DOCSLIB.ORG

Zinc Ammonium Chloride Zac

Total Page:16

File Type:pdf, Size:1020Kb

Download full-text PDF Read full-text
Zinc Ammonium Chloride Zac ZINC AMMONIUM CHLORIDE ZAC CAUTIONARY RESPONSE INFORMATION 4. FIRE HAZARDS 7. SHIPPING INFORMATION 4.1 Flash Point: 7.1 Grades of Purity: Commercial Common Synonyms Solid White Odorless Not flammable 7.2 Storage Temperature: Ambient Ammonium pentachlorozincate 4.2 Flammable Limits in Air: Not flammable Ammonium zinc chloride 7.3 Inert Atmosphere: No requirement 4.3 Fire Extinguishing Agents: Not pertinent Sinks and mixes with water. 7.4 Venting: Open 4.4 Fire Extinguishing Agents Not to Be 7.5 IMO Pollution Category: Currently not available Keep people away. Avoid contact with solid and dust. Used: Not pertinent Notify local health and pollution control agencies. 4.5 Special Hazards of Combustion 7.6 Ship Type: Currently not available Protect water intakes. Products: Not pertinent 7.7 Barge Hull Type: Currently not available 4.6 Behavior in Fire: Currently not available Not flammable. Fire 4.7 Auto Ignition Temperature: Not pertinent 8. HAZARD CLASSIFICATIONS 4.8 Electrical Hazards: Not pertinent 8.1 49 CFR Category: ORM-E 4.9 Burning Rate: Not pertinent CALL FOR MEDICAL AID. 8.2 49 CFR Class: Not pertinent Exposure 4.10 Adiabatic Flame Temperature: Currently DUST 8.3 49 CFR Package Group: Not listed. Irritating to eyes, nose and throat. not available 8.4 Marine Pollutant: No If inhaled will cause coughing or difficult breathing. 4.11 Stoichometric Air to Fuel Ratio: Not If in eyes, hold eyelids open and flush with plenty of water. pertinent. 8.5 NFPA Hazard Classification: Not listed If breathing has stopped, give artificial respiration. 4.12 Flame Temperature: Currently not 8.6 EPA Reportable Quantity: 1000 pounds If breathing is difficult, give oxygen. available 8.7 EPA Pollution Category: C 4.13 Combustion Molar Ratio (Reactant to 8.8 RCRA Waste Number: Not listed SOLID Product): Not pertinent. Irritating to skin and eyes. 8.9 EPA FWPCA List: Yes If swallowed will cause nausea and vomiting. 4.14 Minimum Oxygen Concentration for Remove contaminated clothing and shoes. Combustion (MOCC): Not listed Flush affected areas with plenty of water. 9. PHYSICAL & CHEMICAL PROPERTIES IF IN EYES, hold eyelids open and flush with plenty of water. 5. CHEMICAL REACTIVITY 9.1 Physical State at 15° C and 1 atm: Solid IF SWALLOWED and victim is CONSCIOUS, have victim drink water or milk and have victim induce vomiting. 5.1 Reactivity with Water: No reaction 9.2 Molecular Weight: 296.8 IF SWALLOWED and victim is UNCONSCIOUS OR HAVING CONVULSIONS, 5.2 Reactivity with Common Materials: 9.3 Boiling Point at 1 atm: (sublimes) 644°F = do nothing except keep victim warm. Currently not available 340°C = 613°K 5.3 Stability During Transport: Stable 9.4 Freezing Point: Not pertinent Effect of low concentrations on aquatic life is unknown. 9.5 Critical Temperature: Not pertinent Water May be dangerous if it enters water intakes. 5.4 Neutralizing Agents for Acids and Pollution Notify local health and wildlife officials. Caustics: Not pertinent 9.6 Critical Pressure: Not pertinent Notify operators of nearby water intakes. 