DOCSLIB.ORG

IAEG™ AD-DSL Release Version 2.0 8/16/2017 * CAS Registry Number

Total Page:16

File Type:pdf, Size:1020Kb

Download full-text PDF Read full-text

Load more

IAEG™ AD-DSL Release Version 2.0 8/16/2017 Terms and Conditions of Use of the IAEG™ Aerospace and Defense Declarable Substances List (“AD-DSL”) This document is released for the purpose of establishing a standardized list for supplier materials declaration for the Aerospace & Defense industry. Any further distribution or use requires the written consent of IAEG in accordance with our copyright statement below. © 2017 IAEG® The International Aerospace Environmental Group® ("IAEG®") is the owner of this material. This material may not be used for any purpose other than that for which it is provided without the express written consent of IAEG®. IAEG® will accept no liability for any damages from any use of this material including without limitation any direct, indirect, incidental, special and consequential damages, loss of data, income, profit or goodwill, loss of or damage to property or claims of third parties. IAEG® reserves the right to add to, change or delete its content or any part thereof without notice. BY DOWNLOADING, COPYING OR OTHERWISE USING THE LICENSED MATERIALS, YOU ACKNOWLEDGE THAT YOU HAVE READ AND UNDERSTAND THIS AGREEMENT, AND ARE BOUND BY ITS TERMS. IF YOU CANNOT OR DO NOT AGREE TO BE BOUND BY THIS AGREEMENT, YOU AGREE NOT TO USE THE LICENSED MATERIALS IN ANY FORM, FOR ANY PURPOSE. AD-DSL Substance Groups Groups have been established for substances on the AD-DSL to allow requesting companies the flexibility in the selection of substances used in supplier materials declarations. The use of groups allows users of the AD-DSL to limit required supplier reporting to a smaller subset of the AD-DSL, according to the requestor’s need for information. Three groupings for the substances on the AD-DSL have been established: Group 1: Substances prohibited for presence/use in mixtures/materials or articles by regulatory requirements or that have been identified for prohibition or that will require authorization for its continued use. Group 2: Substances for which a regulatory requirement requires the disclosure, tracking or specific labelling (in addition to what is required by regulatory chemical hazard communication requirements) if present in supplied mixtures/materials or articles. Group 3: Substances that are regulated and have the potential to be prohibited or restricted or to likely have associated required disclosure requirements in the future. * CAS Registry Number is a Registered Trademark of the American Chemical Society. CAS recommends the verification of the CAS RNs through CAS Client Services. ©2015 International Aerospace Environmental Group™. All Rights Reserved. 1 IAEG™ AD-DSL Release Version 2.0 8/16/2017 Substance identification Change Log IAEG priority Date first Revision IAEG ID CAS EC Name Synonyms Group added date IAEG000001 1327-53-3 215-481-4 Diarsenic trioxide Arsenic trioxide 1 2015-03-17 2015-03-17 Arsenic Diarsenic IAEG000002 1303-28-2 215-116-9 pentoxide; 1 2015-03-17 2015-03-17 pentaoxide Arsenic oxide IAEG000003 15606-95-8 427-700-2 Triethyl arsenate 1 2015-03-17 2017-08-14 IAEG000004 7778-39-4 231-901-9 Arsenic acid 1 2015-03-17 2015-03-17 Trilead IAEG000005 3687-31-8 222-979-5 1 2015-03-17 2017-08-14 diarsenate IAEG000006 7778-44-1 231-904-5 Calcium arsenate 1 2015-03-17 2017-08-14 Cadmium Tricadmium IAEG000009 12006-15-4 234-484-1 1 2017-08-14 2017-08-14 arsenide diarsenide IAEG000021 7440-41-7 231-150-7 Beryllium (Be) 3 2015-03-17 2015-03-17 IAEG000022 1306-19-0 215-146-2 Cadmium oxide 1 2015-03-17 2017-08-14 Cadmium IAEG000023 10108-64-2 233-296-7 1 2015-03-17 2017-08-14 chloride Cadmium IAEG000024 1306-23-6 215-147-8 1 2015-03-17 2017-08-14 sulphide Cadmium IAEG000025 10124-36-4 233-331-6 1 2015-03-17 2017-08-14 sulphate Cadmium IAEG000026 31119-53-6 233-331-6 1 2015-03-17 2017-08-14 sulphate Cadmium IAEG000027 7790-79-6 232-222-0 1 2015-03-17 2017-08-14 fluoride IAEG000028 7440-43-9 231-152-8 Cadmium (Cd) 1 2015-03-17 2017-08-14 Cadmium IAEG000029 10325-94-7 233-710-6 Cadmium nitrate 1 2017-08-14 2017-08-14 dinitrate Cadmium dinitrate; Nitric IAEG000030 10022-68-1 233-710-6 Cadmium nitrate 1 2017-08-14 2017-08-14 acid, cadmium salt, tetrahydrate Cadmium IAEG000031 21041-95-2 244-168-5 1 2017-08-14 2017-08-14 hydroxide Cadmium IAEG000032 513-78-0 208-168-9 1 2017-08-14 2017-08-14 carbonate Cadmium IAEG000033 1306-25-8 215-149-9 1 2017-08-14 2017-08-14 telluride Cadmium zinc IAEG000034 8048-07-5 232-466-8 1 2017-08-14 2017-08-14 sulphide yellow Cadmium IAEG000035 58339-34-7 261-218-1 sulphoselenide 1 2017-08-14 2017-08-14 red * CAS Registry Number is a Registered Trademark of the American Chemical Society. CAS recommends the verification of the CAS RNs through CAS Client Services. ©2015 International Aerospace Environmental Group™. All Rights Reserved. 