DOCSLIB.ORG

The Effect of Copper on Rust Mite Control with Four

Total Page:16

File Type:pdf, Size:1020Kb

Download full-text PDF Read full-text
The Effect of Copper on Rust Mite Control with Four 84 FLORIDA STATE HORTICULTURAL SOCIETY, 1960 THE EFFECT OF COPPER ON RUST MITE CONTROL WITH FOUR RUST MITE MITICIDES Alfred, Florida during 1959. In both experi Roger B. Johnson ments brushing sprays were applied after Florida Citrus Experiment Station bloom and again in the summer using con ventional equipment and methods previously Lake Alfred described by Johnson (5). Treatments were evaluated for effective In 1957, Johnson, King and McBride (1) ness against citrus rust mite by frequent reported that zineb (zinc ethylene-bis-dithio- determinations of the density of mite popula carbamate) gave less control of citrus rust tions on fruit and by a harvest examination of mite, Phyllocoptruta oleivora (Ashm.) when fruit for mite damage in the manner also pre used with a fixed copper than when used viously described (5). Although the density alone. An explanation for this reduction in of mite populations was determined at fre control seemed to lie in the work of Winston, quent intervals in both experiments, these data Bowman and Yothers (2) who in 1923 showed are not presented in detail, but are summariz that citrus rust mite always became more ed in four tables. Tables 1 and 4 summarize abundant on trees sprayed with copper than the data obtained after application of post- on unsprayed trees. This fact was verified by bloom sprays. Tables 2 and 5 summarize the Griffiths and Fisher (3) who also reported an data obtained after application of both post- increase in the difficulty of citrus rust mite bloom and summer sprays rather than after control where zinc sulfate and lime had been just summer sprays, because the effectiveness sprayed. These findings indicate that reduc of summer sprays was modified by post-bloom tion in control with zineb through the con treatments. In general, in each case, the high current use of copper is merely due to the er the average percent of infested fruit, the ability of copper to increase the citrus rust shorter the interval of control and the higher mite problem, and therefore would occur with the population after the interval of control. other rust mite miticides. In 1958, however, The interval of control was arbitrarily set at McBride (4) reported that the addition of copper compounds to zineb sprays resulted in the approximate number of weeks between a chemical reaction in which copper ethylene- the date of application and the date when 15 bis-dithiocarbamate was formed, resulting in percent of the fruit was found to be reinfested. a corresponding reduction in the amount of In Experiment 1, host trees were the vari the zinc compound deposited by the spray. ety Pineapple. A split-plot design with three These findings with those of Winston, et al. replications was employed. Three main plots (2) and Griffiths and Fisher (3) suggest that of four trees were randomized in each replicate copper may reduce the effectiveness of any and each main plot was divided into four rust mite miticide through its ability to in sub-plots of one tree each. The main treat crease the citrus rust mite population; but will ments used on the main plots in both post- have a greater effect on zineb or any com bloom and summer sprays were: 1) no control pound with which it will react chemically, of citrus rust mite, 2) 0.5 lb. of 65% zineb per both because of its ability to increase the citrus 100 gallon, and 3) 1.0 lb. of 65% zineb. The rust mite population and because of the subtreatments used with each main treatment chemical effect of the copper on the miticide on the subplots were: 1) no copper, 2) 1.4 itself. The purpose of the study reported here lb. of 53% tribasic copper sulfate in the post- was not only to test this theoiy, but also to bloom spray, 3) 0.7 lb. of 53% copper in the determine the effect of various uses of copper summer spray, and 4) 1.4 lb. of 53% copper on citrus rust mite control. in the post-bloom spray followed by 0.7 lb. in the summer spray. Materials and Methods. — Two experiments In Experiment 2, host trees were the vari were conducted in citrus groves near Lake ety Valencia. A split-plot design with four rep Florida Agricultural Experiment Station Journal Series, lications was employed. Five main plots of No. 1152. JOHNSON: MITICIDES 85 four trees were randomized in each replicate Table 1. Effect of trlbaslc copper sulfate on post-bloom and each main plot was divided into four sub control of citrus rust mite with two amounts of plots of one tree each. The main treatments zineb applied April 13, 1959. used on the main plots in both post-bloom and summer sprays were: 1) no control of citrus Average Percent of Fruit Infes ted With Rust Mite Mltlclde In Citrus Rust Mltea»b rust mite, 2) 10.0 1b. of wettable sulfur per 100 Gallon No Copper Copper* 100 gallon, 3) 0.5 lb. of 65% zineb, 4) 0.5 Check 53.8 53.8 53.8 lb. of Chlorobenzilate 25W (25% ethyl 4, 65Z zineb. 