Difference between revisions of "Organic chemistry"

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''Article derived from the [http://en.wikipedia.org/wiki/Organic_chemistry Wikipedia article on organic chemistry].''
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'''Organic chemistry''' is a discipline within [[chemistry]] which involves the [[science|scientific]] study of the structure, properties, composition, [[chemical reaction|reactions]], and preparation (by [[organic synthesis|synthesis]] or by other means) of [[chemical compound]]s that contain [[carbon]].  These compounds may contain any number of other elements, including [[hydrogen]], [[nitrogen]], [[oxygen]], the [[halogens]] as well as [[phosphorus]], [[silicon]] and [[sulfur]].<ref>Robert T. Morrison, Robert N. Boyd, and Robert K. Boyd, ''Organic Chemistry'', 6th edition (Benjamin Cummings, 1992, ISBN 0-13-643669-2) - this is "Morrison and Boyd", a classic textbook</ref><ref>John D. Roberts, Marjorie C. Caserio, ''Basic Principles of Organic Chemistry'',(W. A. Benjamin,Inc.,1964) - another classic textbook</ref><ref>Richard F. and Sally J. Daley, ''Organic Chemistry'', Online organic chemistry textbook. http://www.ochem4free.info</ref>
  
'''Organic chemistry''' is a specific discipline within the subject of [[chemistry]]. It is the [[science|scientific]] study of the structure, properties, composition, [[chemical reaction|reactions]], and preparation (by [[organic synthesis|synthesis]] or by other means) of chemical compounds of [[carbon]] and [[hydrogen]], which may contain any number of other elements, such as [[nitrogen]], [[oxygen]], [[halogens]], and, more rarely, [[phosphorus]] or [[sulfur]] <ref>Robert T. Morrison, Robert N. Boyd, and Robert K. Boyd, ''Organic Chemistry'', 6th edition (Benjamin Cummings, 1992, ISBN 0-13-643669-2) - this is "Morrison and Boyd", a classic textbook</ref> <ref>Richard F. and Sally J. Daley, ''Organic Chemistry'', www.ochem4free.com, Online organic chemistry textbook.</ref>.
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The original definition of "organic" chemistry came from the misconception that organic compounds were always related to [[life]] processes.  However, organic molecules can be produced by processes not involving life. Life as we know it also depends on [[inorganic chemistry]].  For example, many [[enzyme]]s rely on [[transition metal]]s such as [[iron]] and [[copper]]; and materials such as shells, teeth and bones are part organic, part inorganic in composition.  Apart from elemental carbon, only certain classes of carbon compounds (such as [[oxide]]s, [[carbonates]], and [[carbide]]s) are conventionally considered inorganic. [[Biochemistry]] deals mainly with the natural chemistry of biomolecules such as [[protein]]s, [[nucleic acid]]s, and [[sugar]]s.
  
The original definition of organic chemistry came from the misperception that these compounds were always related to [[life]] processes, but now it is known that life also depends heavily on [[inorganic chemistry]]; for example, many enzymes rely on transition metals such as iron and copper; and materials such as shells, teeth and bones are part organic, part inorganic in composition.  Inorganic chemistry deals, apart from elemental carbon, only with simple carbon compounds, with molecular structures which do not contain carbon to carbon connections (its oxides, acids, salts, carbides, and minerals).  This does not mean that single-carbon organic compounds do not exist (viz. [[methane]] and its simple derivatives).  Compounds that are related to life processes are dealt with in the branch of chemistry which is called [[biochemistry]].
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Because of their unique properties, multi-carbon compounds exhibit extremely large variety and the range of application of organic compounds is enormous. They form the basis of, or are important constituents of many products ([[paint]]s, [[plastic]]s, [[food]], [[explosive]]s, [[drug]]s, [[petrochemical]]s, to name but a few) and (apart from a very few exceptions) they form the basis of all earthly life processes.
  
Because of their unique properties, multi-carbon compounds exhibit extremely large variety and the range of application of organic compounds is enormous. They form the basis of or are important constituents of many products ([[paint]]s, [[plastic]]s, [[food]], [[explosive]]s, [[drug]]s, [[petrochemical]]s, and many others) and of course (apart from a very few exceptions) they form the basis of all life processes.
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The different shapes and chemical reactivities of organic molecules provide an astonishing variety of functions, like those of enzyme [[catalyst]]s in biochemical reactions of live systems.  
  