2 IAEG™ AD-DSL Release Version 2.0 8/16/2017 Substance identification Change Log IAEG priority Date first Revision IAEG ID CAS EC Name Synonyms Group added date Cadmium chloride phosphate IAEG000037 100402-53-7 309-489-8 1 2017-08-14 2017-08-14 (Cd5Cl(PO4)3), manganese- doped Dodecanoic acid, IAEG000038 101012-89-9 309-789-9 cadmium salt, 1 2017-08-14 2017-08-14 basic Octadecanoic IAEG000039 101012-93-5 309-794-6 acid, cadmium 1 2017-08-14 2017-08-14 salt, basic Octadecanoic acid, 12-hydroxy-, IAEG000040 101012-94-6 309-795-1 1 2017-08-14 2017-08-14 cadmium salt, basic Cadmium oxide (CdO), solid soln. with calcium oxide and IAEG000041 101356-99-4 309-896-0 1 2017-08-14 2017-08-14 titanium oxide (TiO2), praseodymium- doped Cadmium selenide (CdSe), solid soln. with cadmium IAEG000042 101357-00-0 309-897-6 sulphide, zinc 1 2017-08-14 2017-08-14 selenide and zinc sulphide, aluminium and copper-doped Cadmium selenide (CdSe), solid soln. with cadmium IAEG000043 101357-01-1 309-898-1 sulphide, zinc 1 2017-08-14 2017-08-14 selenide and zinc sulphide, copper and manganese- doped * CAS Registry Number is a Registered Trademark of the American Chemical Society. CAS recommends the verification of the CAS RNs through CAS Client Services. ©2015 International Aerospace Environmental Group™. All Rights Reserved. 3 IAEG™ AD-DSL Release Version 2.0 8/16/2017 Substance identification Change Log IAEG priority Date first Revision IAEG ID CAS EC Name Synonyms Group added date Cadmium selenide (CdSe), solid soln. with cadmium IAEG000044 101357-02-2 309-899-7 1 2017-08-14 2017-08-14 sulphide, zinc selenide and zinc sulphide, europium-doped Cadmium selenide (CdSe), solid soln. with cadmium IAEG000045 101357-03-3 309-900-0 sulphide, zinc 1 2017-08-14 2017-08-14 selenide and zinc sulphide, gold and manganese- doped Cadmium selenide (CdSe), solid soln. with cadmium IAEG000046 101357-04-4 309-901-6 sulphide, zinc 1 2017-08-14 2017-08-14 selenide and zinc sulphide, manganese and silver-doped Cadmium IAEG000047 10196-67-5 233-489-6 1 2017-08-14 2017-08-14 myristate Cadmium oxide (CdO), solid soln. with magnesium IAEG000048 102110-30-5 310-029-3 1 2017-08-14 2017-08-14 oxide, tungsten oxide (WO3) and zinc oxide Silicic acid, zirconium salt, IAEG000049 102184-95-2 310-077-5 cadmium 1 2017-08-14 2017-08-14 pigment- encapsulated Cadmium IAEG000050 10468-30-1 233-954-3 1 2017-08-14 2017-08-14 dioleate Cadmium IAEG000051 11112-63-3 234-342-9 1 2017-08-14 2017-08-14 selenide sulphide Barium cadmium IAEG000052 1191-79-3 214-740-9 1 2017-08-14 2017-08-14 tetrastearate * CAS Registry Number is a Registered Trademark of the American Chemical Society. CAS recommends the verification of the CAS RNs through CAS Client Services. ©2015 International Aerospace Environmental Group™. All Rights Reserved. 4 IAEG™ AD-DSL Release Version 2.0 8/16/2017 Substance identification Change Log IAEG priority Date first Revision IAEG ID CAS EC Name Synonyms Group added date Cadmium Cadmium IAEG000053 12014-14-1 234-593-4 1 2017-08-14 2017-08-14 titanium oxide titanium trioxide Cadmium Tricadmium IAEG000054 12014-28-7 234-595-5 1 2017-08-14 2017-08-14 phosphide diphosphide Antimony, Cadmium IAEG000055 12014-29-8 234-596-0 compound with 1 2017-08-14 2017-08-14 antimonide cadmium (2:3) Dicadmium IAEG000060 12214-12-9 235-392-4 1 2017-08-14 2017-08-14 selenide sulphide Cadmium zinc IAEG000062 12442-27-2 235-672-6 1 2017-08-14 2017-08-14 sulphide Cadmium IAEG000063 12626-36-7 235-724-8 1 2017-08-14 2017-08-14 selenide sulphide Cadmium IAEG000064 12656-57-4 235-758-3 sulphoselenide 1 2017-08-14 2017-08-14 orange Cadmium IAEG000065 1345-09-1 215-717-6 1 2017-08-14 2017-08-14 mercury sulphide Cadmium IAEG000072 13814-59-0 237-480-8 1 2017-08-14 2017-08-14 selenite Cadmium IAEG000083 14486-19-2 238-490-5 1 2015-03-17 2015-03-17 tetrafluoroborate Cadmium IAEG000109 2223-93-0 218-743-6 1 2017-08-14 2017-08-14 distearate Dimethylcadmiu IAEG000132 506-82-1 208-055-4 1 2017-08-14 2017-08-14 m Cadmium IAEG000136 543-90-8 208-853-2 1 2017-08-14 2017-08-14 di(acetate) IAEG000139 592-02-9 Cadmium, diethyl- 1 2017-08-14 2017-08-14 Naphthenic acids, IAEG000140 61789-34-2 263-053-0 1 2017-08-14 2017-08-14 cadmium salts Cadmium IAEG000184 7789-42-6 232-165-1 1 2017-08-14 2017-08-14 bromide Sulphuric acid, cadmium salt IAEG000187 7790-84-3 1 2017-08-14 2017-08-14 (1:1), hydrate (3:8) Cadmium IAEG000230 14312-00-6 238-252-0 1 2017-08-14 2017-08-14 chromate IAEG000234 542-83-6 208-829-1 Cadmium cyanide 1 2015-03-17 2017-08-14 IAEG000236 7790-80-9 232-223-6 Cadmium iodide 1 2017-08-14 2017-08-14 * CAS Registry Number is a Registered Trademark of the American Chemical Society.
Recommended publications
  • Retention Indices for Frequently Reported Compounds of Plant Essential Oils

