Phenol File
... PHENOL Before you start it would be helpful to… • know the functional groups found in organic chemistry • know the arrangement of bonds around atoms • recall and explain electrophilic substitution of aromatic rings ...
... PHENOL Before you start it would be helpful to… • know the functional groups found in organic chemistry • know the arrangement of bonds around atoms • recall and explain electrophilic substitution of aromatic rings ...
Naming Organic Compounds
... include both carbon atoms of the double bond. 3. The root chain must be numbered from the end nearest a double bond carbon atom. If the double bond is in the center of the chain, the nearest substituent rule is used to determine the end where numbering starts. 4. The smaller of the two numbers desig ...
... include both carbon atoms of the double bond. 3. The root chain must be numbered from the end nearest a double bond carbon atom. If the double bond is in the center of the chain, the nearest substituent rule is used to determine the end where numbering starts. 4. The smaller of the two numbers desig ...
chap 4 org chem
... Carbon Will readily bond with itself (C) with – or = bonds (single, double or even triple) Also bonds with H – O = N, P, & S Forms long chains or backbones of organic molecules Carbon will always have four lines connecting to other atoms. ...
... Carbon Will readily bond with itself (C) with – or = bonds (single, double or even triple) Also bonds with H – O = N, P, & S Forms long chains or backbones of organic molecules Carbon will always have four lines connecting to other atoms. ...
SCIENCE 10: Chemical Reactions – Atomic Structure
... The element copper forms two different compounds with chlorine. Chlorine always forms a 1- ion. Copper can form either a 1+ ion or a 2+ ion. CuCl = copper (I) chloride CuCl2 = copper (II) chloride Naming Ionic Compounds: (p.194) o Metal name first, non-metal name second o Change the ending of the ...
... The element copper forms two different compounds with chlorine. Chlorine always forms a 1- ion. Copper can form either a 1+ ion or a 2+ ion. CuCl = copper (I) chloride CuCl2 = copper (II) chloride Naming Ionic Compounds: (p.194) o Metal name first, non-metal name second o Change the ending of the ...
Organic Chemistry –Syllabus- one Semester Sackler faculty of
... Charge, Bond strength, Bond length, Hybridization(sp3, sp2, sp), geometry of molecules, Dipole Moment, Functional Groups , Resonance, Acids and Bases: The Brønsted-Lowry Definition, conjugation acid-base pair, Ka ,pKa ,Kb, how to determine the position of acid-base reaction, The Effect of Structure ...
... Charge, Bond strength, Bond length, Hybridization(sp3, sp2, sp), geometry of molecules, Dipole Moment, Functional Groups , Resonance, Acids and Bases: The Brønsted-Lowry Definition, conjugation acid-base pair, Ka ,pKa ,Kb, how to determine the position of acid-base reaction, The Effect of Structure ...
Course File - Chemical Engineering and Applied Chemistry
... Discuss nucleophilic substitution and elimination reactions and their mechanisms. Explain a foundation in the alcohols and ethers; their nomenclature, synthesis, reactions and mechanisms. Describe the concepts which deal with aromaticity, aromatic compounds and their nomenclature. Explain th ...
... Discuss nucleophilic substitution and elimination reactions and their mechanisms. Explain a foundation in the alcohols and ethers; their nomenclature, synthesis, reactions and mechanisms. Describe the concepts which deal with aromaticity, aromatic compounds and their nomenclature. Explain th ...
Unit 2 Biochemistry Chp 4 Organic Chemistry Notes
... These chemical groups may be involved in chemical reactions or may contribute to the shape and function of the organic molecule in a characteristic way, giving it unique properties. o ...
... These chemical groups may be involved in chemical reactions or may contribute to the shape and function of the organic molecule in a characteristic way, giving it unique properties. o ...
PowerPoint Presentation - No Slide Title
... “nucleophile”- likes nuclei (likes protons: H+) Nucleophiles: electron-rich atoms or molecules that react with electrophiles. “electrophile”- likes electrons (likes minus: eand anions) Examples of nucleophiles ...
... “nucleophile”- likes nuclei (likes protons: H+) Nucleophiles: electron-rich atoms or molecules that react with electrophiles. “electrophile”- likes electrons (likes minus: eand anions) Examples of nucleophiles ...
Chapter 4
... o When two carbon atoms are joined by a double bond, all bonds around those carbons are in the same plane as the carbons. ...
... o When two carbon atoms are joined by a double bond, all bonds around those carbons are in the same plane as the carbons. ...
Document
... Aldehyde groups, where the C=O group is at the end of an organic molecule. A hydrogen atom is also located on the same carbon atom. Keto groups, where the C=O group is located within an organic molecule. All sugars have either a keto or an aldehyde group. An aldehyde and a ketone may be structural i ...