5.5 Polymerization: Not pertinent 9.7 Specific Gravity: 1.81 at 20°C (solid) 5.6 Inhibitor of Polymerization: Not pertinent 9.8 Liquid Surface Tension: Not pertinent 9.9 Liquid Water Interfacial Tension: Not 6. WATER POLLUTION pertinent 1. CORRECTIVE RESPONSE ACTIONS 2. CHEMICAL DESIGNATIONS 9.10 Vapor (Gas) Specific Gravity: Not pertinent Dilute and disperse 6.1 Aquatic Toxicity: 2.1 CG Compatibility Group: Not listed. 9.11 Ratio of Specific Heats of Vapor (Gas): Stop discharge . Currently not available 2.2 Formula: ZnCl2 3NH4Cl 6.2 Waterfowl Toxicity: Currently not Not pertinent 2.3 IMO/UN Designation: Not listed available 2.4 DOT ID No.: 9154 9.12 Latent Heat of Vaporization: Not pertinent 2.5 CAS Registry No.: 52628-25-8 6.3 Biological Oxygen Demand (BOD): 9.13 Heat of Combustion: Not pertinent Currently not available 2.6 NAERG Guide No.: 171 9.14 Heat of Decomposition: Not pertinent 2.7 Standard Industrial Trade Classification: 6.4 Food Chain Concentration Potential: 9.15 Heat of Solution: Not pertinent 52329 Zinc accumulates in some organisms but is not considered to be bioconcentrative. 9.16 Heat of Polymerization: Not pertinent 3. HEALTH HAZARDS 6.5 GESAMP Hazard Profile: Not listed 9.17 Heat of Fusion: Currently not available 3.1 Personal Protective Equipment: Dust mask; goggles or face shield; protective gloves 9.18 Limiting Value: Currently not available 3.2 Symptoms Following Exposure: Inhalation of dust irritates nose and throat. Ingestion can cause 9.19 Reid Vapor Pressure: Currently not irritation or corrosion of the alimentary tract. Contact with eyes or skin causes irritation. available 3.3 Treatment of Exposure: INHALATION: remove from exposure; begin artificial respiration if breathing has ceased. INGESTION: induce vomiting, followed by prompt and complete gastric lavage, catharsis, and demulcents. EYES: flush with water for at least 15 min. SKIN: flush with water. NOTES 3.4 TLV-TWA: Not listed. 3.5 TLV-STEL: Not listed. 3.6 TLV-Ceiling: Not listed. 3.7 Toxicity by Ingestion: Grade 2; LD50 = 0.5-5 g/kg 3.8 Toxicity by Inhalation: Currently not available. 3.9 Chronic Toxicity: Currently not available 3.10 Vapor (Gas) Irritant Characteristics: Currently not available 3.11 Liquid or Solid Characteristics: Currently not available 3.12 Odor Threshold: Currently not available 3.13 IDLH Value: Not listed. 3.14 OSHA PEL-TWA: Not listed. 3.15 OSHA PEL-STEL: Not listed. 3.16 OSHA PEL-Ceiling: Not listed. 3.17 EPA AEGL: Not listed JUNE 1999 ZINC AMMONIUM CHLORIDE ZAC 9.20 9.21 9.22 9.23 SATURATED LIQUID DENSITY LIQUID HEAT CAPACITY LIQUID THERMAL CONDUCTIVITY LIQUID VISCOSITY Temperature Pounds per cubic foot Temperature British thermal unit per Temperature British thermal unit inch Temperature Centipoise (degrees F) (degrees F) pound-F (degrees F) per hour-square foot-F (degrees F) N N N N O O O O T T T T P P P P E E E E R R R R T T T T I I I I N N N N E E E E N N N N T T T T 9.24 9.25 9.26 9.27 SOLUBILITY IN WATER SATURATED VAPOR PRESSURE SATURATED VAPOR DENSITY IDEAL GAS HEAT CAPACITY Temperature Pounds per 100 pounds Temperature Pounds per square inch Temperature Pounds per cubic foot Temperature British thermal unit per (degrees F) of water (degrees F) (degrees F) (degrees F) pound-F V N N N E O O O R T T T Y P P P S E E E O R R R L T T T U I I I B N N N L E E E E N N N T T T JUNE 1999.