The different shapes and chemical reactivities of organic molecules provide an astonishing variety of functions, like those of [[enzyme]] [[catalyst]]s in biochemical reactions of live systems. The autopropagating nature of these is what life is all about.
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Current (as of 2008) trends in organic chemistry include [[chiral synthesis]], [[green chemistry]], [[microwave chemistry]], [[fullerene]]s and [[rotational spectroscopy|microwave spectroscopy]].
  
Because of the special properties of carbon, it is likely that life on other [[star]] systems will be found to be carbon-based, in spite of speculations about the possibility of substituting [[silicon]], which lies just below carbon in the [[periodic table]].
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==Historical highlights==
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{{Main|History of chemistry}}
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[[Image:Friedrich woehler.jpg|right|thumb|[[Friedrich Wöhler]]]]
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At the very beginning of the nineteenth century chemists generally thought that compounds from living organisms were too complicated in structure to be capable of artificial [[Chemical synthesis|synthesis]] from non-living things, and that a 'vital force' or [[vitalism]] conferred the characteristics of living beings on this form of matter. They named these compounds 'organic', and preferred to direct their investigations toward inorganic materials that seemed more promising.
  
Trends in organic chemistry include [[chiral synthesis]], [[green chemistry]], [[microwave chemistry]], [[fullerene]]s and [[rotational spectroscopy|microwave spectroscopy]].
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Organic chemistry received a boost when it was realized that these compounds could be treated in ways similar to [[inorganic compound]]s and could be created in the laboratory by means other than 'vital force'. Around 1816 [[Michel Eugène Chevreul|Michel Chevreul]] started a study of [[soap]]s made from various [[fat]]s and [[alkali]]. He separated the different acids that, in combination with the alkali, produced the soap.  Since these were all individual compounds, he demonstrated that it was possible to make a chemical change in various fats (which traditionally come from  organic sources), producing new compounds, without 'vital force'. In 1828 [[Friedrich Wöhler]] first manufactured the organic chemical [[urea]] (carbamide), a constituent of [[urine]], from the inorganic [[Cyanate|ammonium cyanate]] NH<sub>4</sub>OCN, in what is now called the [[Wöhler synthesis]].  Although Wöhler was, at this time as well as afterwards, cautious about claiming that he had thereby destroyed the theory of vital force, most
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have looked to this event as the turning point.
  
==Historic highlights==
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A great next step was when in 1856 [[Sir William Henry Perkin|William Henry Perkin]], while trying to manufacture [[quinine]], again accidentally came to manufacture the organic [[dye]] now called [[Perkin's mauve]], which by generating a huge amount of money greatly increased interest in organic chemistry. Another step was the laboratory preparation of [[DDT]] by Othmer Zeidler in 1874, but the [[insecticide]] properties of this compound were not discovered until much later.
[[Image:Friedrich woehler.jpg|right|thumb|200px|[[Friedrich Wöhler]]]]
 
  
Towards the beginning of the nineteenth century, chemists generally thought that compounds from living organisms were too complicated in structure and that these compounds, through a 'vital force' or [[vitalism]], were unique in that they could self-propagate. They named these compounds 'organic' and proceeded to ignore them.
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The crucial breakthrough for the theory of organic chemistry was the concept of chemical structure, developed independently and simultaneously by [[Friedrich August Kekule]] and [[Archibald Scott Couper]] in 1858.  Both men suggested that [[valence (chemistry)|tetravalent]] carbon atoms could link to each other to form a carbon lattice, and that the detailed patterns of atomic bonding could be discerned by skillful interpretations of appropriate chemical reactions.
  
Organic chemistry received a boost when it was realized that these compounds could be treated in ways similar to [[inorganic compound]]s and could be manufactured by means other than 'vital force'. Around 1816 [[Michel Chevreuil]] started a study of [[soap]]s made from various [[fat]]s and [[alkali]]. He separated the different [[acid]]s that, in combination with the alkali, produced the soap.  Since these were all individual compounds, he demonstrated that it was possible to make a chemical change in various fats (which traditionally come from  organic sources), producing new compounds, without 'vital force'.
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The history of organic chemistry continues with the discovery of [[petroleum]] and its separation into [[Fraction (chemistry)|fraction]]s according to boiling ranges. The conversion of different compound types or individual compounds by various chemical processes created the petroleum chemistry leading to the birth of the [[petrochemical]] industry, which successfully manufactured artificial [[rubber]]s, the various organic [[adhesive]]s, the property-modifying petroleum additives, and [[plastic]]s.  
  
