ch04 by Dr. Dina
... “Straight-chain” alkanes have a zig-zag orientation when they are in their most straight orientation ...
... “Straight-chain” alkanes have a zig-zag orientation when they are in their most straight orientation ...
sample paper chemistry clas xi set 3
... 2. Marks for each question are indicated against each 3. Question nos. 1-8 are very short answer questions and carry one mark each. Answer these questions in one word or about one sentence each. 4. Question nos. 9-18 are short answer questions and carry 2 marks each. Answer these questions in about ...
... 2. Marks for each question are indicated against each 3. Question nos. 1-8 are very short answer questions and carry one mark each. Answer these questions in one word or about one sentence each. 4. Question nos. 9-18 are short answer questions and carry 2 marks each. Answer these questions in about ...
NCEA Level 2 Chemistry (91165) 2012
... CH3CH2CH2COONa Chloroethane reacts with KOH(aq) to form an alcohol in a substitution reaction; Cl is replaced by OH. CH3CH2Cl → CH3CH2OH Chloroethane reacts with KOH(alc) to form an alkene in an elimination reaction; H and Cl removed / HCl ...
... CH3CH2CH2COONa Chloroethane reacts with KOH(aq) to form an alcohol in a substitution reaction; Cl is replaced by OH. CH3CH2Cl → CH3CH2OH Chloroethane reacts with KOH(alc) to form an alkene in an elimination reaction; H and Cl removed / HCl ...
NCEA Level 2 Chemistry (91165) 2012 Assessment Schedule
... CH3CH2CH2COONa Chloroethane reacts with KOH(aq) to form an alcohol in a substitution reaction; Cl is replaced by OH. CH3CH2Cl CH3CH2OH Chloroethane reacts with KOH(alc) to form an alkene in an elimination reaction; H and Cl removed / HCl ...
... CH3CH2CH2COONa Chloroethane reacts with KOH(aq) to form an alcohol in a substitution reaction; Cl is replaced by OH. CH3CH2Cl CH3CH2OH Chloroethane reacts with KOH(alc) to form an alkene in an elimination reaction; H and Cl removed / HCl ...
4.5 Topic Checklist Carbonyl Compounds
... basis of a simple chemical test to distinguish between aldehydes and ketones (e.g. Fehling’s solution and Tollens’ reagent) appreciate the hazards of synthesis using HCN/KCN know that aldehydes can be reduced to primary alcohols and ketones to secondary alcohols using reducing agents such as NaBH4. ...
... basis of a simple chemical test to distinguish between aldehydes and ketones (e.g. Fehling’s solution and Tollens’ reagent) appreciate the hazards of synthesis using HCN/KCN know that aldehydes can be reduced to primary alcohols and ketones to secondary alcohols using reducing agents such as NaBH4. ...
Discussion Worksheet #10 Formation of Alcohols Skill 1: Functional
... There are ways to control regiochemistry and stereochemistry with alcohol formation ...
... There are ways to control regiochemistry and stereochemistry with alcohol formation ...
Chapter 9 – Compounds of Carbon
... • It is possible to replace a hydrogen atom in an alkane with a chlorine, to form a chloroalkanes. • The systematic name for a chloroalkane starts with chloro followed by the name of the alkane. • In chains higher than two carbons it is possible to put chlorines on different carbons. • In this case, ...
... • It is possible to replace a hydrogen atom in an alkane with a chlorine, to form a chloroalkanes. • The systematic name for a chloroalkane starts with chloro followed by the name of the alkane. • In chains higher than two carbons it is possible to put chlorines on different carbons. • In this case, ...
Chapter 3 Properties of organic compounds
... two possible products. The favoured product is the one in which the H atom is added to the carbon of the double bond that already carries the most H atoms (Markovnikov’s rule). H CH3CH ...
... two possible products. The favoured product is the one in which the H atom is added to the carbon of the double bond that already carries the most H atoms (Markovnikov’s rule). H CH3CH ...
here
... C4H6 General Properties/Characteristics: Alkanes (paraffins or saturated HC): relatively stable to chemical reactions. Low molecular weight alkanes are gases or liquids, high MW are solids. Alkenes (olefins ): unsaturated HC because they don’t have the maximum number of atoms each carbon is able to ...
... C4H6 General Properties/Characteristics: Alkanes (paraffins or saturated HC): relatively stable to chemical reactions. Low molecular weight alkanes are gases or liquids, high MW are solids. Alkenes (olefins ): unsaturated HC because they don’t have the maximum number of atoms each carbon is able to ...
unsaturated hydrocarbon
... 17. Saponification – the process of making soap from the hydrolysis of an ester by a strong base (glycerol is also a byproduct) 18. Saturated hydrocarbon – an alkane; a hydrocarbon containing all single bonds; a hydrocarbon with no double or triple bonds 19. Secondary – positional description referr ...