Load more

Recommended publications
  • 239 Subpart K—Indirect Discharge Point Sources
    Environmental Protection Agency § 414.111 BAT effluent limita- streams contain significant amounts of tions and NSPS 1 the pollutants identified above. Any such streams designated as metal or Effluent characteristics Maximum Maximum for cyanide bearing must be treated inde- for any monthly one day average pendently of other metal or cyanide bearing waste streams unless the con- 1,1,1-Trichloroethane ........................ 59 22 1,1,2-Trichloroethane ........................ 127 32 trol authority determines that the Trichloroethylene ............................... 69 26 combination of such streams, prior to Vinyl Chloride .................................... 172 97 treatment, with the Appendix A waste 1 All units are micrograms per liter. streams will result in substantial re- 2 Total Zinc for Rayon Fiber Manufacture that uses the vis- cose process and Acrylic Fibers Manufacture that uses the duction of these pollutants. This deter- zinc chloride/solvent process is 6,796 μg/l and 3,325 μg/l for mination must be based upon a review maximum for any one day and maximum for monthly average, respectively. of relevant engineering, production, and sampling and analysis information. [52 FR 42568, Nov. 5, 1987, as amended at 58 1 FR 36893, July 9, 1993] PSES and PSNS Maximum Effluent characteristics Maximum for any Subpart K—Indirect Discharge for any monthly Point Sources one day average Acenaphthene ................................... 47 19 SOURCE: 58 FR 36893, July 9, 1993, unless Anthracene ........................................ 47 19 otherwise noted. Benzene ............................................ 134 57 Bis(2-ethylhexyl) phthalate ................ 258 95 Carbon Tetrachloride ......................... 380 142 § 414.110 Applicability; description of Chlorobenzene .................................. 380 142 the subcategory of indirect dis- Chloroethane ..................................... 295 110 charge point sources. Chloroform ........................................
    [Show full text]
  • Zinc Chloride Catalyzed Multicomponent Synthesis of Pyrazolopyridocoumarin Scaffolds
    View metadata, citation and similar papers at core.ac.uk brought to you by CORE provided by ePrints@Bangalore University J. Chem. Sci. (2019) 131:29 © Indian Academy of Sciences https://doi.org/10.1007/s12039-019-1610-0 REGULAR ARTICLE Zinc chloride catalyzed multicomponent synthesis of pyrazolopyridocoumarin scaffolds DEVADAS SHAMALAa, KALEGOWDA SHIVASHANKARa,∗ , CHANDRAb and MADEGOWDA MAHENDRAb aP. G. Department of Chemistry, Bangalore University, Central College Campus, Bangalore, Karnataka 560 001, India bDepartment of Studies In Physics, Manasagangotri, University of Mysore, Mysore, Karnataka 570 006, India E-mail: [email protected] MS received 4 October 2018; revised 20 February 2019; accepted 27 February 2019; published online 22 March 2019 Abstract. An efficient synthesis of a series of pyrazolopyridocoumarins is reported by condensation of 4- hydroxycoumarin, benzaldehydes and 1-alkyl-5-amino-pyrazoles in the presence of 10 mol% zinc chloride in ethanol under reflux conditions through one-pot reaction. The significant attraction of this protocol is being a simple procedure, mild reaction condition, and excellent yield. The molecular structure of the compound (4e) is established by single crystal X-ray structure determination. Keywords. Coumarins; pyridine; pyrazole; zinc chloride; multicomponent reactions; one-pot synthesis. 1. Introduction have been developed for the preparation of pyra- zolopyridocoumarin derivatives with the use of various Multicomponent reactions (MCRs) efficiently combine catalysts such as n-tetrabutylammonium tribromide, 28 29 30 three or more reactants simultaneously in one pot that do Zn(OTf)2, glacial acetic acid, piperidine in acetic not need the isolation, purification and characterization acid, 31 and iodine. 19,32 However, these methodologies of intermediate products.