0.5 24.0 51.1 4'dichlorobenzilate), and 5) 0.5 lb. of Kepone 37.6 65X zineb, 1.0 8.4 50W (50% 1, 2 decachlorooctahydro-1, 3, 4- 28.4 18.4 metheno-2H-cyclobuta /cd/pentalen-2-one). Average 28.7 44.4 The sub-treatments used with each main treatment on the sub-plots were identical to those in Experiment 1. Average of mite counts made May 18, June 9 and July 1, 1959. Samples of 25 fruit per tree per count. FI6.I-EFFECTS OF COPPER ON RUST MITE °Poat-bloom dosage of 53X trlbaslc copper sulfate: 1.4 lb. per 100 ON LEAVES gallon. X NFESTED UNSPRAYED . _ POSTBLOOM COP. bloom spray than on unsprayed trees. Further 80 - / \ y•- *:\ SUMMER COPPER more, where copper was used in the summer spray, about 80 percent of the fruit remained 60 infested for 6 weeks and even more fruit was infested on trees that also received a post- 40 bloom application of copper (Fig. 1). 20 These effects of copper during July, August SUMMER SPRAY and September were only modified by the summer application of zineb. Although the 5/18 6/9 7/1 7/20 8/12 9/1 9/22 10/12 initial reduction was satisfactory with all zineb sprays except 0.5 lb. of zineb plus copper, Results — Experiment 1. — Citrus rust mite the length of control varied with the copper populations on trees that received no rust mite treatment and amount of zineb used. Control miticide increased at an equal rate during was excellent for more than 12 weeks on trees May and June whether copper was applied sprayed with 1.0 lb. of zineb whether zineb April 13 or the trees left unsprayed (Fig. 1). was used alone, combined with copper, or Where zineb was used, however, there were used on trees that received copper only in the striking differences, not only between amounts post-bloom spray. On the other hand, control of zineb, but especially between copper treat was excellent for only 8 weeks where copper ments. The initial reduction was inferior where was included in both post-bloom and summer copper was included with zineb and the in sprays. Results were entirely different with terval of control was shorter. Control with 0.5 0.5 lb. of zineb. Although the summer appli lb. of zineb was excellent for about 8 weeks, cations of 0.5 and 1.0 lb. of zineb were equally but for only 5 weeks where copper was in effective on trees that received no copper and cluded. Control was excellent for 11 weeks on trees that received copper in only the post- with 1.0 lb. of zineb, but for only 8 weeks bloom spray, control was completely unsatis in the presence of copper (Table 1). factory with 0.5 lb. of zineb where copper Summer sprays were applied on July 6 was included in the summer spray. when the citrus rust mite population on un Table 2 presents a summary of the citrus sprayed trees was at its highest level of about rust mite control obtained with each of the 90 percent infested fruit, but just before a 12 spray programs used in this experiment. sharp decline. Under these conditions the These data show that: 1) the seventy of the summer population trend was markedly citrus rust mite problem increased with each changed by all copper treatments. The pop increase in the use of copper, 2) control of ulation declined about two weeks later on citrus rust mite with zineb decreased with in trees that received copper in only the post- creased use of copper, but this decrease was FLORIDA STATE HORTICULTURAL SOCIETY, 1960 Table 2. Effect of post-bloom, summer and post-bloom plus summer applications of tri- basic copper sulfate on control of citrus rust mite with two amounts of zineb applied April 13 and July 6, 1959. Average Percent of Fruit Infested with Citrus Rust Mite » Main Treatments in No Post-bloom Summer Post-bloom and Pounds per 100 Gallon Copper Copper0 Copperd Summer Copper ' Average Check 36.7 40.3 53.9 51.8 45.7 657o zineb, 0.5 7.7** 23.4 33.9 37.9 27.5 65% zineb, 1.0 3.6** 11.7** 7.4** 18.5 10.3 Average 16.0 25.1 31.7 36.1 aAverage of mite counts made on May 18, June 9, July 1, 10 and 20, August 12, September 1 and 22, and October 12, 1959.