    Retention Indices for Frequently Reported Compounds of Plant Essential Oils

    Retention Indices for Frequently Reported Compounds of Plant Essential Oils V. I. Babushok,a) P. J. Linstrom, and I. G. Zenkevichb) National Institute of Standards and Technology, Gaithersburg, Maryland 20899, USA (Received 1 August 2011; accepted 27 September 2011; published online 29 November 2011) Gas chromatographic retention indices were evaluated for 505 frequently reported plant essential oil components using a large retention index database. Retention data are presented for three types of commonly used stationary phases: dimethyl silicone (nonpolar), dimethyl sili- cone with 5% phenyl groups (slightly polar), and polyethylene glycol (polar) stationary phases. The evaluations are based on the treatment of multiple measurements with the number of data records ranging from about 5 to 800 per compound. Data analysis was limited to temperature programmed conditions. The data reported include the average and median values of retention index with standard deviations and confidence intervals. VC 2011 by the U.S. Secretary of Commerce on behalf of the United States. All rights reserved. [doi:10.1063/1.3653552] Key words: essential oils; gas chromatography; Kova´ts indices; linear indices; retention indices; identification; flavor; olfaction. CONTENTS 1. Introduction The practical applications of plant essential oils are very 1. Introduction................................ 1 diverse. They are used for the production of food, drugs, per- fumes, aromatherapy, and many other applications.1–4 The 2. Retention Indices ........................... 2 need for identification of essential oil components ranges 3. Retention Data Presentation and Discussion . 2 from product quality control to basic research. The identifi- 4. Summary.................................. 45 cation of unknown compounds remains a complex problem, in spite of great progress made in analytical techniques over 5.
  • Minutes of the IUPAC Chemical Nomenclature and Structure Representation Division (VIII) Committee Meeting Boston, MA, USA, August 18, 2002