    [Show full text]
  • A Novel Strategy for the Manufacture of Idelalisib: Controlling the Formation
    RSC Advances View Article Online PAPER View Journal | View Issue A novel strategy for the manufacture of idelalisib: controlling the formation of an enantiomer† Cite this: RSC Adv.,2018,8, 15863 Nagaraju Mekala,ab Srinivasa Rao Buddepu,ab Sanjay K. Dehury,a Krishna Murthy V. R. Moturu, *a Sunil Kumar V. Indukuri,a Umamaheswara Rao Vasireddia and Atchuta R. Parimib A novel and scalable synthesis of 5-fluoro-3-phenyl-2-[(1S)-1-(9H-purin-6-ylamino)propyl]-4(3H)- Received 15th January 2018 quinazolinone, idelalisib 1, has been developed. This strategy controls the desfluoro impurity of 13 during Accepted 13th April 2018 reduction of nitro intermediate 4, and also arrests the formation of the enantiomer during cyclisation of DOI: 10.1039/c8ra00407b diamide 17, without affecting the neighbouring chiral centre. This process is demonstrated on a larger rsc.li/rsc-advances scale in the laboratory and achieved good chemical and chiral purities coupled with good yields. Introduction have received at least one prior therapy and as rst line treat- Creative Commons Attribution 3.0 Unported Licence. ment in the presence of 17p depletion. Quinazolinones are fused heterocyclic alkaloids and have As part of our research programme on the development of attracted many scientists working in organic and medicinal a series of anticancer drugs, herein we disclose a novel strategy chemistry due to their substantial and extensive range of ther- for the synthesis of idelalisib, 1. Our approach has resulted not apeutic activities. The remarkable therapeutic activities1 such as only in achieving almost total control of undesired enantiomer antiinammatory, anticonvulsant, antidiabetic, anticancer, of 1, but also enhanced the yields tremendously during the antitussive, antibacterial, analgesic, hypnotic, and sedative cyclisation step when compared to known related reports in the 5–7 activities coupled with exotic structural features have impelled literature.
    [Show full text]
  • Right to Know
    Right to Know Hazardous Substance Fact Sheet Common Name: ZINC CHLORIDE Synonyms: Butter of Zinc; Tinning Flux; Zinc Dichloride CAS Number: 7646-85-7 Chemical Name: Zinc Chloride (ZnCl2) RTK Substance Number: 2030 Date: December 2000 Revision: January 2010 DOT Number: UN 2331 Description and Use EMERGENCY RESPONDERS >>>> SEE LAST PAGE Zinc Chloride is an odorless, white, crystalline (sand-like) Hazard Summary granule or powder. It is used in soldering flux and iron Hazard Rating NJDOH NFPA galvanizing, as a screening smoke for crowd control and wood HEALTH 3 - preservative, and in making agricultural chemicals, FLAMMABILITY 0 - pharmaceuticals, and textiles. REACTIVITY 0 - CORROSIVE POISONOUS GASES ARE PRODUCED IN FIRE Reasons for Citation f Zinc Chloride is on the Right to Know Hazardous Substance List because it is cited by OSHA, ACGIH, DOT, Hazard Rating Key: 0=minimal; 1=slight; 2=moderate; 3=serious; 4=severe NIOSH, IRIS and EPA. f This chemical is on the Special Health Hazard Substance f Zinc Chloride can affect you when inhaled. List. f Zinc Chloride is a CORROSIVE CHEMICAL and contact can severely irritate and burn the skin and eyes with possible eye damage. f Exposure to Zinc Chloride can irritate the nose and throat. f Inhaling Zinc Chloride can irritate the lungs causing SEE GLOSSARY ON PAGE 5. coughing and/or shortness of breath. Higher exposures may cause a build-up of fluid in the lungs (pulmonary edema), a FIRST AID medical emergency, with severe shortness of breath. f Zinc Chloride can cause nausea, vomiting, diarrhea and Eye Contact abdominal pain. f Immediately flush with large amounts of water for at least 30 minutes, lifting upper and lower lids.