Load more

Recommended publications
  • Word Equations
    Chemical misconceptions 33 Word equations Target level These materials are designed for use with 11–14 year old students who have been taught to use word equations. The materials will also be useful for 14–16 year olds students who need to revisit this topic. Topic Using word equations to represent chemical reactions. Rationale Many students find it difficult to write word equations, which require an appreciation of the nature of chemical change (including conservation of matter), and familiarity with chemical names and the patterns of common reaction types. These materials provide probes for exploring whether students can complete word equations, and a set of practice exercises. These ideas are discussed in Chapter 9 of the Teachers’ notes. In the pilot teachers judged the materials ‘excellent’, ‘very useful’ and ‘helpful for revision’. Some teachers found the responses of some of their pupils to be ‘disappointing’ (or even ‘shocking’). The probes were thought to provide an interesting ‘look into [students’] minds’ and to lead to useful classroom discussion. Although teachers found it useful that students were asked to give reasons for their answers, some of the students did not like having to try to explain their reasons. (Some teachers may wish to ask students to just complete the equations in the probes, and to leave the spaces for making notes when going through the answers.) Students were reported to find the materials helpful and easy to follow, and were considered to have greater understanding afterwards. Instructions These materials may either be used with students who should have mastered word equations as a pre-test (to identify students needing practice), a remedial exercise, and a post-test; or as end-of-topic review material with students meeting word equations for the first time.
    [Show full text]
  • Zinc Sulphate
    RISK ASSESSMENT REPORT ZINC SULPHATE CAS-No.: 7733-02-0 EINECS-No.: 231-793-3 GENERAL NOTE This document contains: - part I Environment (pages 41) - part II Human Health (pages 130) R076_0805_env RISK ASSESSMENT ZINC SULPHATE CAS-No.: 7733-02-0 EINECS-No.: 231-793-3 Final report, May 2008 PART 1 Environment Rapporteur for the risk evaluation of zinc sulphate 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 R076_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.
    [Show full text]
  • US EPA Inert (Other) Pesticide Ingredients
    U.S. Environmental Protection Agency Office of Pesticide Programs List of Inert Pesticide Ingredients List 3 - Inerts of unknown toxicity - By Chemical Name UpdatedAugust 2004 Inert Ingredients Ordered Alphabetically by Chemical Name - List 3 Updated August 2004 CAS PREFIX NAME List No. 6798-76-1 Abietic acid, zinc salt 3 14351-66-7 Abietic acids, sodium salts 3 123-86-4 Acetic acid, butyl ester 3 108419-35-8 Acetic acid, C11-14 branched, alkyl ester 3 90438-79-2 Acetic acid, C6-8-branched alkyl esters 3 108419-32-5 Acetic acid, C7-9 branched, alkyl ester C8-rich 3 2016-56-0 Acetic acid, dodecylamine salt 3 110-19-0 Acetic acid, isobutyl ester 3 141-97-9 Acetoacetic acid, ethyl ester 3 93-08-3 2'- Acetonaphthone 3 67-64-1 Acetone 3 828-00-2 6- Acetoxy-2,4-dimethyl-m-dioxane 3 32388-55-9 Acetyl cedrene 3 1506-02-1 6- Acetyl-1,1,2,4,4,7-hexamethyl tetralin 3 21145-77-7 Acetyl-1,1,3,4,4,6-hexamethyltetralin 3 61788-48-5 Acetylated lanolin 3 74-86-2 Acetylene 3 141754-64-5 Acrylic acid, isopropanol telomer, ammonium salt 3 25136-75-8 Acrylic acid, polymer with acrylamide and diallyldimethylam 3 25084-90-6 Acrylic acid, t-butyl ester, polymer with ethylene 3 25036-25-3 Acrylonitrile-methyl methacrylate-vinylidene chloride copoly 3 1406-16-2 Activated ergosterol 3 124-04-9 Adipic acid 3 9010-89-3 Adipic acid, polymer with diethylene glycol 3 9002-18-0 Agar 3 61791-56-8 beta- Alanine, N-(2-carboxyethyl)-, N-tallow alkyl derivs., disodium3 14960-06-6 beta- Alanine, N-(2-carboxyethyl)-N-dodecyl-, monosodium salt 3 Alanine, N-coco alkyl derivs.