    Minutes of the IUPAC Chemical Nomenclature and Structure Representation Division (VIII) Committee Meeting Boston, MA, USA, August 18, 2002

    Minutes of the IUPAC Chemical Nomenclature and Structure Representation Division (VIII) Committee Meeting Boston, MA, USA, August 18, 2002 Members Present: Dr Stephen Heller, Prof Herbert Kaesz, Prof Dr Alexander Lawson, Prof G. Jeffrey Leigh, Dr Alan McNaught (President), Dr. Gerard Moss, Prof Bruce Novak, Dr Warren Powell (Secretary), Dr William Town, Dr Antony Williams Members Absent: Dr. Michael Dennis, Prof Michael Hess National representatives Present: Prof Roberto de Barros Faria (Brazil) The second meeting of the Division Committee of the IUPAC Division of Chemical Nomenclature and Structure Representation held in the Great Republic Room of the Westin Hotel in Boston, Massachusetts, USA was convened by President Alan McNaught at 9:00 a.m. on Sunday, August 18, 2002. 1.0 President McNaught welcomed the members to this meeting in Boston and offered a special welcome to the National Representative from Brazil, Prof Roberto de Barros Faria. He also noted that Dr Michael Dennis and Prof Michael Hess were unable to be with us. Each of the attendees introduced himself and provided a brief bit of background information. Housekeeping details regarding breaks and lunch were announced and an invitation to a reception from the U. S. National Committee for IUPAC on Tuesday, August 20 was noted. 2.0 The agenda as circulated was approved with the addition of a report from Dr Moss on the activity on his website. 3.0 The minutes of the Division Committee Meeting in Cambridge, UK, January 25, 2002 as posted on the Webboard (http://www.rsc.org/IUPAC8/attachments/MinutesDivCommJan2002.rtf and http://www.rsc.org/IUPAC8/attachments/MinutesDivCommJan2002.pdf) were approved with the following corrections: 3.1 The name Dr Gerard Moss should be added to the members present listing.
  • C–H Arylation of Triphenylene, Naphthalene and Related Arenes Using Pd/C† Cite This: Chem

    C–H Arylation of Triphenylene, Naphthalene and Related Arenes Using Pd/C† Cite This: Chem

    Chemical Science View Article Online EDGE ARTICLE View Journal | View Issue C–H arylation of triphenylene, naphthalene and related arenes using Pd/C† Cite this: Chem. Sci.,2015,6,1816 Karl D. Collins, Roman Honeker,‡ Suhelen Vasquez-C´ espedes,´ ‡ Dan-Tam D. Tang and Frank Glorius* A highly selective arylation of a number of polyaromatic hydrocarbons (PAHs) with aryliodonium salts and Pd/C as the only reagent is reported. The first C–H functionalization of triphenylene is explored, and proceeds at the most sterically hindered position. This non-chelate assisted C–H functionalization Received 4th October 2014 extends the reactivity profile of Pd/C and provides controlled access to p-extended PAHs, an important Accepted 19th December 2014 aspect of work towards the preparation of nanographenes. Mechanistic studies suggest in situ formation DOI: 10.1039/c4sc03051f of catalytically active insoluble nanoparticles, and that the reaction likely proceeds via a Pd(0)/Pd(II) type www.rsc.org/chemicalscience reaction manifold. Creative Commons Attribution 3.0 Unported Licence. Introduction precedent for the direct arylation of larger PAHs is reported. Seminal work by Oi and Inoue reported an effective arylation of Pd/C has long been established as an efficient catalyst in phenanthrene and uoranthene with aryltin trichlorides.10 One hydrogenation and cross-coupling reactions.1 Although sup- example of phenanthrene arylation has also been reported by ported catalysts are formally heterogeneous in nature, studies of Shi.11 Important studies by the group of Itami demonstrated a Pd/C suggest it typically acts as a reservoir of homogeneous more general solution (Scheme 1) using prepared boroxines as active catalytic species, following leaching of palladium from coupling partners.7d 1c,1e,2 the support into the solution.
  • UV-Curable Coating Composition