    [Show full text]
  • Growth and Characterization of a New Non-Linear Optical Crystal: Urea Thiourea Zinc Chloride
    Asian Journal of Chemistry Vol. 20, No. 7 (2008), 5067-5070 Growth and Characterization of a New Non-Linear Optical Crystal: Urea Thiourea Zinc Chloride G. MADHURAMBAL† and M. MARIAPPAN* Department of Chemistry, R.V.S. College and Technology Kallikuppam, Thiruvettakudi Post, Karaikal-609 609, India E-mail: [email protected]; [email protected] Urea thiourea zinc chloride (UTZC) a new semi-organic non-linear optical material has been synthesized. Single crystals of UTZC have been grown by slow evaporation of saturated aqueous solution at room temperature. The spectral bands have been compared with urea, thiourea, bis thiourea zinc chloride (BTZC). Key Words: Urea thiourea zinc chloride crystals, Non- linear optical material. INTRODUCTION Non-linear optics playing a vital role in the emerging photoelectronic technologies. New non-linear optical (NLO) frequency conversion materials have a significant impact on laser technology, optical communication and optical data storage. The search for new and efficient NLO materials has resulted in the development of a new class of materials called semi-organics. These materials have the potential for combining the high optical non- linearity and chemical flexibility of organic materials with the thermal stability and mechanical robustness of inorganic NLO materials1. Thiourea possess a large dipole moment and it forms a number of co-ordination compounds like bis thiourea cadmium chloride (BTCC)2 and tris thiourea zinc sulphate (ZTS)3, antimony thiourea bromide monohydrate (ATBM)4 which are potential materials for frequency doubling of the near IR laser radiation. Single crystals of these materials have very high laser damage threshold5. In general crystals of the type M[tu]2X2, where M = Cd, Co, Hg, Pb, Ti, Zn; tu = thiourea and X = halogen, have been found to exhibit good NLO proper- ties6.
    [Show full text]
  • SAFETY DATA SHEET 113690-Zinc Chloride
    SAFETY DATA SHEET (in accordance with Regulation (EU) 2015/830) 113690-Zinc chloride Version: 2 Page 1 of 9 Revision date: 20/04/2016 Print date: 20/04/2016 SECTION 1: IDENTIFICATION OF THE SUBSTANCE AND OF THE COMPANY/UNDERTAKING. 1.1 Product identifier. Product Name: Zinc chloride Product Code: 113690 Chemical Name: Zinc chloride Index No: 030-003-00-2 CAS No: 7646-85-7 EC No: 231-592-0 Registration No: 01-2119472431-44-XXXX 1.2 Relevant identified uses of the substance and uses advised against. For manufacturing, processing, laboratory or repacking use only Uses advised against: Uses other than those recommended. 1.3 Details of the supplier of the safety data sheet. Company: DC FINE CHEMICALS Ltd. Address: Hill Top, 88 City: NW11 6DY London (United Kingdom) Telephone: +44 (20) 7586 6800 Fax: +44 (20) 7504 1701 E-mail: [email protected] Web: www.dcfinechemicals.com 1.4 Emergency telephone number: (Only available during office hours) SECTION 2: HAZARDS IDENTIFICATION. 2.1 Classification of the substance. In accordance with Regulation (EU) No 1272/2008: Acute Tox. 4 : Harmful if swallowed. Aquatic Chronic 1 : Very toxic to aquatic life with long lasting effects. Skin Corr. 1B : Causes severe skin burns and eye damage. 2.2 Label elements. Labelling in accordance with Regulation (EU) No 1272/2008: Pictograms: -Continued on next page.- SAFETY DATA SHEET (in accordance with Regulation (EU) 2015/830) 113690-Zinc chloride Version: 2 Page 2 of 9 Revision date: 20/04/2016 Print date: 20/04/2016 P303+P361+P353 IF ON SKIN (or hair): Take off immediately all contaminated clothing.