    [Show full text]
  • 1,399,500. Patented Dec, 6, 1921
    C, R, KUAE PR0 (CESS OF MANUFACT UR | N G | TH 0P 0 N E À PPLICATION FILED AUG, 15, 1921, 1,399,500. Patented Dec, 6, 1921. UNITED STATES PATENT OFFICE. CHEARTES. R. E.U2ELE, OF CLARKDALE, ARIZONA. SLLaLLLLLLL0LLLL GLLLLS LLLLLLLYLLLLLLLY LLLL LLLLLLLLS LLLGLLGGLGLLYS 1,399,500. specification of Tetters Patent, latented Dec. 6, 1921. Application filed August 15, 192i. Serial No. 492,342. ?? ??? ?????? ?? ???? ???????"?, these tanks) in which the crude lithopone Be it known that II, CHARLES R. KUZELL, is allowed to thicken by settling until it is a citizen of the United States, residing at concentrated to a Suitably dense pulp after Clarkdale, in the county of Yavapai and which it is drawn off by a high pressure 60 State of Arizona, have invented certain new pump 2 and discharged through suitable and useful Improvements in Processes of Spray nozzles 3 into a desiccating chamber 4 Manufacturing Lithopone, of which the fol through which the fine snray is carried by lowing is a specification. a current of air admitted to the chamber 4. My invention has relation to improve through a spray head 5 terminating the air 65 ments in the manufacture of lithopone, the Supply conduit 6. The air current and the process of which consists in the novel com finely divided lithopone are thoroughly bination of steps more fully set forth here mixed in the desiccating chamber, the latter inafter. being carried through the chamber by the The object of the present invention is to air current, which dries the lithopone as it 70 15 simplify the present method of manufac is carried through the chamber.
    [Show full text]
  • Zinc Supplementation in Children and Adolescents with Acute Leukemia
    European Journal of Clinical Nutrition (2013) 67, 1056–1059 & 2013 Macmillan Publishers Limited All rights reserved 0954-3007/13 www.nature.com/ejcn ORIGINAL ARTICLE Zinc supplementation in children and adolescents with acute leukemia LZZ Consolo, P Melnikov, FZ Coˆ nsolo, VA Nascimento and JCDV Pontes BACKGROUND/OBJECTIVES: Zinc is known as an essential micronutrient for human health because of its structural and biochemical functions, influencing growth and affecting multiple aspects of the immune system. Zinc has been extensively studied in neoplastic processes but its role in children with leukemia still remains to be elucidated in several aspects. The aim of this study was to evaluate the effects of oral zinc supplementation on weight gain and infectious episodes in children and adolescents with acute leukemia. SUBJECTS/METHODS: This study included 38 patients, and was carried out as a randomized, double-blind, placebo-controlled investigation. The dosage of plasma zinc levels and the evaluation of nutritional status were performed during a period of 60 days. Zinc was supplemented orally, 2 mg/kg/day, in the form of amino acid salt. RESULTS: The results showed that plasma zinc concentrations did not increase significantly with the addition of the micronutrient. However, from a clinical point of view, it has become evident that supplementary zinc exerts a positive effect on nutritional status as positive weight gain. Moreover, the number of infection episodes was significantly reduced, possibly because of the immune stimuli. CONCLUSIONS:
    [Show full text]
  • ZINCI SULFAS ZINC SULFATE Final Text for Addition to the International
    Document QAS/07.194/FINAL February 2008 . ZINCI SULFAS ZINC SULFATE Zinc sulfate monohydrate Zinc sulfate heptahydrate Final text for addition to The International Pharmacopoeia This monograph was adopted at the Forty-second WHO Expert Committee on Specifications for Pharmaceutical Preparations in October 2007 for addition to the 4 th edition of The International Pharmacopoeia . ZnSO 4,H2O (monohydrate); ZnSO 4,7H2O (heptahydrate) Relative molecular mass. 179.5 (monohydrate); 287.5 (heptahydrate). Chemical name. Zinc sulfate monohydrate; CAS Reg. No. 7446-19-7 (monohydrate). Zinc sulfate heptahydrate; CAS Reg. No. 7446-20-0 (heptahydrate). Description. A white or almost white, crystalline powder, or colourless, transparent crystals. Solubility. Very soluble in water, practically insoluble in ethanol (~750 g/l) TS. Category. Adjunct to oral rehydration salts in( prevention and) treatment of dehydration due to diarrhoea; astringent. Storage. Zinc sulfate should be kept in a well-closed, non-metallic container. Labelling. The designation on the container should state whether the substance is in the monohydrate or heptahydrate form and, where appropriate, that it is suitable for use in the manufacture of parenteral dosage forms. Requirements Definition. Zinc sulfate monohydrate contains not less than 99.0% and not more than 101.0% of ZnSO 4,H2O. Zinc sulfate heptahydrate contains not less than 99.0% and not more than 104.0% of ZnSO 4,7H2O. Document QAS/07.194/FINAL page 2 Identity tests A. Dissolve 0.25 g in 5 ml of water R and add 0.2 ml of sodium hydroxide (400 g/l) TS. A white precipitate is formed. Add a further 2 ml of sodium hydroxide (400 g/l) TS.