    UV-Curable Coating Composition

    Europaisches Patentamt European Patent Office (fi) Publication number: 0 001 466 A1 Office europeen des brevets EUROPEAN PATENT APPLICATION 2y Application number: 78200215.8 © int. ci.*: C 09 D 3/49, C 08 F 299/00, C 08 F 2/50 §) Date of filing: 28.09.78 © Priority: 11.10.77 NL 7711121 Applicant: Akzo N.V., Ijssellaan 82, NL-6800 LS Arnhem (NL) (7g) Inventor: Noomen, Arie, Schoonoord 22, NL-2215 Ed @ Date of publication of application: 18.04.79 Voorhout (NL) Bulletin 79/8 Inventor: Wolters, Egbert, Potgieterstraat 21, NL-1053 XP Amsterdam (NL) @ Representative: Sieders, Rene et ai, P.O.Box 314, @ Designated Contracting States: BE DE FR GB NL SE NL-6800 AH Arnhem (NL) @ U.V.-curable coating composition. The invention relates to a coating composition which is curable under the influence of ultraviolet light and which comprises a U.V.-curable binder, a photoinitiator and as accelerator a tetrahydro-1,3-oxazine compound and/or an oxazolidine compound. The U.V.-curable binder is pref- erably an adduct containing at least one isocyanate group of a) an acrylic or methacrylic hydroxy ester having 5 to 20 carbon atoms and b) a polyisocyanate having 4 to 40 carbon atoms and 2 to 4 isocyanate groups. The invention relates to a coating composition which can be cured under the influence of ultraviolet light ;and is based on a U.V.-curable binder, a photoinitiator and a nitrogen-containing accelerator. In known com- positions useismade generally of an aromatic carbonyl compound as photoinitiator, and of an alkanolamine as accelerator.
  • Phamarcological Effects Produced by the Modifications in Isoxazole Moeities

    Phamarcological Effects Produced by the Modifications in Isoxazole Moeities

    Archana c. et al. / Asian Journal of Phytomedicine and Clinical Research. 4(1), 2016, 29 - 32. Review Article CODEN: AJPCFF ISSN: 2321 – 0915 Asian Journal of Phytomedicine and Clinical Research Journal home page: www.ajpcrjournal.com PHAMARCOLOGICAL EFFECTS PRODUCED BY THE MODIFICATIONS IN ISOXAZOLE MOEITIES C. Archana *1 , E. Akila 2, Priya john 3 1*Department of Pharmaceutical Chemistry, Prime College of Pharmacy, Palakkad, Kerala, India. 2Department of Pharmacognosy, Prime College of Pharmacy, Palakkad, Kerala, India. 3Department of Pharmacology, Prime College of Pharmacy, Palakkad, Kerala, India. ABSTRACT Isoxazole and its derivatives are an important class of heterocyclic compound displaying a broad spectrum of biological activities which have made them privileged structures. In the present work, attempts were made to identify leading isoxazole moieties as candidate drugs against many diseases. For example, isoxazole substituted 9-anilino acridine derivatives was found to have increased antioxidant activities. The molecular docking studies show a good correlation between their biological activities screened and auto dock binding free energy. These derivatives will encourage helping to design future anti cancer agents with higher therapeutic potential. Another example is isoxazole incorporated 2-quinolones to show increased antimicrobial and anti inflammatory activities. More importantly, various isoxazole derivatives greatly increase biological properties of the structure like anti-infective action, anticancer properties, anti-protozoal and mutagenic properties. A modification in their structures has offered a high degree of diversity that has proven useful for the development of new therapeutic agents having improved potency and lesser toxicity. In the present study of concise review, is provided on the activities of isoxazole and its derivatives which involve history, chemistry, different methods of synthesis of isoxazole with biological activities and docking studies.
  • Cyclobutane Derivatives in Drug Discovery