    [Show full text]
  • Pyridines Using Catalytic Zinc Chloride Amanda L
    Tetrahedron Letters 48 (2007) 4079–4082 Multicomponent synthesis of imidazo[1,2-a]pyridines using catalytic zinc chloride Amanda L. Rousseau,* Pulane Matlaba and Christopher J. Parkinson Discovery Chemistry, Biosciences, CSIR, Private Bag X2, Modderfontein 1645, South Africa Received 1 March 2007; revised 26 March 2007; accepted 4 April 2007 Available online 11 April 2007 Abstract—The novel use of zinc chloride to catalyze the one-pot, three component synthesis of imidazo[1,2-a]pyridines from a range of substrates using either conventional heating or microwave irradiation is described. This methodology affords a number of imidazo[1,2-a]pyridines in reasonable yields and short reaction times without any significant optimization of the reaction conditions. Ó 2007 Elsevier Ltd. All rights reserved. Imidazo[1,2-a]pyridines 1 and the related imidazo[1,2-a]- approach involves the coupling of 2-aminopyridines pyrimidines 2 (Fig. 1) have received significant atten- with a-halocarbonyl compounds.1 However, this tion from the pharmaceutical industry owing to their approach does not readily lend itself to a diversity interesting biological activities displayed over a broad oriented synthesis. range of therapeutic classes,1 exhibiting antibacterial,2 antifungal,3 antiviral,4 and anti-inflammatory5 proper- A more versatile approach uses a three component ties. They have also been shown to be selective cyclin coupling (3CC) involving the condensation of alde- dependant kinase inhibitors,6 GABA,7 and benzodiaze- hydes, 2-aminopyridine, and isocyanides (Scheme 1).10 8 pine receptor agonists, and bradykinin B2 receptor This robust approach allows for the preparation of a antagonists.9 Drug formulations containing imid- diverse range of products and suited our requirements azo[1,2-a]pyridines currently available on the market in the continuation of a synthetic program aimed at include alpidem 3 (anxiolytic), zolpidem 4 (hypnotic), kinase inhibitors.
    [Show full text]
  • Temperature Coefficient of Electrical Conductivity in the System Potassium Chloride - Zinc Chloride R
    Ames Laboratory ISC Technical Reports Ames Laboratory 12-1955 Temperature coefficient of electrical conductivity in the system potassium chloride - zinc chloride R. A. Fleming Iowa State College R. R. Duke Iowa State College Follow this and additional works at: http://lib.dr.iastate.edu/ameslab_iscreports Part of the Chemistry Commons, and the Physics Commons Recommended Citation Fleming, R. A. and Duke, R. R., "Temperature coefficient of electrical conductivity in the system potassium chloride - zinc chloride" (1955). Ames Laboratory ISC Technical Reports. 123. http://lib.dr.iastate.edu/ameslab_iscreports/123 This Report is brought to you for free and open access by the Ames Laboratory at Iowa State University Digital Repository. It has been accepted for inclusion in Ames Laboratory ISC Technical Reports by an authorized administrator of Iowa State University Digital Repository. For more information, please contact [email protected]. Temperature coefficient of electrical conductivity in the system potassium chloride - zinc chloride Abstract The hp ase diagram of the system KCl-ZnCl2 has been constructed. Values of specific onductc ivity and density have been determined at eight temperatures in the range 475-650°C. for a series of compositions covering the concentration range. From these data, equivalent conductivities were calculated. The et mperature coefficient of conductivity as expressed by the activation energy of ionic migration was calculated at four temperatures for each mixture. Keywords Ames Laboratory Disciplines Chemistry | Physics This report is available at Iowa State University Digital Repository: http://lib.dr.iastate.edu/ameslab_iscreports/123 UNCLASSIFIED ISC-686 Subject Category: CHEMISTRY 1Physical Sciences Readin~ Room UNITED STATES ATOMIC ENERGY COMMISSION TEMPERATURE COEFFICIENT OF ELECTRICAL CONDUCTIVITY IN THE SYSTEM POTASSIUM CHLORIDE- ZINC CHLORIDE By R.
