DOCSLIB.ORG

RISK ASSESSMENT REPORT ZINC PHOSPHATE CAS-No

Total Page:16

File Type:pdf, Size:1020Kb

Download full-text PDF Read full-text
RISK ASSESSMENT REPORT ZINC PHOSPHATE CAS-No RISK ASSESSMENT REPORT ZINC PHOSPHATE CAS-No.: 7779-90-0 EINECS-No.: 231-944-3 GENERAL NOTE This document contains: - part I Environment (pages 44) - part II Human Health (pages 124) R077_0805_env RISK ASSESSMENT ZINC PHOSPHATE CAS-No.: 7779-90-0 EINECS-No.: 231-944-3 Final report, May 2008 PART 1 Environment Rapporteur for the risk evaluation of zinc phosphate is the Ministry of Housing, Spatial Planning and the Environment (VROM) in consultation with the Ministry of Social Affairs and Employment (SZW) and the Ministry of Public Health, Welfare and Sport (VWS). Responsible for the risk evaluation and subsequently for the contents of this report is the rapporteur. The scientific work on this report has been prepared by the Netherlands Organization for Applied Scientific Research (TNO) and the National Institute of Public Health and Environment (RIVM), by order of the rapporteur. Contact point: Bureau Reach P.O. Box 1 3720 BA Bilthoven The Netherlands R077_0805_env PREFACE For zinc metal (CAS No. 7440-66-6), zinc distearate (CAS No. 557-05-1 / 91051-01-3), zinc oxide (CAS No.1314-13-2), zinc chloride (CAS No.7646-85-7), zinc sulphate (CAS No.7733- 02-0) and trizinc bis(orthophosphate) (CAS No.7779-90-0) risk assessments were carried out within the framework of EU Existing Chemicals Regulation 793/93. For each compound a separate report has been prepared. It should be noted, however, that the risk assessment on zinc metal contains specific sections (as well in the exposure part as in the effect part) that are relevant for the other zinc compounds as well. For these aspects, the reader is referred to the risk assessment report on zinc. 2 CAS No.7779-90-0 R077_0805_env CONTENTS 0 OVERALL CONCLUSIONS/RESULTS OF THE RISK ASSESSMENT 6 1 GENERAL SUBSTANCE INFORMATION 9 1.1 Identification of the substance 9 1.2 Environmental classification and labelling of zinc phosphate 10 1.2.1 Introduction 10 1.2.2 Test results water solubility and aquatic toxicity 10 1.2.3 Conclusion 11 2 GENERAL INFORMATION ON EXPOSURE 12 2.1 Production 12 2.2 Use pattern 12 3 ENVIRONMENT 14 3.1 General introduction 14 3.2 Environmental exposure 15 3.2.1 Exposure scenarios 16 3.2.1.1 General 16 3.2.1.2 Local exposure assessment 18 3.2.1.2.1 General 18 3.2.1.2.2 Production of zinc phosphate 18 3.2.1.2.3 Formulation and processing of zinc phosphate in paints 26 3.2.1.2.4 Measured local data in the environment 29 3.2.1.2.5 Summary of results for the local exposure assessment 29 3.3 Effects assessment 30 3.3.1 Aquatic and terrestrial compartment 30 3.3.2 Atmosphere 31 3.3.3 Secondary poisoning 31 3.4 Risk characterisation 32 3.4.1 General 32 3.4.2 Local risk characterisation 36 3.4.2.1 Aquatic compartment 36 3.4.2.1.1 STP effluent 36 3.4.2.1.2 Surface water (incl. sediment) 36 3.4.2.2 Terrestrial compartment 37 3.4.2.3 Atmospheric compartment 38 3.4.2.4 Secondary poisoning 38 3.4.3 Regional risk characterisation 40 APPENDIX 3.4 BIOAVAILABILITY CORRECTIONS 42 3 CAS No.7779-90-0 R077_0805_env 4 REFERENCES 44 4 CAS No.7779-90-0 R077_0805_env 5 CAS No.7779-90-0 R077_0805_env 0 OVERALL CONCLUSIONS/RESULTS OF THE RISK ASSESSMENT CAS No. 7779-90-0 EINECS No. 231-944-3 IUPAC Name Trizinc bis(ortho)phosphate ( ) i) There is need for further information and/or testing (X) ii) There is at present no need for further information and/or testing and for risk reduction measures beyond those which are being applied already (X) iii) There is a need for limiting the risks; risk reduction measures which are already being applied shall be taken into account (X) iii*) A conclusion applied to local scenarios in which the local scenario