    Cyclobutane Derivatives in Drug Discovery

    Cyclobutane Derivatives in Drug Discovery Overview Key Points Unlike larger and conformationally flexible cycloalkanes, Cyclobutane adopts a rigid cyclobutane and cyclopropane have rigid conformations. Due to the ring strain, cyclobutane adopts a rigid puckered puckered conformation Offer ing advantages on (~30°) conformation. This unique architecture bestowed potency, selectivity and certain cyclobutane-containing drugs with unique pharmacokinetic (PK) properties. When applied appropriately, cyclobutyl profile. scaffolds may offer advantages on potency, selectivity and pharmacokinetic (PK) profile. Bridging Molecules for Innovative Medicines 1 PharmaBlock designs and Cyclobutane-containing Drugs synthesizes over 1846 At least four cyclobutane-containing drugs are currently on the market. cyclobutanes, and 497 Chemotherapy carboplatin (Paraplatin, 1) for treating ovarian cancer was cyclobutane products are prepared to lower the strong nephrotoxicity associated with cisplatin. By in stock. CLICK HERE to replacing cisplatin’s two chlorine atoms with cyclobutane-1,1-dicarboxylic find detailed product acid, carboplatin (1) has a much lower nephrotoxicity than cisplatin. On information on webpage. the other hand, Schering-Plough/Merck’s hepatitis C virus (HCV) NS3/4A protease inhibitor boceprevir (Victrelis, 2) also contains a cyclobutane group in its P1 region. It is 3- and 19-fold more potent than the 1 corresponding cyclopropyl and cyclopentyl analogues, respectively. Androgen receptor (AR) antagonist apalutamide (Erleada, 4) for treating castration-resistant prostate cancer (CRPC) has a spirocyclic cyclobutane scaffold. It is in the same series as enzalutamide (Xtandi, 3) discovered by Jung’s group at UCLA in the 2000s. The cyclobutyl- (4) and cyclopentyl- derivative have activities comparable to the dimethyl analogue although the corresponding six-, seven-, and eight-membered rings are slightly less 2 active.
  • Exam 1 (February 23, 2004) ID# ______

    Exam 1 (February 23, 2004) ID# ______

    Chemistry 211 Name ___________________________ Exam 1 (February 23, 2004) ID# ___________________________ 10 1. You desire to synthesize 3-ethyl-3-pentanol starting with an ester. (i) What would be the name of the ester, and what is the name for the Grignard reagent (e.g., methyl magnesium bromide)? (ii) For the carbons shown in the product, show plausible hydrocarbons that you could start with to produce the ester and the Grignard reagent (as in a retrosynthesis). 12 2. (i) Show the step-by-step process required to produce propyllithium, which requires a free radical reaction mechanism, . (ii) Show the complete reaction mechanism for reaction between propyllithium and the correct ketone to produce 3-propyl-3-pentanol. (iii) Propose a possible reaction mechanism by which dipropyl cuprate (Cu+ with two propyl groups attached) could react with ethyl bromide to produce a new hydrocarbon. (This is a thinking exercise! So, think! () 8 3. As mentioned in the text, diethyl ether, pentane, and 1-butanol have similar molar masses, but different physical properties. Boiling points are 35oC, 36oC, and 117oC, respectively. Their respective solubilities in water are 7.5g/100mL, insoluble, and 9g/100mL. (i) Draw structures for each of these compounds. (ii) Justify the observed boiling points and their solubilities. 16 4. Draw structures of the following compounds 2,3-heptanediol isopropyllithium benzylmagnesium bromide benzoic acid benzaldehylde dimethyl sulfide t-butyl methanoate dibutyl ketone 12 5. Alcohols can be oxidized to produce other compounds, and can be produced by reduction. For the reactions shown below, show the structure for the expected product (if reaction does not occur, state: No Reaction) when treated with the indicated oxidizing or reducing agents.
  • Polycyclic Aromatic Hydrocarbon Structure Index

    Polycyclic Aromatic Hydrocarbon Structure Index

    NIST Special Publication 922 Polycyclic Aromatic Hydrocarbon Structure Index Lane C. Sander and Stephen A. Wise Chemical Science and Technology Laboratory National Institute of Standards and Technology Gaithersburg, MD 20899-0001 December 1997 revised August 2020 U.S. Department of Commerce William M. Daley, Secretary Technology Administration Gary R. Bachula, Acting Under Secretary for Technology National Institute of Standards and Technology Raymond G. Kammer, Director Polycyclic Aromatic Hydrocarbon Structure Index Lane C. Sander and Stephen A. Wise Chemical Science and Technology Laboratory National Institute of Standards and Technology Gaithersburg, MD 20899 This tabulation is presented as an aid in the identification of the chemical structures of polycyclic aromatic hydrocarbons (PAHs). The Structure Index consists of two parts: (1) a cross index of named PAHs listed in alphabetical order, and (2) chemical structures including ring numbering, name(s), Chemical Abstract Service (CAS) Registry numbers, chemical formulas, molecular weights, and length-to-breadth ratios (L/B) and shape descriptors of PAHs listed in order of increasing molecular weight. Where possible, synonyms (including those employing alternate and/or obsolete naming conventions) have been included. Synonyms used in the Structure Index were compiled from a variety of sources including “Polynuclear Aromatic Hydrocarbons Nomenclature Guide,” by Loening, et al. [1], “Analytical Chemistry of Polycyclic Aromatic Compounds,” by Lee et al. [2], “Calculated Molecular Properties of Polycyclic Aromatic Hydrocarbons,” by Hites and Simonsick [3], “Handbook of Polycyclic Hydrocarbons,” by J. R. Dias [4], “The Ring Index,” by Patterson and Capell [5], “CAS 12th Collective Index,” [6] and “Aldrich Structure Index” [7]. In this publication the IUPAC preferred name is shown in large or bold type.
  • Electrooxidation Enables Highly Regioselective Dearomative Annulation of Indole and Benzofuran Derivatives