    [Show full text]
  • Acute Toxicity of Zinc Sulfate Heptahydrate (Znso4*7H2O) And
    Aquacu nd ltu a r e s e J i o r u e r h n Zeng et al., Fish Aqua J 2018, 9:1 s a i l F Fisheries and Aquaculture Journal DOI: 10.4172/2150-3508.1000240 ISSN: 2150-3508 Research Article Open Access Acute Toxicity of Zinc Sulfate Heptahydrate (ZnSO4*7H2O) and Copper (II) Sulfate Pentahydrate (CuSO4*5H2O) on Freshwater Fish, Percocypris pingi Ling Zeng, Lan Huang, Ming Zhao, Sheng Liu, Zhengjian He, Jupan Feng, Chuanjie Qin and Dengyue Yuan* Department of Aquaculture, College of Life Sciences, Neijiang Normal University, Neijiang, Sichuan, 641100, PR China *Corresponding author: Dengyue Yuan, Department of Aquaculture, College of Life Sciences, Neijiang Normal University, Neijiang, Sichuan, 641100, PR China, Tel: +86(0832) 234-4599; E-mail: [email protected] Received date: February 23, 2018; Accepted date: March 14, 2018; Published date: March 29, 2018 Copyright: © 2018 Yuan D, et al. This is an open-access article distributed under the terms of the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original author and source are credited. Abstract This study was carried out to determine acute toxicity of two heavy metals (zinc and copper) to fingerlings Percocypris pingi by static bioassays. The experimental fish were subjected to a range of concentrations of heavy metals. At different exposure periods (24 h, 48 h, 72 h and 96 h), the mortality rate were separately investigated. The median lethal concentration (LC50) was determined with Probit analysis. The LC50 values of zinc for the Percocypris pingi at 24 h, 48 h, 72 h and 96 h were 3.504 mg/L, 2.933 mg/L, 2.852 mg/L and 2.852 mg/L, respectively.
    [Show full text]
  • C09c - 2020.01
    CPC - C09C - 2020.01 C09C TREATMENT OF INORGANIC MATERIALS, OTHER THAN FIBROUS FILLERS, TO ENHANCE THEIR PIGMENTING OR FILLING PROPERTIES (preparation of inorganic compounds or non-metallic elements C01; treatment of materials specially adapted to enhance their filling properties in mortars, concrete or artificial stone C04B 14/00, C04B 18/00, C04B 20/00); PREPARATION OF CARBON BLACK; {PREPARATION OF INORGANIC MATERIALS WHICH ARE NO SINGLE CHEMICAL COMPOUNDS AND WHICH ARE MAINLY USED AS PIGMENTS OR FILLERS} Definition statement This place covers: The treatment of inorganic compounds other than fibrous fillers, to enhance their pigmenting or filling properties; Preparation of carbon black. Preparation of inorganic materials being no single chemical compounds and used as pigments or fillers. References Limiting references This place does not cover: Treatment by polymerisation onto particle is classified in C08F 292/00. Only treatment by already polymerised agents is classified in C09C. Special rules of classification The following IPC groups are not used in the internal CPC classification scheme. Subject matter covered by these groups is classified in the following CPC groups: IPC group C09C1/68 is covered by CPC group C09K 3/14. Whenever in groups C09C 1/00 - C09C 1/66 the materials consist of a particulate core bearing a coating or any other deposit, classification is done only according to the composition of the core, unless otherwise stated, e.g. C09C 1/0015, C09C 1/0078. Preparations of materials which are no single chemical compounds, mainly comprising ceramic pigments (C09C 1/0009),consisting of solid solutions or polycristalline structures, and compounds defined as composite materials (C09C 1/0081).Preparation and treatment steps are not always easy to distinguish from each other, e.g.
