DOCSLIB.ORG

Paint Film Components Monograph

Total Page:16

File Type:pdf, Size:1020Kb

Download full-text PDF Read full-text
Paint Film Components Monograph NATIONAL ENVIRONMENTAL HEALTH FORUM Paint Film Components National Environmental Health Monographs General Series No. 2 1998 1 Paint Film Components M van Alphen National Environmental Health Forum Monographs General Series No. 2 National Environmental Health Forum 1998 Paint Film Components 2 Copyright 1998 Copyright in this publication is assigned to the Department of Human Services on the basis of an agreement with M van Alphen Printed by Glenelg Press Published by the National Environmental Health Forum Prepared for publication by Bill Lock Public and Environmental Health Service Department of Human Services Price available on application. Correspondence with the author on Paint Film Components can be sent to: Mike van Alphen PO Box 3421 Rundle Mall SA 5000 Minor amendments have been made to page 8. The list of Published Monographs has been updated. National Library of Australia Cataloguing-in-Publication; van Alphen, Mike. Paint film components. Bibliography. ISBN 0 642 30532 3. ISSN 1328 - 2867 1. Paint - Analysis. 2. Paint - Toxicology. I. National Environmental Health Forum. II. Title. (Series: National Environmental Health Forum Monographs. General Series; no. 2 Paint Film Components 3 Contents Acknowledgements 7 Disclaimer 7 Published monographs 8 Preface 9 1. Legislation affecting paint 12 1.1 International 12 1.2 Great Britain 12 1.3 Australia 13 1.3.1 Past legislation relating to paint manufacture and sale in Australia 13 1.3.2 Queensland 14 1.3.3 Tasmania 15 1.3.4 New South Wales 16 1.3.5 South Australia 16 1.3.6 Australia 16 1.4 Occupational health and safety and paint in Australia 17 2. The Paint Industry 19 2.1 The export and import of paints 19 2.2 The paint industry in Australia 19 2.3 Pigment manufacture 22 2.4 The early water paints - whitewash 22 2.5 Pigments and paint formulation practice 24 2.6 Pigment particle characteristics 25 2.7 After-treated and core pigments 26 2.8 World wide pigment utilisation 26 3. Lead pigments 27 3.1 White lead 27 3.1.1 Introduction 27 3.1.2 White lead manufacture processes 28 3.1.3 Properties of white lead 28 3.1.4 Imitation mother of pearl - white lead 30 3.2 White basic sulphate of lead 31 3.3 Red lead paint 32 3.4 Sublimed blue lead 34 3.5 Calcium plumbate 34 3.6 Lead titanate 35 3.7 Lead chlorides in paint 35 3.8 Lead chromates 35 4. The mixing of lead and zinc in paint 37 5. Zinc in paint 38 5.1 Zinc oxide 38 Paint Film Components 4 6. Lithopone 41 7. Titanium Dioxide 44 7.1 Introduction 44 7.1.1 TiO2 from ilmenite 44 7.1.2 Anatase and rutile forms of TiO2 45 7.1.3 Trace components of titanium dioxide pigments 45 7.1.4 Extended TiO2 47 7.1.5 Was TiO2 a well known pigment in the 1940s? 47 8. Lead, Zinc Oxide, Lithopone and TiO2 49 8.1 TiO2 in Australia 50 8.2 Summary: TiO2 in paint 51 9. Other pigment materials 51 9.1 Antimony 51 9.2 Arsenic 52 9.3 Barium 52 9.4 Bismuth 54 9.5 Cadmium pigments 54 9.6 Chromate pigments 55 9.6.1 Introduction 55 9.6.2 Chrome green and fast chrome green 55 9.6.3 Chromium oxide 56 9.6.4 Zinc chromate 56 9.7 Cobalt 57 9.8 Copper 57 9.9 Iron 58 9.10 Manganese 58 9.11 Mixed metal oxide pigments 58 9.12 Molybdate red and orange pigments 59 9.13 Organic pigments 59 9.13.1 3,3'-Dichlorobenzidine 59 9.13.2 Benzidine 60 9.13.3 para-Chloro-ortho-toluidine 60 9.13.4 5-Nitro-ortho-toluidine 60 9.14 Prussian blue: ferric ferrocyanide 60 9.14.1 Brunswick Green 61 9.15 Ultramarine 62 10. Paint additives 63 10.1 Introduction 63 10.2 Mineral