merits conclusion (ii) but where (possibly) due to high regional background concentrations a local risk cannot be excluded. LOCAL Conclusion (ii) is drawn for all local scenarios, including secondary poisoning, except those listed below. Conclusion iii) or iii*) is drawn for the specified scenarios, because: STP • the PECSTP exceeds the PNECadd for microorganisms in three processing scenarios listed in Table 3.4.10 (conclusion iii). Surface water • the Clocaladd in water exceeds the PNECadd for surface water in a number of processing scenarios listed in Table 3.4.10 (conclusion iii). Sediment • the Clocaladd / PNECadd ratio is larger than 1 for a number of processing scenarios listed in Table 3.4.10 (conclusion iii). For the production sites and remaining processing scenarios listed in Table 3.4.10 the Clocaladd / PNECadd ratio is <1, but a potential risk at local scale cannot be excluded due to the possible existence of high regional background concentrations (conclusion iii*). Soil • one processing scenario listed in Table 3.4.10 resulted in a PECadd / PNECadd ratio >1 (conclusion iii). 6 CAS No.7779-90-0 R077_0805_env REGIONAL The regional risk characterisation is discussed in the RAR on Zinc Metal. 7 CAS No.7779-90-0 R077_0805_env 8 CAS No.7779-90-0 R077_0805_env 1 GENERAL SUBSTANCE INFORMATION 1.1 IDENTIFICATION OF THE SUBSTANCE CAS-No.: 7779-90-0 EINECS-No.: 231-944-3 IUPAC name: trizinc bis(orthophosphate) Synonyms: zinc phosphate; zinc orthophosphate; phosphoric acid-zinc salt Molecular formula: Zn3(PO4)2 · 2-4H2O Structural formula: Zn3(PO4)2 · 2-4H2O Molecular weight: 458.14 Purity/impurities, additives Purity: no data Impurity: <0-4.5% zinc oxide, typical <100 ppm lead, <100 ppm cadmium Additives: none Physico-chemical properties In table 1A the physico-chemical properties are summarized. Table 1A Physico-chemical properties of zinc phosphate Property Result Comment Physical state solid, powder Melting point 900 ºC * Boiling point not applicable **** Relative density 3.3 at 20 ºC ** Vapour pressure not applicable **** Surface tension not applicable **** Water solubility very slightly soluble - insoluble * Solubility in other solvents soluble in acids and NH4OH; insoluble in alcohol *** Partition coefficient no data **** n-octanol/water(log value) 9 CAS No.7779-90-0 R077_0805_env Property Result Comment Flash point not flammable **** Flammability not flammable **** Autoflammability temperature not applicable **** Explosive properties not explosive **** Oxidizing properties not oxidizing **** * More than one apparently independent source. No methods are specified. ** Several values found in literature. The value presented is considered as most appropriate. *** One source **** Conclusion based on theoretical, and/or structural considerations. These data are mainly derived from CRC Handbook of Chemistry and Physics (1995), Römpp Chemie Lexikon (1995), and company MSDS's. For an extended description see HEDSET. Conclusion: Data on boiling point and partition coefficient were not provided. In view of the nature of the substance determination of these parameters is considered to be irrelevant. Vapour pressure and surface tension are reported to be not applicable. This is correct based on theoretical considerations. Information on flammability, explosive properties and oxidizing properties is not available. However, on theoretical considerations the compound is concluded to be not flammable, not explosive and not oxidizing. All other required physico-chemical data were submitted. None of these data is based on test results, substantiated with reports. However, the data are considered as sufficiently reliable to fulfil the Annex VIIA requirements. 