슬라이드 1
... A soluble bis-phosphine complexes, Ni(dppe)2Cl2, is a particularly effective catalyst. The main distinction between this reaction and Pd-catalyzed cross coupling is that the nickel reaction can be more readily applied to saturated alkyl groups because of a reduced tendency for b-elimination. ...
... A soluble bis-phosphine complexes, Ni(dppe)2Cl2, is a particularly effective catalyst. The main distinction between this reaction and Pd-catalyzed cross coupling is that the nickel reaction can be more readily applied to saturated alkyl groups because of a reduced tendency for b-elimination. ...
File
... Isomers – same molecular formula, different structures (moving double bond produces isomer) ...
... Isomers – same molecular formula, different structures (moving double bond produces isomer) ...
World of Chemistry Chapter 20—Organic Chemistry
... C. More than any other element, carbon can form long chains of molecules II. Section 20.2—Alkanes A. Alkanes are saturated hydrocarbons—which means that they are a chain of carbon and hydrogen atoms where each carbon atom is bound to 4 other atoms with no double or triple bonds B. The simplest alkan ...
... C. More than any other element, carbon can form long chains of molecules II. Section 20.2—Alkanes A. Alkanes are saturated hydrocarbons—which means that they are a chain of carbon and hydrogen atoms where each carbon atom is bound to 4 other atoms with no double or triple bonds B. The simplest alkan ...
Infrared Unknown Identities
... Unknown #1 3100 -- The broad intense absorption band seen here is characteristic of a carboxylic acid dimer. 2960 -- CH aliphatic assymmetric stretch 2870 -- CH aliphatic symmetic stretching vibrational band. 1415 -- Absorption in this region is due to CH3. Note the weak band just below 1400. This i ...
... Unknown #1 3100 -- The broad intense absorption band seen here is characteristic of a carboxylic acid dimer. 2960 -- CH aliphatic assymmetric stretch 2870 -- CH aliphatic symmetic stretching vibrational band. 1415 -- Absorption in this region is due to CH3. Note the weak band just below 1400. This i ...
ORGANIC CHEMISTRY
... • Carbon, Oxygen, Nitrogen and Hydrogen combine in certain ways to form organic molecules that make up living things. ...
... • Carbon, Oxygen, Nitrogen and Hydrogen combine in certain ways to form organic molecules that make up living things. ...
Chapter 4 mastery check
... they have different chemical properties they have the same molecular formula their atoms and bonds are arranged in different sequences they are a result of restricted movement around a carbon double bond their possible numbers increase as carbon skeletons increase in size. ...
... they have different chemical properties they have the same molecular formula their atoms and bonds are arranged in different sequences they are a result of restricted movement around a carbon double bond their possible numbers increase as carbon skeletons increase in size. ...
Organic Chemistry
... Cracking: large molecules broken down to smaller ones by breaking carbon-carbon bonds. Pyrolysis (thermal cracking): The process that produces cracking at high temperatures. ...
... Cracking: large molecules broken down to smaller ones by breaking carbon-carbon bonds. Pyrolysis (thermal cracking): The process that produces cracking at high temperatures. ...
BCH 201 lect2
... - The four single bonds that can be formed by a carbon atom are arranged tetrahedrally, with an angle of about 109.5 between any two bonds (Fig.) and an average length of 0.154 nm. - There is free rotation around each single bond, unless very large or highly charged groups are attached to both carb ...
... - The four single bonds that can be formed by a carbon atom are arranged tetrahedrally, with an angle of about 109.5 between any two bonds (Fig.) and an average length of 0.154 nm. - There is free rotation around each single bond, unless very large or highly charged groups are attached to both carb ...
sources - critical chemistry
... valence electrons which are offered in order to create covalent bonds. Covalent compounds formed by carbon are either polar or non polar which depends on the bond that is formed between the atoms. The fact that carbon has 4 valence electrons means it can form up to a maximum of 4 bonds, which are si ...
... valence electrons which are offered in order to create covalent bonds. Covalent compounds formed by carbon are either polar or non polar which depends on the bond that is formed between the atoms. The fact that carbon has 4 valence electrons means it can form up to a maximum of 4 bonds, which are si ...
organic chemistry - Turner Fenton Secondary School
... Nomenclature of Hydrocarbons Involving Halides Halides = Halogens = F, Cl, Br, I The nomenclature of naming hydrocarbons with Halides on them remains the same as naming a hydrocarbon containing an alkyl group. However, instead of Fluorine ethane it is Fluoroethane for example. Therefore change th ...