whites, fillers or extenders 63 10.3 Asbestos 64 10.3.1 Asbestos, asbestine and other nomenclature 64 10.3.2 The function of asbestos in paint 64 10.3.3 Quantities of asbestos in paint 65 Paint Film Components 5 10.3.4 The risk of asbestos in paint 67 10.4 Driers 68 10.4.1 Paint driers, old and recent 68 10.4.2 Driers: usual practice 70 10.4.3 The misuse of driers 71 10.5 Risks associated with paint driers 72 10.6 Fungicides 72 10.6.1 Surface disinfection in hospitals 74 10.7 Insecticidal paints 75 10.8 Mercury in paint 75 10.8.1 Mercury as a pigment 75 10.8.1.1 Substitutions for mercury as a pigment 76 10.8.1.2 Lingering use of mercury as a pigment 76 10.8.2 Mercury as a biocide 78 10.9 Plasticisers 80 10.10 Stabilisers 81 10.11 Thixotropic agents 81 11. Chlorine in paint 82 11.1 Chlorinated rubber 82 11.2 Polychlorinated biphenyls in paint 82 11.3 Chlorinated paraffins in paint 83 12. Metal primers: General 84 13. Metallic materials in paint 85 13.1 Metallic lead as a primer 85 13.2 Zinc dust metal paints 86 14. Luminous and fluorescent paints 86 15. Some non-household paints 87 15.1 Vehicle paints 87 15.2 Marine paints 87 15.2.1 Antifouling 88 16. Paint failure 89 16.1 Paint chalking descriptions 89 16.2 Paint chalking causes 90 16.3 Chalking of white lead paint 90 16.4 Susceptible pigments and modifications of pigments to address chalking 91 16.5 Properties of chalked paint surfaces 91 16.6 The risks of chalking paint 91 16.7 The durability and weathering of paint films 92 16.8 Gross failure 94 16.8.1 Alligatoring and cracking 94 16.8.2 Blistering 95 17. Renovating 96 17.1 Sandpaper abrasion of paint 96 Paint Film Components 6 17.2 Paint removal using heat 96 18. Paint solvents 97 19. Paint Substrates 97 19.1 Putty 98 19.2 Wood preservatives 99 19.3 Wood 99 19.4 Corrugated iron 99 19.5 Paint failure on cement 100 19.6 Miscellaneous 101 20. Lead in paint on Australian houses 101 20.1 Queensland 101 20.2 Mort Bay, Sydney 101 20.3 Boolaroo, Newcastle 102 20.4 Port Pirie 102 20.5 Broken Hill 103 20.6 Paint lead in residential settings in Australia 103 20.7 Summary: The analysis of lead in paint in Australia 104 21. Paint covering and paint thickness, lead loadings and lead concentrations 105 21.1 Upper limits for lead content 105 21.2 Paint film thickness 105 21.3 Painted surface lead loadings 106 21.3.1 Summary 109 22. How much paint lead on a house? 110 23. The amount of lead in a chip of paint 111 24. Lead added to soils 113 References 117 Appendix 1 ~ Inorganic pigments 124 Appendix 2 ~ Paint pigments 128 Appendix 3 ~ Synthetic organic pigments 132 Paint Film Components 7 Acknowledgements My work in the South Australian Health Commission since 1993 has been directed towards the investigation of child lead exposure and lead smelter emissions with a limited emphasis on paint lead. An early draft of this work emerged after the realisation of the presence of paint film components such as asbestos, mercury, cadmium, and PCBs, among other components that may pose risks; in addition to those of lead. This project emerged (after hours) given the early encouragement of Mark Farfel, Rob Fowler and Nick Kim. For unpublished paint lead analysis data provided by Dani Boddington of the Broken Hill Environmental Lead Centre, and national paint lead survey data from Phil Anderson of the Australian Institute of Health and Welfare, I owe particular thanks. Two technical references provided a great deal of historical data for this work, the publishers of The Forensic Examination of Paints and Pigments (Charles C Thomas) and Paint Film Defects: their causes and cure (Chapman and Hall) have