1.2 ENVIRONMENTAL CLASSIFICATION AND LABELLING OF ZINC PHOSPHATE 1.2.1 Introduction For a general introduction on the classification and labelling of metals, the reader is referred to sections 1.2.1 and 1.2.2 of the risk assessment report on zinc metal. 1.2.2 Test results water solubility and aquatic toxicity The results of Heubach (1996) indicate a water solubility of ±10, ±100 and >1000 mg dissolved Zn/l at pH 8, 7 and 6, respectively. These summarised results of the Heubach-study (1996) will be used for classification. 10 CAS No.7779-90-0 R077_0805_env There are no short-term toxicity data available for zinc phosphate. The water solubility of zinc phosphate will be related to the L(E)C50-values of zinc chloride or zinc sulphate for classification. This classification approach is described in the testing strategy document (ECBI/61/95-Add 51-Rev. 4) and summarised in the diagram 1.1/2 in section 1.2.2 of the risk assessment report on zinc metal (RAR Zinc metal). The L(E)C50 values of the soluble zinc salts are presented in Table 1.2 (section 1.3.2.2) of the zinc metal report. The selected values for Daphnia magna, Oncorhynchus mykiss and Selenastrum capricornutum are a 48-hour EC50 of 0.07 mg/l, a 96-hour LC50 of 0.14 mg/l and a 72-hour EC50 of 0.14 mg/l, respectively. 1.2.3 Conclusion The water solubility of zinc phosphate exceeds the lowest L(E)C50 values for Daphnia magna, algae and fish. Zinc phosphate has thus been classified with N R50-R53. This classification for zinc phosphate has been included in Annex I of the EU-Directive 67/548/EC, see below. Classification and labelling (human health, environment and physico-chemical) Annex 1 of Directive 67/548/EEC contains a list of harmonised classifications and labellings for substances or groups of substances, which are legally binding within the EU. For zinc phosphate the current Annex 1 classification and labelling (29th ATP, 2004) is as follows: Classification N; R50-53 Labelling N; R50/53 S60-61 11 CAS No.7779-90-0 R077_0805_env 2 GENERAL INFORMATION ON EXPOSURE 2.1 PRODUCTION The zinc phosphate production sites in the European Union with a volume of more than 1000 t/y are presented in Table 2.1.1.
Load more

Recommended publications
  • A Practical Guide to the Use of Luting Cements a Peer-Reviewed Publication Written by John O
    Earn 4 CE credits This course was written for dentists, dental hygienists, and assistants. 1992 1850s Early 1900s 1972 Resin- Zinc oxide 1900s Zinc Glass modified eugenol Zinc poly- ionomers glass phosphate carboxylate ionomers Early 2000s Self- adhesive cements A Practical Guide To The Use Of Luting Cements A Peer-Reviewed Publication Written by John O. Burgess, DDS, MS and Taneet Ghuman, BDS PennWell is an ADA CERP Recognized Provider Go Green, Go Online to take your course This course has been made possible through an unrestricted educational grant. The cost of this CE course is $59.00 for 4 CE credits. Cancellation/Refund Policy: Any participant who is not 100% satisfied with this course can request a full refund by contacting PennWell in writing. Educational Objectives a clinical success. The first change increased the strength Overall goal: The purpose of this article is to provide dental of the mixed material, allowing it to be used for permanent professionals with information on the selection and applica- cementation, and the second produced an easy-to-mix tion of luting cements. paste-paste system for provisional cementation that is still Upon completion of this course, the clinician will be able in use today.2,3 While the cement had an obtunding effect to do the following: on pulp, its disadvantages, including a high film thickness, 1. List the types of luting cements and their chemical have limited its use.4 The physical properties of dental ce- composition. ments appear in Table 1. 2. List the physical properties that affect the performance of luting cements.