... 17. Saponification – the process of making soap from the hydrolysis of an ester by a strong base (glycerol is also a byproduct) 18. Saturated hydrocarbon – an alkane; a hydrocarbon containing all single bonds; a hydrocarbon with no double or triple bonds 19. Secondary – positional description referr ...
chapter 12_13_14_16_17 Organic Nomenclature
... ► Very similar rules as for alkanes ► Additional rules: ►Choose longest chain that contains the double or triple bond ►Suffix for alkenes: -ene ►Suffix for alkynes: -yne ►Include a number with the parent to indicate which carbon the double/triple bond starts on. ...
... ► Very similar rules as for alkanes ► Additional rules: ►Choose longest chain that contains the double or triple bond ►Suffix for alkenes: -ene ►Suffix for alkynes: -yne ►Include a number with the parent to indicate which carbon the double/triple bond starts on. ...
1 Saturday X-tra X-Sheet: 8 Organic Molecules Hydrocarbons Key
... • The alkyl groups which consist of radicals formed when one hydrogen is removed from an alkane e.g methyl –CH3, ethyl –C2H5 • The halides e.e. –Cl chloro, -Br bromo, -I iodo • If the substitution group apeas more than once in a molecule, the prefixes di,tri-,tetra- ect are used and numbers are used ...
... • The alkyl groups which consist of radicals formed when one hydrogen is removed from an alkane e.g methyl –CH3, ethyl –C2H5 • The halides e.e. –Cl chloro, -Br bromo, -I iodo • If the substitution group apeas more than once in a molecule, the prefixes di,tri-,tetra- ect are used and numbers are used ...
Final Exam Review - Clayton State University
... A) The compounds are designated as D- and L- isomers. B) The compounds each contain at least one chiral carbon. C) The compounds are known as enantiomers. D) The compounds are superimposable. E) The compounds are optically active. ...
... A) The compounds are designated as D- and L- isomers. B) The compounds each contain at least one chiral carbon. C) The compounds are known as enantiomers. D) The compounds are superimposable. E) The compounds are optically active. ...
Organic Chemistry
... Going the other way: Rules for interpreting organic structures • Carbon is always present in every organic molecule – assume carbon is at each end of every bond unless another atom is explicitly specified. • means that there is a carbon atom at the end of every ...
... Going the other way: Rules for interpreting organic structures • Carbon is always present in every organic molecule – assume carbon is at each end of every bond unless another atom is explicitly specified. • means that there is a carbon atom at the end of every ...
File - Mr Weng`s IB Chemistry
... formula, which differ from each other by a common structural unit. • Structural formulas can be represented in full and condensed format. • Structural isomers are compounds with the same molecular formula but different arrangements of atoms. • Functional groups are the reactive parts of molecules. • ...
... formula, which differ from each other by a common structural unit. • Structural formulas can be represented in full and condensed format. • Structural isomers are compounds with the same molecular formula but different arrangements of atoms. • Functional groups are the reactive parts of molecules. • ...
Organic Chemistry - WilsonSCH4U1-07-2015
... • These forces are based on the simultaneous attraction of the electrons of one molecule by the positive nuclei of neighbouring molecules • The strength of the force is directly related to the number of electrons and protons in a given molecule • The greater the number of electrons and protons the g ...
... • These forces are based on the simultaneous attraction of the electrons of one molecule by the positive nuclei of neighbouring molecules • The strength of the force is directly related to the number of electrons and protons in a given molecule • The greater the number of electrons and protons the g ...
Aim: How can we describe Hydrocarbons?
... intermolecular forces that hold them together) – The great number of carbons leads to a higher melting point. ...
... intermolecular forces that hold them together) – The great number of carbons leads to a higher melting point. ...
1 Carbonyl Condensation Reactions (Conjugate Addition) If we look
... In this reaction, an enolate is the nuclophile; one aldehyde molecule becomes the enolate while the other molecule serves as the electrophile. With aldehydes, the equilibrium usually favors the aldol products. But with ketones, the equilibrium usually favors starting materials. Of course, there are ...
... In this reaction, an enolate is the nuclophile; one aldehyde molecule becomes the enolate while the other molecule serves as the electrophile. With aldehydes, the equilibrium usually favors the aldol products. But with ketones, the equilibrium usually favors starting materials. Of course, there are ...
Background Information
... environments (i.e., the Lucas reagent) for the reaction to take place. Therefore, only water-soluble, 1°, 2°, 3° allylic, 3° alkyl and some 2 ° alkyl alcohols of low molecular weight will provide positive results in this test. The reaction that occurs in the Lucas test is an SN1 nucleophilic substit ...