    [Show full text]
  • Ionic Liquid Character of Zinc Chloride Hydrates Define Solvent
    Article pubs.acs.org/JPCB Ionic Liquid Character of Zinc Chloride Hydrates Define Solvent Characteristics that Afford the Solubility of Cellulose ‡ † † † ‡ Sanghamitra Sen, , Bradley P. Losey, Elijah E. Gordon, Dimitris S. Argyropoulos, † and James D. Martin*, † Department of Chemistry, North Carolina State University, Raleigh, North Carolina 27695-8204, United States ‡ Department of Forest Biomaterials, North Carolina State University, Raleigh, North Carolina 27695-8001, United States *S Supporting Information ABSTRACT: The recently described ionic liquid structure of the · three equivalent hydrate of zinc chloride (ZnCl2 RH2O, R =3, existing as [Zn(OH2)6][ZnCl4]) explains the solubility of cellulose in this medium. Only hydrate compositions in the narrow range of 3 − x < R <3+x with x ≈ 1 dissolve cellulose. Once dissolved, the cellulose remains in solution up to the R = 9 hydrate. Neutron diffraction and differential pair distribution function analysis of cellulose and model compound solutions (1 wt % cellulose in the R = 3 hydrate and 1 wt % ethanol in the R = 3 hydrate and the · ZnCl2 3 ethanol liquid) coupled with detailed solubility measure- ments suggest that cellulose solubility occurs via coordination of the primary OH to the hydrated zinc cation with ring hydroxyls forming part of a second coordination shell around the cation of the ionic liquid. ■ INTRODUCTION water present. Lu and Shen reported that when heated at 80 °C Cellulose is one of the most abundant natural polymers. With for about 2 h, the R = 3 zinc chloride hydrate dissolves 5.5 wt % extensive inter- and intramolecular hydrogen bonding between of bacterial cellulose, but neither the R = 2 or 4 hydrate 1,2 dissolves cellulose, though both were observed to swell the glycoside units of the polymer, it is insoluble in water and fi 23 ff most organic solvents, dramatically restricting commercial macromolecule, making a ne distribution.
    [Show full text]
  • Zinc Chloride
    SIGMA-ALDRICH sigma-aldrich.com SAFETY DATA SHEET Version 4.7 Revision Date 03/25/2014 Print Date 03/26/2014 1. PRODUCT AND COMPANY IDENTIFICATION 1.1 Product identifiers Product name : Zinc chloride Product Number : 229997 Brand : Aldrich Index-No. : 030-003-00-2 REACH No. : A registration number is not available for this substance as the substance or its uses are exempted from registration, the annual tonnage does not require a registration or the registration is envisaged for a later registration deadline. CAS-No. : 7646-85-7 1.2 Relevant identified uses of the substance or mixture and uses advised against Identified uses : Laboratory chemicals, Manufacture of substances 1.3 Details of the supplier of the safety data sheet Company : Sigma-Aldrich 3050 Spruce Street SAINT LOUIS MO 63103 USA Telephone : +1 800-325-5832 Fax : +1 800-325-5052 1.4 Emergency telephone number Emergency Phone # : (314) 776-6555 2. HAZARDS IDENTIFICATION 2.1 Classification of the substance or mixture GHS Classification in accordance with 29 CFR 1910 (OSHA HCS) Acute toxicity, Oral (Category 4), H302 Skin corrosion (Category 1B), H314 Serious eye damage (Category 1), H318 Acute aquatic toxicity (Category 1), H400 Chronic aquatic toxicity (Category 1), H410 For the full text of the H-Statements mentioned in this Section, see Section 16. 2.2 GHS Label elements, including precautionary statements Pictogram Signal word Danger Hazard statement(s) H302 Harmful if swallowed. H314 Causes severe skin burns and eye damage. H410 Very toxic to aquatic life with long lasting effects. Precautionary statement(s) P260 Do not breathe dust or mist.
