardized system for South African bead studies. Results of the analysis are employed for the following purposes: 1) To provide a database of the varieties of glass beads in circulation in Zululand for two relatively short periods of time in the nineteenth century. 2) To determine the spatial and temporal variability in relative abundance of bead types in the two sites. Subtle differences occur between beads excavated from one section of Mgungundlovu and another.
    [Show full text]
  • Encyclopedia of Japanese Business and Management
    ENCYCLOPEDIA OF JAPANESE BUSINESS AND MANAGEMENT ENCYCLOPEDIA OF JAPANESE BUSINESS AND MANAGEMENT Edited by Allan Bird London and New York First published 2002 by Routledge 11 New Fetter Lane, London EC4P 4EE Simultaneously published in the USA and Canada by Routledge 29 West 35th Street, New York, NY 10001 Routledge is an imprint of the Taylor & Francis Group This edition published in the Taylor & Francis e-Library, 2007. “To purchase your own copy of this or any of Taylor & Francis or Routledge’s collection of thousands of eBooks please go to www.eBookstore.tandf.co.uk” ©selection and editorial matter Allan Bird 2002; ©the entries Routledge 2002 All rights reserved. No part of this book may be reprinted or reproduced or utilized in any form or by any electronic, mechanical, or other means, now known or hereafter invented, including photocopying and recording, or in any information storage or retrieval system, without permission in writing from the publishers. British Library Cataloguing in Publication Data A catalogue record for this book is available from the British Library Library of Congress Cataloging in Publication Data Encyclopedia of Japanese business and management/edited by Allan Bird. Includes bibliographical references and index. 1. Japan—Gommerce—Encyclopedias. 2. Industrial management—Japan— Encyclopedias. 3. Corporations, Japanese—Management—Encyclopedias. 4. Business enterprises—Japan—Encyclopedias. 5. Japan—Commerce— Dictionaries. 6. Japanese language—Dictionaries-English. I. Title: Japanese business and management. II. Bird, Allan. HF1001 .E467 2001 1650′.0952–dc21 2001019952 ISBN 0-203-99632-1 Master e-book ISBN ISBN 0-415-18945-4 (Print Edition) Contents List of contributors vii Entries A-Z 1 Acknowledgements xi Introduction xiii Index 483 How to use this book xv Thematic entry list xvi Contributors Editorial team Volume editor Allan Bird University of Missouri, St.
    [Show full text]
  • Processing of Hollow Glass Microspheres
    Sci Eng Compos Mater 2021; 28:116–127 Research Article Olusegun A. Afolabi, Krishnan Kanny, and T. P Mohan* Processing of Hollow Glass Microspheres (HGM) filled Epoxy Syntactic Foam Composites with improved Structural Characteristics https://doi.org/10.1515/secm-2021-0011 This HGM is embedded in a polymer material to form syntac- Received Aug 10, 2020; accepted Nov 30, 2020 tic foam composites. The hollow particles may sometimes be in the form of metal, carbon, ceramics, or polymer [1, 3]. Abstract: The objective of this work is to improve the struc- Furthermore, thermoset resins such as epoxy are generally tural characteristics of hollow glass microsphere (HGM) used as a binder for combining of microballoons, which pro- filled epoxy syntactic foam composites with little voids con- duces composite material with improved properties. Com- tent and improved HGM dispersion in the composite. posite material developed from this combination is widely A modified degassing technique has been introduced dur- used in structural applications due to its low cost, excellent ing resin casting process of the HGM filled syntactic foam specific strength, and ease of processing [4, 5]. composites. The effect of HGM content volume fractions There is a need to produce a lightweight material for the (5-25%) on the degassing techniques was examined. The structural application that is economically friendly and fire syntactic foam composites were characterized by analysing retardant. Syntactic foams have been studied to fit into this structural morphology using Scanning Electron Microscopy aspect because they are known to be of good advantages (SEM), Transmission Electron Microscopy(TEM), and den- for construction purposes due to their reduced weight thus sity measurements (theoretical and experimental).
    [Show full text]