... Nomenclature of Hydrocarbons Involving Halides Halides = Halogens = F, Cl, Br, I The nomenclature of naming hydrocarbons with Halides on them remains the same as naming a hydrocarbon containing an alkyl group. However, instead of Fluorine ethane it is Fluoroethane for example. Therefore change th ...
polar covalent bond
... – Since alkanes are insoluble and less dense than water, they float on top of the water. ...
... – Since alkanes are insoluble and less dense than water, they float on top of the water. ...
Organic compounds
... • Carbon compounds – Organic compounds- primarily made of carbon • Carbon can from four covalent bonds • As a result, carbon can bon in a number of ways ...
... • Carbon compounds – Organic compounds- primarily made of carbon • Carbon can from four covalent bonds • As a result, carbon can bon in a number of ways ...
Ch. 22 Hydrocarbon Compounds
... Cis-trans isomers are most commonly found in compounds with double bonds (alkenes) Cis configuration: similar groups are on the same side of the double bond Trans configuration: similar groups are on opposite sides of the double bond ...
... Cis-trans isomers are most commonly found in compounds with double bonds (alkenes) Cis configuration: similar groups are on the same side of the double bond Trans configuration: similar groups are on opposite sides of the double bond ...
+ Y
... has an electron-poor atom (e.g H+, CH3+ ) and can form a bond by accepting a pair of electrons from a nucleophile ...
... has an electron-poor atom (e.g H+, CH3+ ) and can form a bond by accepting a pair of electrons from a nucleophile ...
Study Guide
... Each compound has different characteristics. Propane (3 carbons, single bonds) is grill gas. Polyproplyene (a repeating chain of 3-carbons with double bonds) is the polymer used in fleece and water bottles. For a given hydrocarbon, you can add an OH group to it and you have created an alcohol. Propa ...
... Each compound has different characteristics. Propane (3 carbons, single bonds) is grill gas. Polyproplyene (a repeating chain of 3-carbons with double bonds) is the polymer used in fleece and water bottles. For a given hydrocarbon, you can add an OH group to it and you have created an alcohol. Propa ...
Aromaticity
In organic chemistry, the term aromaticity is formally used to describe an unusually stable nature of some flat rings of atoms. These structures contain a number of double bonds that interact with each other according to certain rules. As a result of their being so stable, such rings tend to form easily, and once formed, tend to be difficult to break in chemical reactions. Since one of the most commonly encountered aromatic system of compounds in organic chemistry is based on derivatives of the prototypical aromatic compound benzene (common in petroleum), the word “aromatic” is occasionally used to refer informally to benzene derivatives, and this is how it was first defined. Nevertheless, many non-benzene aromatic compounds exist. In living organisms, for example, the most common aromatic rings are the double-ringed bases in RNA and DNA.The earliest use of the term “aromatic” was in an article by August Wilhelm Hofmann in 1855. Hofmann used the term for a class of benzene compounds, many of which do have odors (unlike pure saturated hydrocarbons). Today, there is no general relationship between aromaticity as a chemical property and the olfactory properties of such compounds, although in 1855, before the structure of benzene or organic compounds was understood, chemists like Hofmann were beginning to understand that odiferous molecules from plants, such as terpenes, had chemical properties we recognize today are similar to unsaturated petroleum hydrocarbons like benzene.In terms of the electronic nature of the molecule, aromaticity describes the way a conjugated ring of unsaturated bonds, lone pairs of electrons, or empty molecular orbitals exhibit a stabilization stronger than would be expected by the stabilization of conjugation alone. Aromaticity can be considered a manifestation of cyclic delocalization and of resonance. This is usually considered to be because electrons are free to cycle around circular arrangements of atoms that are alternately single- and double-bonded to one another. These bonds may be seen as a hybrid of a single bond and a double bond, each bond in the ring identical to every other. This commonly seen model of aromatic rings, namely the idea that benzene was formed from a six-membered carbon ring with alternating single and double bonds (cyclohexatriene), was developed by August Kekulé (see History section below). The model for benzene consists of two resonance forms, which corresponds to the double and single bonds superimposing to produce six one-and-a-half bonds. Benzene is a more stable molecule than would be expected without accounting for charge delocalization.