kindly provided permission to reproduce extended extracts from their works. Comments provided on the text by Andrew Langley and Nick Kim were very useful, the final preparation of the document, review of the text and checking of calculations by Bill Lock was readily appreciated. Any feedback on this work; be it requests for clarification, suggestions of alternate sources of information or any matters of debate; they would be greatly appreciated by the writer. Finally I thank Joe van Alphen - who has shared much practical knowledge, from some 40 years in the painting trade. Disclaimer This document has been prepared in good faith exercising due care and attention. However, no representation or warranty, expressed or implied, is made as to the relevance, accuracy, completeness or fitness for purpose of this document in respect of any particular user’s circumstances. Users of this document should satisfy themselves concerning its application to, and where necessary seek expert advice about, their situation. The NEHF, its participants and the SAHC shall not be liable to the purchaser or any other person or entity with respect to any liability, loss or damage caused or alleged to have been caused directly or indirectly by this publication. Paint Film Components 8 Published monographs Water Series 1. Guidance for the control of Legionella (1996) 2. Guidance on water quality for heated spas (1996) 3. Guidance on the use of rainwater tanks (1998) Soil Series 1. Health-based soil investigation levels, 2nd edition (1998) 2. Exposure scenarios and exposure settings, 2nd edition (1998) 3. Composite sampling (1996) Metal Series 1.
Load more

Recommended publications
  • Additions to the Rust Fungi of South Africa
    View metadata, citation and similar papers at core.ac.uk brought to you by CORE provided by RERO DOC Digital Library Mycol Progress (2012) 11:483–497 DOI 10.1007/s11557-011-0764-z ORIGINAL ARTICLE Additions to the rust fungi of South Africa Reinhard Berndt & Alan R. Wood Received: 7 February 2011 /Revised: 15 April 2011 /Accepted: 19 April 2011 /Published online: 28 May 2011 # German Mycological Society and Springer 2011 Abstract This paper presents new species, combinations, Leucosidea sericea (Rosaceae), Uromyces cypericola whose national reports and host records for the South African rust urediniospores are described for the first time, Phakopsora fungi (Uredinales/Pucciniales). Endophyllum mpenjatiense stratosa in that spermogonia and Uredo-like aecia were on cf. Hibiscus sp. (Malvaceae), Phakopsora combretorum discovered, and for Sphaerophragmium dalbergiae in that (anamorph Uredo combreticola) on the new host Combretum characters of the urediniospores are re-evaluated. A lectotype apiculatum (Combretaceae) and Uredo sekhukhunensis on is selected for Aecidium garckeanum and spermogonia are Ziziphus mucronata (Rhamnaceae) are described as new reported for this rust for the first time. The rust fungi of species. Dietelia cardiospermi and E. metalasiae are Ehrharta (Poaceae) are discussed and critically evaluated in proposed as new combinations to replace Aecidium cardio- the light of spore morphology and host species. spermi on Cardiospermum halicacabum (Sapindaceae) and A. metalasiae on Metalasia spp. (Asteraceae), respectively. Keywords Combretum . Dietelia . Ehrharta . Four species are new records for South Africa: Crossopsora Endophyllum . Ziziphus antidesmae-dioicae on Antidesma venosum (Euphorbiaceae), Phakopsora ziziphi-vulgaris on Z. mucronata,andUromyces cypericola and Puccinia subcoronata, both on a new host, Introduction Cyperus albostriatus (Cyperaceae).