    [Show full text]
  • Dictionary of Geology and Mineralogy
    McGraw-Hill Dictionary of Geology and Mineralogy Second Edition McGraw-Hill New York Chicago San Francisco Lisbon London Madrid Mexico City Milan New Delhi San Juan Seoul Singapore Sydney Toronto All text in the dictionary was published previously in the McGRAW-HILL DICTIONARY OF SCIENTIFIC AND TECHNICAL TERMS, Sixth Edition, copyright ᭧ 2003 by The McGraw-Hill Companies, Inc. All rights reserved. McGRAW-HILL DICTIONARY OF GEOLOGY AND MINERALOGY, Second Edi- tion, copyright ᭧ 2003 by The McGraw-Hill Companies, Inc. All rights reserved. Printed in the United States of America. Except as permitted under the United States Copyright Act of 1976, no part of this publication may be reproduced or distributed in any form or by any means, or stored in a database or retrieval system, without the prior written permission of the publisher. 1234567890 DOC/DOC 09876543 ISBN 0-07-141044-9 This book is printed on recycled, acid-free paper containing a mini- mum of 50% recycled, de-inked fiber. This book was set in Helvetica Bold and Novarese Book by the Clarinda Company, Clarinda, Iowa. It was printed and bound by RR Donnelley, The Lakeside Press. McGraw-Hill books are available at special quantity discounts to use as premi- ums and sales promotions, or for use in corporate training programs. For more information, please write to the Director of Special Sales, McGraw-Hill, Professional Publishing, Two Penn Plaza, New York, NY 10121-2298. Or contact your local bookstore. Library of Congress Cataloging-in-Publication Data McGraw-Hill dictionary of geology and mineralogy — 2nd. ed. p. cm. “All text in this dictionary was published previously in the McGraw-Hill dictionary of scientific and technical terms, sixth edition, —T.p.
    [Show full text]
  • The Mineralogical Magazine
    THE MINERALOGICAL MAGAZINE AND JOUR1VAL OF THE MINERALOGICAL SOCIETY. No. 68. April, 1908. Vol. XV. On Hopeite and other zinc phosphates and associated minerals from the Broken Hill mines, North-Western .Rhodesia. By L. J. SrENC~R, M.A., F.G.S. Assistant in the Mineral Department of the :British Museum. [Read November 12, 1907.] HE new and remarkable mineral locality known as Rhodesia T Broken Hill is situated in NorLh-Western Rhodesla, at a distance of about 800 miles to tile north-east of tile Victoria Falls, and at tlw present terminus of the Cape to Cairo ]{ailway. The outcrop of lead and zinc ore which occurs here was accidentally discovered in January, 1902, by Mr. T. G. Davey, while he was prospecti,g the country for copper, l~ising out of the flat surrounding country is a series of low hills or kopjes, the largest of them being about 90 feet in height ; and these consist almost entirely of oxidized ore. The surrounding rocks are mainly crystalline limestones with some beds of sandstone, conglomerate, and phyllite. The ordinary type of ore of which the kopjes consist is compact and of a light yellowish colour. It is composed of an intimate intermixture of zinc silicate (hemimorphite) and lead carbonate (eerussitc) with variable amounts of interspersed iron hydroxide (llmonite). Crystal-lined cavities are of frequent occurrence in this ore. In the work of explora- tion, one of the tunnels driven through Kopje No. 1 broke into a large cavern, measuring about 24 x 80 feet. In this cave were found bones of recent animals, together with stone implements and other evidences of B 2 L, J.
    [Show full text]
  • Dietary Zinc
    NTP TECHNICAL REPORT ON THE TOXICOLOGY AND CARCINOGENESIS STUDY OF DIETARY ZINC (CAS NO. 5263-02-5) IN SPRAGUE DAWLEY RATS (Hsd:Sprague Dawley SD) (FEED STUDY) Scheduled Peer Review Date: July 13, 2017 NOTICE This DRAFT Technical Report is distributed solely for the purpose of predissemination peer review under the applicable information quality guidelines. It has not been formally disseminated by the NTP. It does not represent and should not be construed to represent NTP determination or policy. NTP TR 592 National Toxicology Program National Institutes of Health Public Health Service U.S. DEPARTMENT OF HEALTH AND HUMAN SERVICES FOREWORD The National Toxicology Program (NTP) is an interagency program within the Public Health Service (PHS) of the Department of Health and Human Services (HHS) and is headquartered at the National Institute of Environmental Health Sciences of the National Institutes of Health (NIEHS/NIH). Three agencies contribute resources to the program: NIEHS/NIH, the National Institute for Occupational Safety and Health of the Centers for Disease Control and Prevention (NIOSH/CDC), and the National Center for Toxicological Research of the Food and Drug Administration (NCTR/FDA). Established in 1978, the NTP is charged with coordinating toxicological testing activities, strengthening the science base in toxicology, developing and validating improved testing methods, and providing information about potentially toxic substances to health regulatory and research agencies, scientific and medical communities, and the public. The Technical Report series began in 1976 with carcinogenesis studies conducted by the National Cancer Institute. In 1981, this bioassay program was transferred to the NTP. The studies described in the Technical Report series are designed and conducted to characterize and evaluate the toxicologic potential, including carcinogenic activity, of selected substances in laboratory animals (usually two species, rats and mice).