... Aldehyde groups, where the C=O group is at the end of an organic molecule. A hydrogen atom is also located on the same carbon atom. Keto groups, where the C=O group is located within an organic molecule. All sugars have either a keto or an aldehyde group. An aldehyde and a ketone may be structural i ...
Bonds - MCAT Cooperative
... Kinetics: rate depends only on the substrate, R=k[reactant] Stereochemistry: racemization of chiral substrates Favored with weak or bulky Nu, good LG, stable carbocation ...
... Kinetics: rate depends only on the substrate, R=k[reactant] Stereochemistry: racemization of chiral substrates Favored with weak or bulky Nu, good LG, stable carbocation ...
Lecture
... Saturated monocyclic rings are named according to ring size as 3-, iran; 4-, -etan; 5-, -olan; and 6-, -ane. Even this system does not apply to nitrogencontaining rings and finds only limited use in common practice. ...
... Saturated monocyclic rings are named according to ring size as 3-, iran; 4-, -etan; 5-, -olan; and 6-, -ane. Even this system does not apply to nitrogencontaining rings and finds only limited use in common practice. ...
No Slide Title
... “nucleophile”- likes nuclei (likes protons: H+) Nucleophiles: electron-rich atoms or molecules that react with electrophiles. “electrophile”- likes electrons (likes minus: eand anions) Examples of nucleophiles ...
... “nucleophile”- likes nuclei (likes protons: H+) Nucleophiles: electron-rich atoms or molecules that react with electrophiles. “electrophile”- likes electrons (likes minus: eand anions) Examples of nucleophiles ...
Chapter 8
... Group 1A and 2A metals have only 1 oxidation number. Transition metals and metals on the right side of the periodic table have more then 1 oxidation number – Fe2+ and O2- is FeO, named iron (II) oxide – Fe3+ and O2- is Fe2O3, named iron (III) oxide ...
... Group 1A and 2A metals have only 1 oxidation number. Transition metals and metals on the right side of the periodic table have more then 1 oxidation number – Fe2+ and O2- is FeO, named iron (II) oxide – Fe3+ and O2- is Fe2O3, named iron (III) oxide ...
Ionic and Covalent Bonding - Fall River Public Schools
... (Metal and a non-metal) Determine charges for each ion Overall charge of compound must be zero General formula for names: Cation + Anion Root-ide ...
... (Metal and a non-metal) Determine charges for each ion Overall charge of compound must be zero General formula for names: Cation + Anion Root-ide ...
Aromatic heterocycles 1: structures and reactions
... Benzene is aromatic because it has six electrons in a cyclic conjugated system. We know it is aromatic because it is exceptionally stable and it has a ring current and hence large chemical shifts in the proton NMR spectrum as well as a special chemistry involving substitution rather than addition wi ...
... Benzene is aromatic because it has six electrons in a cyclic conjugated system. We know it is aromatic because it is exceptionally stable and it has a ring current and hence large chemical shifts in the proton NMR spectrum as well as a special chemistry involving substitution rather than addition wi ...
File - Fortrose Chemistry
... 19Hydrocarbons (General) Hydrocarbons are: compounds that contain only carbon atoms and hydrogen atoms obtained from crude oil by fractional distillation and can be classified into different groups. The two groups that you need to know about for Standard Grade are called alkanes and alkenes. Remembe ...
... 19Hydrocarbons (General) Hydrocarbons are: compounds that contain only carbon atoms and hydrogen atoms obtained from crude oil by fractional distillation and can be classified into different groups. The two groups that you need to know about for Standard Grade are called alkanes and alkenes. Remembe ...
Biochemistry Review
... preventing the enzyme from working, are considered “negative” and result in noncompetitive inhibition. If a substance, in either of these cases, is an end product of the reactions brought on by the enzyme, than feedback inhibition occurs, a selfregulating system that stops the reaction when enough ...
... preventing the enzyme from working, are considered “negative” and result in noncompetitive inhibition. If a substance, in either of these cases, is an end product of the reactions brought on by the enzyme, than feedback inhibition occurs, a selfregulating system that stops the reaction when enough ...
Nahla abd elmoaty mohamed
... Chemical and biological studies on some Heterocyclic nitrogen derivatives ...
... Chemical and biological studies on some Heterocyclic nitrogen derivatives ...
Chemical Bonding for Biochemistry 3/19/04 version
... Biomolecules are Carbon Compounds •Chemistry of living organisms is organized around the element carbon (“carbon-based life forms”) •Molecules with covalently bonded carbon backbones are termed organic compounds. •Carbon accounts for 50% of the dry weight of cells •Carbon can form: ...
... Biomolecules are Carbon Compounds •Chemistry of living organisms is organized around the element carbon (“carbon-based life forms”) •Molecules with covalently bonded carbon backbones are termed organic compounds. •Carbon accounts for 50% of the dry weight of cells •Carbon can form: ...
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.