    [Show full text]
  • HISTORY of LEAD POISONING in the WORLD Dr. Herbert L. Needleman Introduction the Center for Disease Control Classified the Cause
    HISTORY OF LEAD POISONING IN THE WORLD Dr. Herbert L. Needleman Introduction The Center for Disease Control classified the causes of disease and death as follows: 50 % due to unhealthy life styles 25 % due to environment 25% due to innate biology and 25% due to inadequate health care. Lead poisoning is an environmental disease, but it is also a disease of life style. Lead is one of the best-studied toxic substances, and as a result we know more about the adverse health effects of lead than virtually any other chemical. The health problems caused by lead have been well documented over a wide range of exposures on every continent. The advancements in technology have made it possible to research lead exposure down to very low levels approaching the limits of detection. We clearly know how it gets into the body and the harm it causes once it is ingested, and most importantly, how to prevent it! Using advanced technology, we can trace the evolution of lead into our environment and discover the health damage resulting from its exposure. Early History Lead is a normal constituent of the earth’s crust, with trace amounts found naturally in soil, plants, and water. If left undisturbed, lead is practically immobile. However, once mined and transformed into man-made products, which are dispersed throughout the environment, lead becomes highly toxic. Solely as a result of man’s actions, lead has become the most widely scattered toxic metal in the world. Unfortunately for people, lead has a long environmental persistence and never looses its toxic potential, if ingested.
    [Show full text]
  • Making Basic Period Pigments at Home
    Making Basic Period Pigments at Home KWHSS – July 2019 Barony of Coeur d’Ennui Kingdom of Calontir Mistress Aidan Cocrinn, O.L., Barony of Forgotten Sea, Kingdom of Calontir Mka Holly Cochran [email protected] Contents Introduction .................................................................................................................................................. 3 Safety Rules: .................................................................................................................................................. 4 Basic References ........................................................................................................................................... 5 Other important references:..................................................................................................................... 6 Blacks ............................................................................................................................................................ 8 Lamp black ................................................................................................................................................ 8 Vine black .................................................................................................................................................. 9 Bone Black ................................................................................................................................................. 9 Whites ........................................................................................................................................................
    [Show full text]
  • Ayesha Altaf Env Sci 2018 LCWU PRR.Pdf
    NATURAL COLORANTS AS PHOTOSENSITIZER FOR DYE-SENSITIZED SOLAR CELLS (DSSCs) FOR GREEN ECONOMY By Ayesha Altaf DEPARTMENT OF ENVIRONMENTAL SCIENCE LAHORE COLLEGE FOR WOMEN UNIVERSITY, LAHORE, PAKISTAN 2018 NATURAL COLORANTS AS PHOTOSENSITIZER FOR DYE-SENSITIZED SOLAR CELLS (DSSCs) FOR GREEN ECONOMY A THESIS SUBMITTED TO LAHORE COLLEGE FOR WOMEN UNIVERSITY IN PARTIAL FULFILLMENT OF THE REQUIREMENTS FOR THE DEGREE OF DOCTOR OF PHILOSPHY IN ENVIRONMENTAL SCIENCE By Ayesha Altaf Registration No. 14-PhD/LCWU-193 Supervisor: Prof. Dr. Tahira Aziz Mughal Co-Supervisor: Dr. Zafar Iqbal DEPARTMENT OF ENVIRONMENTAL SCIENCE LAHORE COLLEGE FOR WOMEN UNIVERSITY, LAHORE, PAKISTAN 2018 Declaration Form This is to certify that the research work described in this thesis submitted by Mrs. Ayesha Altaf to Department of Environmental Sciences, Lahore College for Women University has been carried out under my direct supervision. I have personally gone through the raw data and certify the correctness and authenticity of all results reported herein. I further certify that thesis data have not been use in part or full, in a manuscript already submitted or in the process of submission in Partial/complete fulfillment of the award of any other degree from any other institution or home or abroad. I also certified that the enclosed manuscript, has been to paid under my supervision and I endorse its evaluation for the award of Ph.D degree through the official procedure of University. ________________ __________________ Prof. Dr. Tahira Aziz Mughal Dr. Zafar Iqbal (Supervisor) (Co- Supervisor) Date: ___________ Date: ___________ _________________ Date: ___________ External Examiner ________________ Date: ___________ Chairperson Department of Environmental Science LCWU, Lahore Stamp ______________________ Controller of Examination LCWU, Lahore.