    [Show full text]
  • Surface Pretreatment by Phosphate Conversion Coatings – a Review
    130Rev.Adv.Mater.Sci. 9 (2005) 130-177 T.S.N. Sankara Narayanan SURFACE PRETREATMENT BY PHOSPHATE CONVERSION COATINGS A REVIEW T.S.N. Sankara Narayanan National Metallurgical Laboratory, Madras Centre CSIR, Complex, Taramani, Chennai-600 113, India Received: April 22, 2005 Abstract. Phosphating is the most widely used metal pretreatment process for the surface treatment and finishing of ferrous and non-ferrous metals. Due to its economy, speed of opera- tion and ability to afford excellent corrosion resistance, wear resistance, adhesion and lubricative properties, it plays a significant role in the automobile, process and appliance industries. Though the process was initially developed as a simple method of preventing corrosion, the changing end uses of phosphated articles have forced the modification of the existing processes and development of innovative methods to substitute the conventional ones. To keep pace with the rapid changing need of the finishing systems, numerous modifications have been put forth in their development - both in the processing sequence as well as in the phosphating formulations. This review addresses the various aspects of phosphating in detail. In spite of the numerous modifications put forth on the deposition technologies to achieve different types of coatings and desirable properties such as improved corrosion resistance, wear resistance, etc., phosphate conversion coating still plays a vital part in the automobile, process and appliance industries. Contents 3.5.3. Phosphating 1. Introduction 3.5.4. Rinsing after phosphating 2. Chemical conversion coatings 3.5.5. Chromic acid sealing 3. Phosphating 3.5.6. Drying 3.1. History and development of the 3.6.
    [Show full text]
  • Impact of Zinc Orthophosphate Inhibitor on Distribution System Water Quality
    University of Central Florida STARS Electronic Theses and Dissertations, 2004-2019 2007 Impact Of Zinc Orthophosphate Inhibitor On Distribution System Water Quality Xiaotao Guan University of Central Florida Part of the Environmental Engineering Commons Find similar works at: https://stars.library.ucf.edu/etd University of Central Florida Libraries http://library.ucf.edu This Doctoral Dissertation (Open Access) is brought to you for free and open access by STARS. It has been accepted for inclusion in Electronic Theses and Dissertations, 2004-2019 by an authorized administrator of STARS. For more information, please contact [email protected]. STARS Citation Guan, Xiaotao, "Impact Of Zinc Orthophosphate Inhibitor On Distribution System Water Quality" (2007). Electronic Theses and Dissertations, 2004-2019. 3184. https://stars.library.ucf.edu/etd/3184 IMPACT OF ZINC ORTHOPHOSPHATE INHIBITOR ON DISTRIBUTION SYSTEM WATER QUALITY by XIAOTAO GUAN B.S. Beijing University of Technology, 2001 M.S. Beijing University of Technology, 2004 A dissertation submitted in partial fulfillment of the requirements for the degree of Doctor of Philosophy in the Department of Civil and Environmental Engineering in the College of Engineering and Computer Science at the University of Central Florida Orlando, Florida Fall Term 2007 Advisor: James S. Taylor © 2007 Xiaotao Guan ii ABSTRACT This dissertation consists of four papers concerning impacts of zinc orthophosphate (ZOP) inhibitor on iron, copper and lead release in a changing water quality environment. The mechanism of zinc orthophosphate corrosion inhibition in drinking water municipal and home distribution systems and the role of zinc were investigated. Fourteen pilot distribution systems (PDSs) which were identical and consisted of increments of PVC, lined cast iron, unlined cast iron and galvanized steel pipes were used in this study.