    [Show full text]
  • Zinc Therapy in Dermatology: a Review
    Hindawi Publishing Corporation Dermatology Research and Practice Volume 2014, Article ID 709152, 11 pages http://dx.doi.org/10.1155/2014/709152 Review Article Zinc Therapy in Dermatology: A Review Mrinal Gupta, Vikram K. Mahajan, Karaninder S. Mehta, and Pushpinder S. Chauhan DepartmentofDermatology,Venereology&Leprosy,Dr.R.P.Govt.MedicalCollege,Kangra(Tanda),HimachalPradesh176001,India Correspondence should be addressed to Vikram K. Mahajan; [email protected] Received 1 May 2014; Accepted 23 June 2014; Published 10 July 2014 Academic Editor: Craig G. Burkhart Copyright © 2014 Mrinal Gupta et al. This is an open access article distributed under the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original work is properly cited. Zinc, both in elemental or in its salt forms, has been used as a therapeutic modality for centuries. Topical preparations like zinc oxide, calamine, or zinc pyrithione have been in use as photoprotecting, soothing agents or as active ingredient of antidandruff shampoos. Its use has expanded manifold over the years for a number of dermatological conditions including infections (leishmaniasis, warts), inflammatory dermatoses (acne vulgaris, rosacea), pigmentary disorders (melasma), and neoplasias (basal cell carcinoma). Although the role of oral zinc is well-established in human zinc deficiency syndromes including acrodermatitis enteropathica, it is only in recent years that importance of zinc as a micronutrient essential for infant
    [Show full text]
  • Chemical Reactions. Balance Each Equation. 1. Zinc + Copper (II) Sulfate → Copper + Zinc Sulfate Zn + Cuso4 → Cu + Znso4 2
    Chemical Reactions. Balance Each Equation. 1. zinc + copper (II) sulfate → copper + zinc sulfate Zn + CuSO4 → Cu + ZnSO4 2. potassium chlorate → potassium chloride + oxygen 2KClO3 → 2KCl + 3 O2 3. potassium iodide + lead (II) nitrate → lead (II) iodide + potassium nitrate 2KI + Pb(NO3)2 → PbI2 + 2KNO3 4. iron (III) oxide + carbon → iron + carbon monoxide Fe2O3 + 3C → 2Fe + 3CO 5. iron + water → hydrogen + iron (III) oxide 2Fe + 3H2O → 3H2 + Fe2O3 6. aluminum + sulfuric acid → aluminum sulfate + hydrogen 2Al + 3H2SO4 → Al2(SO4)3 + 3H2 7. magnesium chloride + ammonium nitrate → magnesium nitrate + ammonium chloride MgCl2 + 2NH4NO3 → Mg(NO3)2 + 2NH4Cl 8. mercury (II) oxide → mercury + oxygen 2HgO → 2Hg + O2 9. sodium carbonate + calcium hydroxide → sodium hydroxide + calcium carbonate 2Na2CO3 + Ca(OH)2 → 2NaOH + CaCO3 10. phosphorus + oxygen → phosphorus pentoxide 2P + 5O2 → 2PO5 11. sodium + water → sodium hydroxide + hydrogen 2Na + 2HOH → 2NaOH + H2 12. zinc + sulfuric acid → zinc sulfate + hydrogen Zn + H2SO4 → ZnSO4 + H2 13. calcium oxide + water → calcium hydroxide CaO + H2O → Ca(OH)2 14. iron + copper (I) nitrate → iron (II) nitrate + copper Fe + 2CuNO3 → Fe(NO3)2 + 2Cu 15. potassium oxide + water → potassium hydroxide K2O + H2O → 2KOH 16. ammonium sulfide + lead (II) nitrate → ammonium nitrate + lead (II) sulfide (NH4)2S + Pb(NO3)2 → 2NH4NO3 + PbS 17. mercury (II) hydroxide + phosphoric acid → mercury (II) phosphate + water 3Hg(OH)2 + 2H3PO4 → Hg3(PO4)2 + 6H2O 18. potassium hydroxide + phosphoric acid → potassium phosphate + water 3KOH + H3PO4 → K3PO4 + HOH 19. calcium chloride + nitric acid → calcium nitrate + hydrochloric acid CaCl2 + 2HNO3 → Ca(NO3)2 + 2HCl 20. potassium carbonate + barium chloride → potassium chloride + barium carbonate K2CO3 + BaCl2 → 2KCl + BaCO3 21.