    [Show full text]
  • Derivan Matisse Flow to Americana Acrylics Color Conversion Chart
    Derivan Matisse Flow to Americana Acrylics Color Conversion Chart Derivan Americana Derivan Americana Matisse Flow Acrylics Matisse Flow Acrylics Alpine Green 2 - DAO82 Evergreen Brilliant Alizarine 2 - DA179 Alizarin Crimson 1 - DA144 Yellow Light 1 - DA159 Cherry Red Antique Blue 1 - DAO38 Wedgewood Blue Burgundy 1 - DA140 Red Violet 1 - DA166 Deep Midnight Blue 1 - DA165 Napa Red 1 - DA172 Black Plum Antique Gold 1 - DA146 Antique Gold Deep Burnt Sienna DA223 Traditional Burnt Sienna ato - DAO67 Lamp (Ebony) Black Antique Green 2 - DA105 Blue Grey Mist Burnt Umber 2 - DA221 Traditional Burnt Umber 1 - DAO84 Midnite Green 1 - DA160 Antique Maroon Antique White 2 - DA239 Warm White Cadmium Orange 8 - DA228 Bright Orange 1 - DAO3 Buttermilk 1 - DAO10 Cadmium Yellow Aqua Green Light 2 - DAO1 Snow (Titanium) White Cadmium Red Medium DAO15 Cadmium Red 1 - DAO47 Bluegrass Green Ash Pink 4 - DA164 Light Buttermilk Cadmium Yellow Light DA144 Yellow Light 3 - DA189 Summer Lilac 2 - DA186 French Mauve Aureolin Yellow 4 - DA144 Yellow Light Cadmium Yellow Medium DA227 Bright Yellow 1 - DA146 Antique Gold Deep 1 - DAO10 Cadmium Yellow Australian Olive Green 10 - DA113 Plantation Pine Carbon Black DAO67 Lamp (Ebony) Black 1 - DAO67 Lamp (Ebony) Black Australian Red Violet DA140 Red Violet Cerulean Blue DAO36 True Blue Australian Sap Green 2 - DA113 Plantation Pine Chromium Green Oxide 2 - DAO51 Leaf Green 1 - DA144 Yellow Light 1 - DAO53 Mistletoe Australian Sienna 1 - DA223 Traditional Burnt Sienna Cobalt Blue 2 - DA141 Blue Violet 1 - DA194 Marigold
    [Show full text]
  • Study of Fragments of Mural Paintings from the Roman Province Of
    Study of fragments of mural paintings from the Roman province of Germania Superior Thesis submitted in partial fulfilment of the requirements of the degree Doctor rer. nat. of the Faculty of Environment and Natural Resources, Albert-Ludwigs-Universität Freiburg im Breisgau, Germany by Rafaela Debastiani Freiburg im Breisgau, Germany 2016 Name of Dean: Prof. Dr. Tim Freytag Name of Supervisor: Prof. Dr. Michael Fiederle Name of 2nd Reviewer: PD Dr. Andreas Danilewsky Date of thesis' defense: 03.02.2017 “The mind is not a vessel to be filled, but a fire to be kindled” Plutarch Contents Nomenclature ........................................................................................................................ 1 Acknowledgment ................................................................................................................... 3 Abstract ................................................................................................................................. 5 Zusammenfassung ................................................................................................................ 7 1. Introduction .................................................................................................................... 9 2. Analytical techniques in the non-destructive analyses of fragments of mural paintings ..13 2.1 X-ray Fluorescence Spectroscopy ..........................................................................13 2.1.1 Synchrotron-based scanning macro X-ray fluorescence (MA-XRF) .................17
    [Show full text]
  • Rust Disease of Water Willow Intercepted in Import Plant Quarantine in Japan
    RES.BULL.PL.PROT.JAPAN No. 41: 59~64(2005) Short Communication Rust Disease of Water Willow Intercepted in Import Plant Quarantine in Japan Yoichi MOTOKURA, Masayoshi NAGASE*, Akihiro OOI**, Koshi UEDA, and SHIGERU KIMURA Research Division, Yokohama Plant Protection Station 1-16-10, Shin-yamashita, Naka-ku, Yokohama 231- 0801, Japan. * Nagoya Airport Branch, Nagoya Plant Protection Station ** Nagoya Plant Protection Station Abstract: A rust disease on water willow(Justicia gendarussa Burm f.)was found at an import plant quar- antine inspection at Nagoya airport, in January, 2002. The causal rust fungus was identified with Puccinia thwaitesii Berk., based on it's morphology and the results of inoculation experiments. This is the first report on the interception of rust disease of water willow caused by P. thwaitesii at import plant quarantine inspection in Japan. Key words: rust, water willow, Justicia gendarussa, Puccinia thwaitesii Introduction Water willow(Justicia gendarussa Burm f..)is a perennial shrub native to the tropical and sub- tropical zones of the Asia, and it belongs to Acanthaceae(Editorial Committee of the Flora of Taiwan,1998). In the Southeast Asia, this plant is utilized as a raw material of Chinese medicine, or as a medicine for rheumatism(IWATSUKI et. al. ed., 1997). In our country, water willow is introduced and used as an ornamental plant, mainly for indoor. In January 2002, potted plants of water willow infected with a rust disease were found at an import plant quarantine inspection at Komaki(Nagoya international airport)in Japan. They were plants imported from Thailand for use as the ornamental foliage.