    [Show full text]
  • Zinc Phosphate Cement
    2019 Self-Study Course #2 Course Course Instructions: . Read and review the course materials. Complete the 8 question test. A total of 6 questions must be answered correctly for credit. Submit your answers online at: http://dentistry.osu.edu/sms- Frequently Asked Contact Us: continuing-education Questions: . Check your email for your CE Q: Who can earn FREE CE credits? Phone certification of completion (please check your junk/spam 614-292-6737 A: EVERYONE - All dental professionals folder as well). in your office may earn free CE credits. Each person must read the course Toll Free materials and submit an online answer 1-888-476-7678 About SMS CE courses: form independently. TWO CREDIT HOURS are issued Q: Where can I find my SMS number? Fax for successful completion of this self-study course for the OSDB A: Your SMS number can be found in the 614-292-8752 2019-2021 biennium totals. upper right hand corner of your monthly reports, or, imprinted on the back of . CERTIFICATE of COMPLETION E-mail is used to document your CE your test envelopes. The SMS number is the account number for your office only, [email protected] credit and is emailed to each course participant. and is the same for everyone in the office. ALLOW 2 WEEKS for processing Web of your certificate. Q: How often are these courses dentistry.osu.edu/sms available? A: Four times per year (8 CE credits). The Ohio State University College of Dentistry is a recognized provider for ADA CERP credit. ADA CERP is a service of the American Dental Association to assist dental professionals in identifying quality providers of continuing dental education.
    [Show full text]
  • United States Patent (19) (11) 4,439,572 Kindrick 45 Mar
    United States Patent (19) (11) 4,439,572 Kindrick 45 Mar. 27, 1984 (54) ZINCOXIDE-ZINCSALT SMOKE 58) Field of Search ..................... 106/18.27; 524/399, SUPPRESSANT/FLAME RETARDANTS 524/405, 411, 417,420, 423, 432, 434, 472; 75) Inventor: Robert H. Kindrick, Grosse Ile, 523/210, 200, 205, 223 Mich. 56 References Cited (73) Assignee: The Sherwin-Williams Company, U.S. PATENT DOCUMENTS Cleveland, Ohio 2,785,990 3/1957 Coulter ....... 106/296 3,900,441 8/1975 King ... ... 524/406 (21) Appl. No.: 443,723 3,945,974 3/1976 Schwarcz et al. ... S24/409 3,957,723 5/1976 Lawson et al. ..................... 524/432 (22) Filed: Nov. 22, 1982 4,111,885 9/1978 Abu-Isa ............................... 524/405 Primary Examiner-Melvyn I. Marquis Attorney, Agent, or Firm-James W. Tura; Robert E. Related U.S. Application Data McDonald 63) Continuation-in-part of Ser. No. 315,336, Oct. 26, 1981, abandoned. 57 ABSTRACT This invention is directed to halogen-containing poly (51) Int. Cli................................................ CO8K 3/38 meric compositions containing a smoke suppressant/- (52) U.S.C. .................................... 524/405; 524/399; flame retardant comprising intimate mixtures of zinc 524/411; 524/417; 524/420; 524/423; 524/432; oxide and zinc salts. 524/434; 524/472; 523/200; 523/210; 523/205; 523/223; 106/18.27 13 Claims, No Drawings 4,439,572 1. 2 zinc oxide could be used to reduce cost at least as a ZINCOXIDE-ZINC SALT SMOKE partial if not a total replacement for these flame retar SUPPRESSANT/FLAME RETARDANTS dants or smoke suppressants, e.g.