    [Show full text]
  • Signature of Author
    NEW METHODS FOR THE FORMATION OF CARBON-CARBON BONDS VIA ORGANOMETALLIC COMPOUNDS by BRIAN SCOTT BRONK B.A. (High Honors), Colgate University (1989) SUBMITTED TO THE DEPARTMENT OF CHEMISTRY IN PARTIAL FULFILLMENT OF THE REQUIREMENTS FOR THE DEGREE OF DOCTOR OF PHILOSOPHY at the MASSACHUSETTS INSTITUTE OF TECHNOLOGY February 1995 © Massachusetts Institute of Technology, 1995 Signature of Author.. ........................................................... Department of Chemistry September 19, 1994 /' I . N 'N Certified by....................... ......... .. ........................................ Certifiedby Rick L. Danheiser Thesis Supervisor Certified by ......... ... ...................................... Stephen J. Lippard A Thesis Supervisor // . Accepted by.................. .................... /../.!.............................................. Dietmar Seyferth Departmental Committee on Graduate Studies I:;. .i., . : .1'_I_ , This doctoral thesis has been examined by a committee of the Department of Chemistry as follows: n An Professor Stephen L. Buchw ald ....... ............................. m L. BcChairman Professor Rick L. Danheiser . ................... Thesis Supervisor Professor Stephen J. Lippard ........... ........ .................... Thesis Supervisor Professor Dietmar Seyferth ............ .......... -.... 2 ACKNOWLEDGMENTS After writing a thesis totaling over 300 pages, the task of writing one final page would seem quite simple. Unfortunately, I am left with a single page to express my gratitude to :l who have made
    [Show full text]
  • Cellulose Aerogels Prepared from an Aqueous Zinc Chloride Salt Hydrate
    Carbohydrate Polymers 137 (2016) 642–649 Contents lists available at ScienceDirect Carbohydrate Polymers j ournal homepage: www.elsevier.com/locate/carbpol Cellulose aerogels prepared from an aqueous zinc chloride salt hydrate melt ∗ Maria Schestakow , Ilknur Karadagli, Lorenz Ratke German Aerospace Center – Institute of Materials Research, Linder Höhe, 51147 Köln, Germany a r t i c l e i n f o a b s t r a c t Article history: Monolithic cellulose aerogels are prepared using a salt hydrate melt based on cheap zinc chloride tetrahy- Received 20 May 2015 drate (ZnCl2·4H2O) that can be washed out of the wet gel-body by using common solvents such as water, Received in revised form 26 October 2015 ethanol, isopropanol or acetone. Cellulose aerogels with concentrations of 1–5 wt.% cellulose were pro- Accepted 30 October 2015 duced. These aerogels are characterized with respect to shrinkage, density and surface area as well as Available online 12 November 2015 mechanical properties and micro-structure via SEM. Cellulose aerogels regenerated in acetone show a 2 −1 specific surface area of around 340 m g being 60% higher than those regenerated in water. The onset Keywords: of irreversible plastic deformation under compressive load is around 0.8 MPa for acetone-regenerated Cellulose aerogel aerogels and thus a factor of two larger compared to ethanol regenerated ones. The Young’s modulus Zinc chloride depends almost linearly on the cellulose concentration which is observed for all regenerative fluids with Regenerative fluid Structure the exception of water. The results achieved are presented in light of the polarity and ability of solvation Stiffness of ZnCl2·4H2O in the regenerative fluids used.
    [Show full text]