    [Show full text]
  • PIGMENTS Pigments Can Be Used for Colouring and Tinting Paints, Glazes, Clays and Plasters
    PIGMENTS Pigments can be used for colouring and tinting paints, glazes, clays and plasters. About Pigments About Earthborn Pigments Get creative with Earthborn Pigments. These natural earth and mineral powders provide a source of concentrated colour for paint blending and special effects. With 48 pigments to choose from, they can be blended into any Earthborn interior or exterior paint to create your own unique shade of eco friendly paint. Mixed with Earthborn Wall Glaze, the pigments are perfect for decorative effects such as colour washes, dragging, sponging and stencilling. Some even contain naturally occurring metallic flakes to add extra dazzle to your design. Earthborn Pigments are fade resistant and can be mixed with Earthborn Claypaint and Casein Paint. Many can also be mixed with lime washes, mortars and our Ecopro Silicate Masonry Paint. We have created this booklet to show pigments in their true form. Colour may vary dependant on the medium it is mixed with. Standard sizes 75g, 500g Special sizes 50g and 400g (Mica Gold, Mangan Purple, Salmon Red and Rhine Gold only) Ingredients Earth pigments, mineral pigments, metal pigments, trisodium citrate. How to use Earthborn Pigments The pigments must be made into a paste before use as follows: For Silicate paint soak pigment in a small amount of Silicate primer and use straightaway. For Earthborn Wall Glaze, Casein or Claypaint soak pigment in enough water to cover the powder, preferably overnight, and stir to create a free-flowing liquid paste. When mixing pigments into any medium, always make a note of the amounts used. Avoid contact with clothing as pigments may permanently stain fabrics.
    [Show full text]
  • A Novel Route to Synthesis of Lead Glycolate and Perovskite Lead Titanate, Lead Zirconate, and Lead Zirconate Titanate (PZT)