... environments (i.e., the Lucas reagent) for the reaction to take place. Therefore, only water-soluble, 1°, 2°, 3° allylic, 3° alkyl and some 2 ° alkyl alcohols of low molecular weight will provide positive results in this test. The reaction that occurs in the Lucas test is an SN1 nucleophilic substit ...
Organic Chemistry Syllabus and Course Outline
... reactions, equilibria, rates and energy changes, bond dissociation energies, energy diagrams 7. Alkenes: Structure and Reactivity Carbon-carbon double bonds, electrophilic addition reactions, industrial preparation and use of alkenes, naming, stereoisomerism, the Hammond Postulate, carbocations. 8. ...
... reactions, equilibria, rates and energy changes, bond dissociation energies, energy diagrams 7. Alkenes: Structure and Reactivity Carbon-carbon double bonds, electrophilic addition reactions, industrial preparation and use of alkenes, naming, stereoisomerism, the Hammond Postulate, carbocations. 8. ...
Chemistry 112A Second Midterm Review Sheet Summary of
... Allowing fluorine (lowest priority) to point away from the viewer the rotation is clockwise hence the R-assignment. In the assignment of L-serine highest priority is given to the nitrogen atom (Z = 7) in the amino group (NH2). Both the methylalcohol group (CH2OH ) and the carboxylic acid group (COOH ...
... Allowing fluorine (lowest priority) to point away from the viewer the rotation is clockwise hence the R-assignment. In the assignment of L-serine highest priority is given to the nitrogen atom (Z = 7) in the amino group (NH2). Both the methylalcohol group (CH2OH ) and the carboxylic acid group (COOH ...
solutions
... A1) What factor determines the order of water-solubility for a series of substances? a) intermolecular forces b) intramolecular forces c) boiling points d) molecular shape A2) Which of the following molecules will not undergo oxidation? a) 2-propanol b) 2-methylpropanal c) 2-methyl-2-butanol ...
... A1) What factor determines the order of water-solubility for a series of substances? a) intermolecular forces b) intramolecular forces c) boiling points d) molecular shape A2) Which of the following molecules will not undergo oxidation? a) 2-propanol b) 2-methylpropanal c) 2-methyl-2-butanol ...
Haloalkane
The haloalkanes (also known, as halogenoalkanes or alkyl halides) are a group of chemical compounds derived from alkanes containing one or more halogens. They are a subset of the general class of halocarbons, although the distinction is not often made. Haloalkanes are widely used commercially and, consequently, are known under many chemical and commercial names. They are used as flame retardants, fire extinguishants, refrigerants, propellants, solvents, and pharmaceuticals. Subsequent to the widespread use in commerce, many halocarbons have also been shown to be serious pollutants and toxins. For example, the chlorofluorocarbons have been shown to lead to ozone depletion. Methyl bromide is a controversial fumigant. Only haloalkanes which contain chlorine, bromine, and iodine are a threat to the ozone layer, but fluorinated volatile haloalkanes in theory may have activity as greenhouse gases. Methyl iodide, a naturally occurring substance, however, does not have ozone-depleting properties and the United States Environmental Protection Agency has designated the compound a non-ozone layer depleter. For more information, see Halomethane. Haloalkane or alkyl halides are the compounds which have the general formula ″RX″ where R is an alkyl or substituted alkyl group and X is a halogen (F, Cl, Br, I).Haloalkanes have been known for centuries. Chloroethane was produced synthetically in the 15th century. The systematic synthesis of such compounds developed in the 19th century in step with the development of organic chemistry and the understanding of the structure of alkanes. Methods were developed for the selective formation of C-halogen bonds. Especially versatile methods included the addition of halogens to alkenes, hydrohalogenation of alkenes, and the conversion of alcohols to alkyl halides. These methods are so reliable and so easily implemented that haloalkanes became cheaply available for use in industrial chemistry because the halide could be further replaced by other functional groups.While most haloalkanes are human-produced, non-artificial-source haloalkanes do occur on Earth, mostly through enzyme-mediated synthesis by bacteria, fungi, and especially sea macroalgae (seaweeds). More than 1600 halogenated organics have been identified, with bromoalkanes being the most common haloalkanes. Brominated organics in biology range from biologically produced methyl bromide to non-alkane aromatics and unsaturates (indoles, terpenes, acetogenins, and phenols). Halogenated alkanes in land plants are more rare, but do occur, as for example the fluoroacetate produced as a toxin by at least 40 species of known plants. Specific dehalogenase enzymes in bacteria which remove halogens from haloalkanes, are also known.