Slide 1
... – Carbonyl group—a carbon linked by a double bond to an oxygen atom – Carboxyl group—consists of a carbon doublebonded to both an oxygen and a hydroxyl group – Amino group—composed of a nitrogen bonded to two hydrogen atoms and the carbon skeleton – Phosphate group—consists of a phosphorus atom bond ...
... – Carbonyl group—a carbon linked by a double bond to an oxygen atom – Carboxyl group—consists of a carbon doublebonded to both an oxygen and a hydroxyl group – Amino group—composed of a nitrogen bonded to two hydrogen atoms and the carbon skeleton – Phosphate group—consists of a phosphorus atom bond ...
Powerpoint File - University of Evansville Faculty Web sites
... on its carbon skeleton, but also on certain groups of atoms that are covalently linked to the skeleton. These groups of atoms are called functional groups, the name reflecting the fact that these parts of the organic molecules usually are involved in chemical reactions. See Table 4.1 in Campbell and ...
... on its carbon skeleton, but also on certain groups of atoms that are covalently linked to the skeleton. These groups of atoms are called functional groups, the name reflecting the fact that these parts of the organic molecules usually are involved in chemical reactions. See Table 4.1 in Campbell and ...
OCR Chemistry A Basic concepts of organic chemistry Specification
... Can you interpret and use the term skeletal formula (the simplified organic formula, shown by removing hydrogen atoms from alkyl chains, leaving just a carbon skeleton and associated functional groups)? ...
... Can you interpret and use the term skeletal formula (the simplified organic formula, shown by removing hydrogen atoms from alkyl chains, leaving just a carbon skeleton and associated functional groups)? ...
Macromolecule Paper Modeling
... constructing models of each biochemical structure so that you have an understanding of how the structure helps the molecule perform certain functions. Sometimes it is difficult to visualize chemical reactions, especially biochemical ones. So we will be using paper models of the various organic polym ...
... constructing models of each biochemical structure so that you have an understanding of how the structure helps the molecule perform certain functions. Sometimes it is difficult to visualize chemical reactions, especially biochemical ones. So we will be using paper models of the various organic polym ...
Document
... Molarity, or moles per liter (M) A mole of an element or compound is equal to its atomic or molecular weight (sum of atomic weights) in grams One mole of any substance contains exactly the same number of solute particles (6.02 x 1023) 37. Colloids and Suspensions Colloids, or emulsions, are heteroge ...
... Molarity, or moles per liter (M) A mole of an element or compound is equal to its atomic or molecular weight (sum of atomic weights) in grams One mole of any substance contains exactly the same number of solute particles (6.02 x 1023) 37. Colloids and Suspensions Colloids, or emulsions, are heteroge ...
Chemistry in 7 Days
... • Water is very important in chemistry • It enables chemicals to react with each other • It is so important is almost a science on its own • So why is water so important in so many chemical reactions? ...
... • Water is very important in chemistry • It enables chemicals to react with each other • It is so important is almost a science on its own • So why is water so important in so many chemical reactions? ...
Today*s topic is*11 letters long
... reaction and that determines the properties of many organic compounds ...
... reaction and that determines the properties of many organic compounds ...
Arenes test - A-Level Chemistry
... In this question, one mark is available for the quality of use and organisation of scientific terms. Describe how benzene could be converted into nitrobenzene. State the reagents and conditions, give a balanced equation for each stage and show the structure of the product. ...
... In this question, one mark is available for the quality of use and organisation of scientific terms. Describe how benzene could be converted into nitrobenzene. State the reagents and conditions, give a balanced equation for each stage and show the structure of the product. ...
Ch 4 Slides - people.iup.edu
... chemistry that deals with carbon: organic chemistry • Vitalism was the idea that carbon compounds could only be produced by living organisms, ...
... chemistry that deals with carbon: organic chemistry • Vitalism was the idea that carbon compounds could only be produced by living organisms, ...
Ch 4 Slides
... chemistry that deals with carbon: organic chemistry • Vitalism was the idea that carbon compounds could only be produced by living organisms, ...
... chemistry that deals with carbon: organic chemistry • Vitalism was the idea that carbon compounds could only be produced by living organisms, ...
AP Ch. 25 Notes
... • When it is burned in the presence of oxygen (oxyacetylene torch) the temperature is about 5300º F! • Alkynes are named in the same way as alkenes with the suffix -yne replacing the -ene for alkenes. ...
... • When it is burned in the presence of oxygen (oxyacetylene torch) the temperature is about 5300º F! • Alkynes are named in the same way as alkenes with the suffix -yne replacing the -ene for alkenes. ...
CSUS Department of Chemistry Molecular Shapes Chem. 1A Page
... Molecular polarity is a physical property of compounds which relates to other physical properties such as melting and boiling points, solubility, and intermolecular interactions between molecules. For the most part, there is a direct correlation between the polarity of a molecule and number and ty ...
... Molecular polarity is a physical property of compounds which relates to other physical properties such as melting and boiling points, solubility, and intermolecular interactions between molecules. For the most part, there is a direct correlation between the polarity of a molecule and number and ty ...
Organic Chemistry
... • p-orbitals: two lobes with opposite signs, electrons further from nucleus ...
... • p-orbitals: two lobes with opposite signs, electrons further from nucleus ...
Chemistry Quiz #1
... No, both are non-metals. Ionic compounds require one atom to give electrons away (a metal) and one atom to receive electrons (a non-metals). That cannot happen here as both atoms are non-metal and tend to gain electrons in an ionic bond. Oxygen and Sulfur will end up sharing electrons and will form ...
... No, both are non-metals. Ionic compounds require one atom to give electrons away (a metal) and one atom to receive electrons (a non-metals). That cannot happen here as both atoms are non-metal and tend to gain electrons in an ionic bond. Oxygen and Sulfur will end up sharing electrons and will form ...
Practice: Chapter 21
... double bonds of alkenes cause them to be more reactive than alkanes. Alkynes are generally even more reactive than alkenes because of their triple bonds. 15.Yes; both compounds have the molecular formula C5H8, but they have different carbon chains. 16.The aromatic compounds are 1-methyl-4-propylbenz ...
... double bonds of alkenes cause them to be more reactive than alkanes. Alkynes are generally even more reactive than alkenes because of their triple bonds. 15.Yes; both compounds have the molecular formula C5H8, but they have different carbon chains. 16.The aromatic compounds are 1-methyl-4-propylbenz ...
Hydrocarbons - msottchemistry
... commonly H, O, N, S, and halogens • Carbon – Can form many different compounds due to its hybrid orbitals – Has intermediate electonegativity, so its most likely to form molecular compounds (Recall: molecular compounds have diverse properties) – Can make single, double, and triple bonds – Can form i ...
... commonly H, O, N, S, and halogens • Carbon – Can form many different compounds due to its hybrid orbitals – Has intermediate electonegativity, so its most likely to form molecular compounds (Recall: molecular compounds have diverse properties) – Can make single, double, and triple bonds – Can form i ...
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.