    [Show full text]
  • SAFETY DATA SHEET HY-Bond Zinc Phosphate Cement LIQUID
    page 1/7 SAFETY DATA SHEET HY-Bond Zinc Phosphate Cement LIQUID Printing date: August 26, 2019 SCTION 1. Identification of the substance or mixture and of the supplier (Contd. on page0) 1.1 Product identifier Trade Name: HY-Bond Zinc Phosphate Cement "LIQUID" 1.2 Relevant identified uses of the substance or mixture and uses advised against Relevant identified uses: Dental material Uses advised against: No further data 1.3 Details of the supplier of the safety date sheet Company/Undertaking identification Manufacturer's Name: SHOFU DENTAL CORPORATION Address: 1225 Stone Drive, San Marcos, CA 92078 USA Toll Free: 1-800-827-4638 Phone: 760-736-3277 Fax: 760-736-3276 E-Mail: [email protected] Section in Charge: Quality Management & Regulatory Affairs 1.4 Emergency Telephone Number For emergencies only. Call CHEMTREC: +1 703-741-5970 / 1-800-424-9300 (24 hours) SCTION 2. Hazards identification 2.1 GHS Classification HEALTH HAZARDS ACUTE TOXICITY-ORAL Category 4 SKIN CORROSION/IRRITATION Category 1A EYE DAMAGE/IRRITATION Category 1 SPECIFIC TARGET ORGAN SYSTEMIC TOXICITY (SINGLE EXPOSURE) Category 2 (systemic toxicity) Category 3 (respiratory tract irritation) SPECIFIC TARGET ORGAN SYSTEMIC TOXICITY (REPEATED EXPOSURE) Category 2 (lung) ENVIRONMENTAL HAZARD HAZARDOUS TO THE AQUATIC ENVIRONMENT-ACUTE HAZARD Category 2 HAZARDOUS TO THE AQUATIC ENVIRONMENT-CHRONIC HAZARD Category 2 The thing without mention is out of a classification object. Or cannot classify it. 2.2 Label elements SYMBOL GHS05 GHS07 GHS08 GHS09 Version Number 9 Revision date: August 9, 2019 page 2/7 SAFETY DATA SHEET HY-Bond Zinc Phosphate Cement LIQUID Printing date: August 26, 2019 SIGNAL WORD Danger HAZARD STATEMENTS Harmful if swallowed Causes severe skin burns and eye damage May cause respiratory irritation May cause damage to organs (systemic toxicity) May cause damage to organs through prolonged or repeated exposure (lung) Toxic to aquatic life with long lasting effects PRECAUTIONARY STATEMENTS [Prevention] Obtain special instruction before use.
    [Show full text]
  • Toxicological Profile for Zinc
    ZINC 119 4. CHEMICAL AND PHYSICAL INFORMATION 4.1 CHEMICAL IDENTITY Information concerning the chemical identity of elemental zinc and zinc compounds is listed in Table 4-1. Zinc is a naturally occurring element found in the earth=s surface rocks. Because of its reactivity, zinc metal is not found as the free element in nature. There are approximately 55 mineralized forms of zinc. The most important zinc minerals in the world are sphalerite (ZnS), smithsonite (ZnCO3), and hemimorphite (Zn4Si2O7(OH2)H2O). Zinc appears in Group IIB of the periodic table and has two common oxidation states, Zn(0) and Zn(+2). Zinc forms a variety of different compounds, such as zinc chloride, zinc oxide, and zinc sulfate (Goodwin 1998; Ohnesorge and Wilhelm 1991; WHO 2001). 4.2 PHYSICAL AND CHEMICAL PROPERTIES Information regarding the physical and chemical properties of elemental zinc and zinc compounds is located in Table 4-2. Zinc is a lustrous, blue-white metal that burns in air with a bluish-green flame. It is stable in dry air, but upon exposure to moist air, it becomes covered with a film of zinc oxide or basic carbonate (e.g., 2ZnCO3·3Zn(OH)2) isolating the underlying metal and retarding further corrosion. Bonding in zinc compounds tends to be covalent, as in the sulfide and oxide (Goodwin 1998). In solution, four to six ligands can be coordinated with the zinc ion. Zinc has a strong tendency to react with acidic, alkaline, and inorganic compounds. Since zinc is amphoteric (i.e., capable of reacting chemically either as an acid 2- or a base), it also forms zincates (e.g., [Zn(OH)3H2O]- and [Zn(OH)4] ) (Goodwin 1998; Ohnesorge and Wilhelm 1991; WHO 2001).