    36 «“√ “√«‘®—¬ ¡¢. (∫».) 7 (1) : ¡.§. - ¡’.§. 2550 A Novel Route to Synthesis of Lead Glycolate and Perovskite Lead Titanate, Lead Zirconate, and Lead Zirconate Titanate (PZT) via Sol-Gel Process π«—µ°√√¡¢Õß°√–∫«π°“√ —߇§√“–Àå‡≈¥‰°≈‚§‡≈µ·≈–‚§√ß √â“ß·∫∫ ‡æÕ√Õø ‰°µå¢Õ߇≈¥‰∑∑“‡πµ ‡≈¥‡´Õ√傧‡πµ ·≈– ‡≈¥‡´Õ√傧‡πµ‰∑∑“‡πµ ºà“π°√–∫«π°“√‚´≈-‡®≈ Nuchnapa Tangboriboon (πÿ™π¿“ µ—Èß∫√‘∫Ÿ√≥å)* Dr. Sujitra Wongkasemjit (¥√. ÿ®‘µ√“ «ß»å‡°…¡®‘µµå)** Dr. Alexander M. Jameison (¥√. Õ‡≈Á°´“π‡¥Õ√å ‡ÕÁ¡ ‡®¡‘ —π)*** Dr. Anuvat Sirivat (¥√. Õπÿ«—≤πå »‘√‘«—≤πå)**** ABSTRACT The reaction of lead acetate trihydrate Pb(CH3COO)2.3H2O and ethylene glycol, using triethylenetetramine (TETA) as a catalyst, provides, in one step, an access to a polymer-like precursor of lead glycolate [-PbOCH2CH2O-] via oxide one pot synthesis (OOPS). The lead glycolate precursor has superior electrical properties than lead acetate trihydrate, suggesting that the lead glycolate precursor can possibly be used as a starting material mixed with other precursors such as titanium glycolate and sodium tris (glycozirconate) to produce lead titanate, lead zirconate, and lead zirconate titanate by sol-gel transition process. ∫∑§¥¬— àÕ ß“π«‘®—¬π’ȉ¥â»÷°…“°“√‡°‘¥ªØ‘°‘√‘¬“√–À«à“߇≈¥Õ–´’‡µ¥‰µ√‰Œ‡¥√µ ·≈–‡Õ∑‘≈’π‰°≈§Õ≈‚¥¬„™â “√ ‰µ√‡Õ∑‘≈’π‡µµ√–¡’π‡ªìπ§–µ–≈’ µå‡æ◊ËÕ„™â„π°“√º≈‘µ “√µ—Èßµâπ‚æ≈‘‡¡Õ√å§◊Õ‡≈¥‰°≈‚§‡≈µ [-PbOCH2CH2O-] ∑ ”§’Ë ≠™π— ¥Àπ‘ ßµ÷Ë Õ¢∫«π°“√𔉪„™à „π°“√ â ߇§√“–À— å “√‰¥Õ‡≈§µ√‘ °™π‘ ¥µ‘ “ßÊà ‰¥·°â à “√‡øÕ√‚√‰¥Õå ‡≈§µ√‘ °‘ “√·Õπ‰∑‡øÕ√å‚√Õ‘‡≈§µ√‘°·≈– “√‡æ’¬‚´‰¥Õ‘‡≈§µ√‘°®“°°“√ —߇§√“–Àå¥â«¬ “√ª√–°Õ∫ÕÕ°‰´¥å‡æ’¬ß ¢—ÈπµÕπ‡¥’¬«∑’ˇ√’¬°«à“ Oxide One Pot Synthesis (OOPS) ∑”„À≥⠓√µ—Èßµâπ‡≈¥‰°≈‚§‡≈µ¡’ ¡∫—µ‘∑“߉øøÑ“ ¥’°«à“‡≈¥Õ–´’‡µ¥‰µ√‰Œ‡¥√µ πÕ°®“°π’Ȭ—ß “¡“√∂𔉪„™âº ¡°—∫ “√µ—Èßµâπ™π‘¥Õ◊ËπÊ ‡™àπ ‰∑∑“‡π’¬¡ ‰°≈‚§‡≈µ·≈–‚´‡¥’¬¡∑√’ ‰°≈‚§‡´Õ√傧‡πµ‡æ◊ËÕº≈‘µ‡≈¥‰∑∑“‡πµ ‡≈¥‡´Õ√傧‡πµ·≈–‡≈¥‡´Õ√傧‡πµ ‰∑∑“‡πµ ‚¥¬ºà“π°√–∫«π°“√‚´≈-‡®≈∑√“π ‘™—Ëπ Key Words : OOPS, Sol-gel process, Dielectric materials §” ”§—≠ : OOPS °√–∫«π°“√‚´≈-‡®≈ «— ¥ÿ‰¥Õ‘‡≈§µ√‘° * Ph.D.