    [Show full text]
  • Wettable Powder Versus Tank-Mix Dithiocarbamates on Potatoes and Tomatoes in Ohio
    RESEARCH CIRCULAR 9 APRIL 11953 WETTABLE POWDER versus TANK-MIX DITHIOCARBAMATES on POTATOES and TOMATOES 1n• OHIO • J. D. WILSON • OHIO AGRICULTURAL EXPERIMENT STATION W 0 0 S T E R, 0 H I 0 CONTENTS * * Introduction .. 3 Preliminary Work 4 Results and Discussion 6 Conclusions ..... 19 Literature Citations . 20 Appendix .... .. 21 WETTABLE POWDER VERSUS TANK-MIX DITHIOCARBAMATES ON POTATOES AND TOMATOES IN OHIO J. D. WILSON INTRODUCTION The dithiocarbamates have now been used as fungicides in Ohio, experimentally or otherwise, for more than 15 years ( 4) . F ermate (ferbam), or ferric dimethyl dithiocarbamate, was the first of these to be used on tomatoes and potatoes, to which it was applied both as spray and dust mixtures prepared from a wettable powder formulation ( 1, 2). Dithane and Parzate have now been tested experimentally for several years both as wettable powders (zineb) and as "tank-mix" formulations of solubilized zinc sulfate plus liquid disodium ethylene bis dithiocarbamate (nabam). There has always been some question as to which type of formulation is capable of giving the best control of such diseases as the early and late blights of potato and tomato ( 10, 12). During the same period, as good or better results were being obtained with a slurry form of zinc dimethyl dithiocarbamate than with the cor­ responding wettable powders known as Zerlate and Methasan (ziram) (16,17,18). The wettable powder formulations of such fungicides as ferbam, ziram, and zineb are prepared by the manufacturer for use in spray and dust applications. The active ingredients of these powder formulations, which are comparatively insoluble and non-wettable, are made wettable by adding wetting and/or conditioning agents.
    [Show full text]
  • Treatment of Pityriasis Versicolour with Topical 15% Zinc Sulfate Solution
    Treatment of Pityriasis Versicolour with Topical 15% Zinc Sulfate Solution Khalifa E. Sharquie Wisam S. Al- Dori MD; PhD. MD; FIBMS. Inas K. Sharquie Adil A. Al– Nuaimy BSc; MSc. MD; DDV; FICMS. Abstract Background: Pityriasis versicolour is a common skin problem of cosmetic importance among young individuals. Many modality of the treatment have been used to control this disease, but often end with relapse. Zinc sulfate had been proven to have antifungal activity invitro study. Still we are searching for a new therapeutic agent like zinc sulfate. Objective: The aim of the present work is to assess the therapeutic effectiveness of topical 15% zinc sulfate solution in treatment of tinea versicolor. Patients& Methods: This single blinded controlled therapeutic trail was carried out in Department of Dermatology and Venereology - Baghdad Teaching Hospital, during the period from May 2004- Sept. 2004. Patients consisted of 60 person (40 males&20 females) and their ages ranged from 15 – 45 years with a mean ± SD of 32 ± 3 years, while the duration of the disease was 2-30 ( 5.18 ± 4.77) months. These patients were enrolled in this study and were divided into two groups:- Group A: Thirty patients (16 males and 14 females) were treated with topical 15% zinc sulfate solution once daily and examine every week for three weeks and followed up for one month without therapy. Mycological and Wood's light examination were performed to establish diagnosis before therapy and repeated every week to asses the response to therapy. Group B: Thirty patients (24 males and 6 females) were treated with distilled water as a placebo treated group and with a similar manner in group A.
    [Show full text]