    [Show full text]
  • Всички Цитати 1967 1968 1973
    Всички цитати • Звено: ( ИОНХ ) Институт по обща и неорганична химия • Година: 2015 ÷ 2015 Брой цитирани публикации: 810 Брой цитиращи източници: 2559 1967 1. Peshev, P, Bliznakov, G, Leyarovska, L. On the preparation of some chromium, molybdenum and tungsten borides. Journal of The Less-Common Metals, 13, 2, Elsevier, 1967, ISSN:00225088, DOI:doi:10.1016/0022-5088(67)90188-9, 241 - 247. SJR:1.091, ISI IF:2.999 Цитира се в: 1. Bedse, R.D, Sonber, J.K, Sairam, K, Murthy, T.S.R.Ch, Hubli, R.C. Processing and Characterization of CrB2-Based Novel Composites High Temperature Materials and Processes, 34 (7), pp. 683-687, 2015 1968 2. Peshev, P, Leyarovska, L, Bliznakov, G. On the borothermic preparation of some vanadium, niobium and tantalum borides. Journal of The Less-Common Metals, 15, 3, Elsevier, 1968, ISSN:00225088, DOI:doi:10.1016/0022-5088(68)90184-7, 259 - 267. SJR:1.091, ISI IF:2.999 Цитира се в: 2. Balci, Ö, Aʇaoʇullari, D, Ovali, D, Lütfi Öveçoʇlu, M, Duman, I. In situ synthesis of NbB2-NbC composite powders by milling-assisted carbothermal reduction of oxide raw materials Advanced Powder Technology, 26 (4), art. no. 1021, pp. 1200-1209, 2015 3. Peshev, P, Bliznakov, G. On the borothermic preparation of titanium, zirconium and hafnium diborides. Journal of The Less-Common Metals, 14, 1, Elsevier, 1968, ISSN:00225088, DOI:doi:10.1016/0022- 5088(68)90199-9, 23 - 32. SJR:1.091, ISI IF:2.999 Цитира се в: 3. Liu, J, Zhang, G. Recent research progress on ZrB2and HfB2-based ceramics China's Refractories, 24 (3), pp.
    [Show full text]
  • Safety Assessment of Zinc Salts As Used in Cosmetics
    Safety Assessment of Zinc Salts as Used in Cosmetics Status: Tentative Report for Public Comment Release Date: December 15, 2017 Panel Meeting Date: March 5-6, 2018 All interested persons are provided 60 days from the above date to comment on this safety assessment and to identify additional published data that should be included or provide unpublished data which can be made public and included. Information may be submitted without identifying the source or the trade name of the cosmetic product containing the ingredient. All unpublished data submitted to CIR will be discussed in open meetings, will be available at the CIR office for review by any interested party and may be cited in a peer-reviewed scientific journal. Please submit data, comments, or requests to the CIR Executive Director, Dr. Bart Heldreth. The 2017 Cosmetic Ingredient Review Expert Panel members are: Chair, Wilma F. Bergfeld, M.D., F.A.C.P.; Donald V. Belsito, M.D.; Ronald A. Hill, Ph.D.; Curtis D. Klaassen, Ph.D.; Daniel C. Liebler, Ph.D.; James G. Marks, Jr., M.D., Ronald C. Shank, Ph.D.; Thomas J. Slaga, Ph.D.; and Paul W. Snyder, D.V.M., Ph.D. The CIR Executive Director is Bart Heldreth, Ph.D. This safety assessment was prepared by Laura N. Scott, Scientific Writer/Analyst, and Monice Fiume, Senior Director. © Cosmetic Ingredient Review 1620 L Street, NW, Suite 1200 ♢ Washington, DC 20036-4702 ♢ ph 202.331.0651 ♢ fax 202.331.0088 ♢ [email protected] ABSTRACT The Cosmetic Ingredient Review (CIR) Expert Panel (Panel) assessed the safety of 27 inorganic and organometallic zinc salts as used in cosmetic formulations; these salts are specifically of the 2+ (II) oxidation state cation of zinc.
    [Show full text]