    [Show full text]
  • The Titanium Industry: a Case Study in Oligopoly and Public Policy
    THE TITANIUM INDUSTRY: A CASE STUDY IN OLIGOPOLY AND PUBLIC POLICY DISSERTATION Presented in Partial Fulfillment of the Requirements for the Degree Doctor of Philosophy In the Graduate School of the Ohio State University by FRANCIS GEORGE MASSON, B.A., M.A. The Ohio State University 1 9 5 k Content* L £MR I. INTRODUCTION............................................................................................... 1 II. THE PRODUCT AND ITS APPLICATIONS...................................... 9 Consumption and Uses ................................. 9 Properties ........................................................ ...... 16 III. INDUSTRY STRUCTURE................................................................................ 28 Definition of the I n d u s t r y ............................................ 28 Financial Structure. ..••••••.••. 32 Alloys and Carbide Branch. ........................... 3 k Pigment Branch .............................................................................. 35 Primary Metal Branch ................................. 1*0 Fabrication Branch ................................. $0 IT. INDUSTRY STRUCTURE - CONTINUED............................................. $2 Introduction ................................ $2 World Production and Resources ................................. $3 Nature of the Demand for Ram Materials . $8 Ores and Concentrates Branch. ••••••• 65 Summary.................................................................. 70 V. TAXATION. ANTITRUST AND TARIFF POLICY............................
    [Show full text]
  • Standard Operating Procedure for the Preparation of Lead-Containing Paint Films and Lead-In-Paint Diagnostic Test Materials
    EPA/600/R-10/070 August 2009 www.epa.gov/ord Standard Operating Procedure for the Preparation of Lead-Containing Paint Films and Lead-in-Paint Diagnostic Test Materials Prepared by Kristen Sorrell, David Binstock, Curtis Haas, Cynthia Salmons, and William Gutknecht Environmental and Industrial Sciences Division RTI International Research Triangle Park, NC 27709 Disclaimer The information in this document has been funded wholly or in part by the U. S. Environmental Protection Agency (EPA) under EPA Contract No. EP-D-05-065 to Alion Science and Technology, Inc., and RTI Subcontract No. SUB1174861RB. It has been subjected to the Agency’s peer and administrative review. Mention of trade names or commercial products does not constitute endorsement or recommendation for use. ii Acknowledgments This document was prepared under the direction of the Work Assignment Contracting Officer’s Representative, Ms. Sharon L. Harper, National Environmental Research Laboratory, U.S. Environmental Protection Agency, Research Triangle Park, NC. Special acknowledgment is given to Dr. Hunter Daughtrey, Alion Science and Technology, Inc., for his support of this effort and careful review of this document. iii iv Table of Contents List of Figures...............................................................................................................................................vii List of Appendixes........................................................................................................................................vii 1.0 PRINCIPLE AND
    [Show full text]
  • Toxicological Profile for Lead
    TOXICOLOGICAL PROFILE FOR LEAD U.S. DEPARTMENT OF HEALTH AND HUMAN SERVICES Public Health Service Agency for Toxic Substances and Disease Registry August 2007 LEAD ii DISCLAIMER The use of company or product name(s) is for identification only and does not imply endorsement by the Agency for Toxic Substances and Disease Registry. LEAD iii UPDATE STATEMENT A Toxicological Profile for Lead, Draft for Public Comment was released in September 2005. This edition supersedes any previously released draft or final profile. Toxicological profiles are revised and republished as necessary. For information regarding the update status of previously released profiles, contact ATSDR at: Agency for Toxic Substances and Disease Registry Division of Toxicology and Environmental Medicine/Applied Toxicology Branch 1600 Clifton Road NE Mailstop F-32 Atlanta, Georgia 30333 LEAD iv This page is intentionally blank. v FOREWORD This toxicological profile is prepared in accordance with guidelines developed by the Agency for Toxic Substances and Disease Registry (ATSDR) and the Environmental Protection Agency (EPA). The original guidelines were published in the Federal Register on April 17, 1987. Each profile will be revised and republished as necessary. The ATSDR toxicological profile succinctly characterizes the toxicologic and adverse health effects information for the hazardous substance described therein. Each peer-reviewed profile identifies and reviews the key literature that describes a hazardous substance's toxicologic properties. Other pertinent literature is also presented, but is described in less detail than the key studies. The profile is not intended to be an exhaustive document; however, more comprehensive sources of specialty information are referenced. The focus of the profiles is on health and toxicologic information; therefore, each toxicological profile begins with a public health statement that describes, in nontechnical language, a substance's relevant toxicological properties.
    [Show full text]