    Electrooxidation Enables Highly Regioselective Dearomative Annulation of Indole and Benzofuran Derivatives

    ARTICLE https://doi.org/10.1038/s41467-019-13829-4 OPEN Electrooxidation enables highly regioselective dearomative annulation of indole and benzofuran derivatives Kun Liu1, Wenxu Song1, Yuqi Deng1, Huiyue Yang1, Chunlan Song1, Takfaoui Abdelilah1, Shengchun Wang 1, Hengjiang Cong 1, Shan Tang1 & Aiwen Lei1* 1234567890():,; The dearomatization of arenes represents a powerful synthetic methodology to provide three-dimensional chemicals of high added value. Here we report a general and practical protocol for regioselective dearomative annulation of indole and benzofuran derivatives in an electrochemical way. Under undivided electrolytic conditions, a series of highly functio- nalized five to eight-membered heterocycle-2,3-fused indolines and dihydrobenzofurans, which are typically unattainable under thermal conditions, can be successfully accessed in high yield with excellent regio- and stereo-selectivity. This transformation can also tolerate a wide range of functional groups and achieve good efficiency in large-scale synthesis under oxidant-free conditions. In addition, cyclic voltammetry, electron paramagnetic resonance (EPR) and kinetic studies indicate that the dehydrogenative dearomatization annulations arise from the anodic oxidation of indole into indole radical cation, and this process is the rate- determining step. 1 College of Chemistry and Molecular Sciences, Institute for Advanced Studies (IAS), Wuhan University, Wuhan 430072, P. R. China. *email: aiwenlei@whu. edu.cn NATURE COMMUNICATIONS | (2020) 11:3 | https://doi.org/10.1038/s41467-019-13829-4 | www.nature.com/naturecommunications 1 ARTICLE NATURE COMMUNICATIONS | https://doi.org/10.1038/s41467-019-13829-4 reaking the aromatic systems of electron-rich arenes or fused indolines (Fig. 1a)39–44. Therefore, it is highly appealing to heteroarenes provides three-dimensional chemicals of high develop efficient approaches to allow for their preparation.
  • Chemistry for S5 Students Short Notes & Questions with Answers & And

    Chemistry for S5 Students Short Notes & Questions with Answers & And

    Chemistry for S5 students Short notes & questions with answers & and other questions to help S5 Students to revise Important Concepts: Chemical Reactions of Alkyl Halides The reaction can be broadly classified in two categories: (a) Nucleophilic substitution (b) Elimination reactions Nucleophilic substitution reactions: In this reaction a nucleophile, which is rich in electrons, attacks partial positive charge on the carbon atom bonded to halogen to replace the leaving group. Nucleophilic reactions proceed by two different mechanism: (a) Substitution nucleophilic bimolecular (SN2) (b) Substitution nucleophilic unirnolecular (SN1) The reaction follows second order kinetics No intermediate is formed. It usually requires a strong nucleophile. The order of reactivity followed as: Primary halide > Secondary halide > Tertiary halide It is carried out in polar protic solvents (water, Alcohol, acetic acid etc.). These reactions occur in two steps as shown above The order of leaving ability is: F- < Cl- < Br- < I- The order of reactivity is as shown below: Difference between E1 and E2 reaction mechanism: Attributes E1 E2 Rate law Depend on the concentration of Depends on the concentration of both substrate substrate and base Barrier Formation of carbocation None 3o>2o>> 1o Base Does not require strong base Requires strong base Stereochemistry Does not require stereochemistry Leaving group must be anti to hydrogen removed Some solved questions are given below: Question 1:Which is the correct increasing order of boiling points of the following compounds? 1-bromoethane, 1-bromopropane, 1-bromobutane, Bromobenzene (a) Bromobenzene < 1-bromobutane < 1-bromopropane < 1-bromoethane (b) Bromobenzene < 1-bromothane < 1-bromopropane < 1-bromobutane (c) 1-bromopropane < 1-bromobutane < 1-bromoethane < Bromobenzene (d) 1-bromoethane < 1-bromopropane < 1-bromobutane < Bromobenzene Solution 1: Boiling point increases with increase in size of hydrocarbon part for the same haloalkanes.
  • Benzofuran Synthesis Through Iodocyclization Reactions: Recent Advances

    Benzofuran Synthesis Through Iodocyclization Reactions: Recent Advances

    MOJ Bioorganic & Organic Chemistry Mini Review Open Access Benzofuran synthesis through iodocyclization reactions: recent advances Abstract Volume 1 Issue 7 - 2017 Recent advancements (2014-17) in the benzofuran synthesis through iodocyclization Saurabh Mehta have been summarized. The successful use of various iodinating agents, bases, additives Department of Applied Chemistry, Delhi Technological etc. make iodocyclization a versatile and efficient methodology. The methodology has University, India been applied for the synthesis of more complex benzofuran derivatives, and may open interesting avenues in the area of heterocyclic chemistry (Figure 1). Correspondence: Saurabh Mehta, Department of Applied O-LG Chemistry, Delhi Technological University, Bawana Road, Delhi, + O R1 I 1 2 110042 India, Tel +9188 0066 5868, R R Email [email protected], [email protected] R2 I Received: December 17, 2017 | Published: December 29, 2017 LG = H, Me or other Protecting group 1 R = H, Me, OMe, I, CO2Me, etc. R2 = H, aryl, alkyl, alkenyl, etc. Figure 1 Keywords: annulations, alkyne, benzofuran, iodocyclization, heterocycle Introduction derivatives were obtained in high yields (84%−100%) under mild conditions. The authors demonstrated that the choice of bis(2,4,6- Benzo[b]furan is a privileged heterocyclic scaffold. Several collidine)iodonium hexafluorophosphate [I(coll)2PF6] as the compounds containing this scaffold have interesting biological iodinating agent was necessary for the success of the reaction. Also, 1 activities, such as anti-cancer, anti-viral, anti-inflammatory, etc. Few the ethoxyethyl ether group acted as a protecting group as well as a 2 derivatives are even used as commercial drugs, such as Amiodarone, good leaving group.
  • Recent Advances in the Total Synthesis of Cyclobutane-Containing Natural Products Cite This: Org

    Recent Advances in the Total Synthesis of Cyclobutane-Containing Natural Products Cite This: Org

    Volume 7 | Number 1 | 7 January 2020 ORGANIC CHEMISTRY FRONTIERS rsc.li/frontiers-organic ORGANIC CHEMISTRY FRONTIERS View Article Online REVIEW View Journal | View Issue Recent advances in the total synthesis of cyclobutane-containing natural products Cite this: Org. Chem. Front., 2020, 7, 136 Jinshan Li,†a Kai Gao, †a Ming Bianb and Hanfeng Ding *a,c Complex natural products bearing strained cyclobutane subunits, including terpenoids, alkaloids and steroids, not only display fascinating architectures, but also show potent biological activities. Due to their unique structures as critical core skeletons in these molecules, a variety of new strategies for the con- Received 24th September 2019, struction of cyclobutane rings have greatly emerged during the last decade. In this review, we wish to Accepted 11th November 2019 summarize the recent progress in the cyclobutane-containing natural product synthesis with an emphasis DOI: 10.1039/c9qo01178a on disconnection tactics employed to forge the four-membered rings, aiming to provide a complement rsc.li/frontiers-organic to existing reviews. 1. Introduction stereoselectively, poses significant challenges in synthetic chemistry. On the other hand, cyclobutanes readily undergo a In the class of strained carbocycles, cyclobutanes have been number of ring-opening reactions by virtue of their tendency known as intriguing structural motifs for more than one to release inherent strain energies. In some cases, however, century but remained relatively less explored in parallel with striking ring strains can be dramatically reduced by the instal- their homologues.1 Due to the highly strained ring systems (ca. lation of a gem-dialkyl substituent (through the Thorpe–Ingold − 26.7 kcal mol 1), construction of cyclobutane rings, especially effect),2 a carbonyl group, a heteroatom, or other functional- ities (Fig.