The real event that has completely destroyed the myth of 'vitalism' occurred, however, when in [[1828]] [[Friedrich Wöhler]] first manufactured the organic chemical [[urea]] (carbamide), a constituent of the liquid waste matter urine from the inorganic [[cyanates|ammonium cyanate]] NH<sub>4</sub>OCN, in what is now called the [[Wöhler synthesis]].
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The [[pharmaceutical]] industry began in the last decade of the 19th century when acetylsalicylic acid (more commonly referred to as [[aspirin]]) manufacture was started in Germany by [[Bayer]]. The first time a drug was systematically improved was with [[arsphenamine]] (Salvarsan). Numerous derivatives of the dangerously toxic [[atoxyl]] were systematically synthesized and tested by [[Paul Ehrlich]] and his group, and the compound with best effectiveness and toxicity characteristics was selected for production.
  
A great next step was when in 1856 [[William Henry Perkin]], while trying to manufacture [[quinine]], again accidentally came to manufacture the organic dye now called [[Perkin's mauve]], which by generating a huge amount of money greatly increased interest in organic chemistry. Another step was the laboratory preparation of [[DDT]] by Othmer Zeidler in 1874, but the insecticide properties of this compound were not discovered till much later.
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Early examples of organic reactions and applications were [[Serendipity|serendipitous]], such as Perkin's accidental discovery of Perkin's mauve. However, from the 20th century, the progress of organic chemistry allowed for synthesis of specifically selected compounds or even molecules designed with specific properties, as in [[drug design]]. The process of finding new synthesis routes for a given compound is called total synthesis. [[Total synthesis]] of complex natural compounds started with [[urea]], increased in complexity to [[glucose]] and [[terpineol]], and in 1907, total synthesis was commercialized the first time by [[Gustaf Komppa]] with [[camphor]]. Pharmaceutical benefits have been substantial, for example [[cholesterol]]-related compounds have opened ways to synthesis of complex human hormones and their modified derivatives. Since the start of the 20th century, complexity of total syntheses has been increasing, with examples such as [[lysergic acid]] and [[vitamin B12]]. Today's targets feature
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tens of [[stereogenic center]]s that must be synthesized correctly with [[asymmetric synthesis]].
  
The history of organic chemistry continues with the discovery of [[petroleum]] and its separation into [[fraction]]s according to boiling ranges. The conversion of different compound types or individual compounds by various chemical processes created the petroleum chemistry leading to the birth of the petrochemical industry, which successfully manufactured artificial rubbers, the various organic adhesives, the property modifying petroleum additives, and plastics.
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[[Biochemistry]], the chemistry of living organisms, their structure and interactions [[in vitro]] and inside living systems, has only started in the 20th century, opening up a brand new chapter of organic chemistry with enormous scope.
 
 
The pharmaceutical industry began in the last decade of the 19th century when acetylsalicylic acid ([[aspirin]]) manufacture was started in Germany by [[Bayer]].
 
 
 
[[Biochemistry]], the chemistry of living organisms, their structure and interactions in vitro and inside living systems, has only started in the 20th century, opening up a brand new chapter of organic chemistry with enormous scope.
 
  
 
==Classification of organic substances==
 
==Classification of organic substances==
 
===Description and nomenclature===
 
===Description and nomenclature===
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Classification is not possible without having a full description of the individual compounds.  
 
Classification is not possible without having a full description of the individual compounds.  
In contrast with [[inorganic chemistry]], in which describing a [[chemical compound]] could be achieved by simply enumerating the chemical symbols of the [[chemical element|elements]] present in the compound together with the number of these elements in the molecule, in organic chemistry the relative arrangement of the atoms within a molecule has to be added for a full description.
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In contrast with [[inorganic chemistry]], in which describing a [[chemical compound]] can be achieved by simply enumerating the chemical symbols of the [[chemical element|elements]] present in the compound together with the number of these elements in the molecule, in organic chemistry the relative arrangement of the atoms within a molecule must be added for a full description.
  
One way of describing the molecule is by drawing its [[structural formula]]. Because of the complexity this method has changed, becoming simplified over the years. The latest version is the line formula, which achieves simplicity without introducing ambiguity, whilst representing carbon and hydrogen by implication. The disadvantage which arises from the fact that structural formulae cannot be described by words, and that they are not easily printable does not arise when the structure is described by the [[organic nomenclature]] .   
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One way of describing the molecule is by drawing its [[structural formula]]. Because of molecular complexity, simplified systems of chemical notation have been developed. The latest version is the [[Bond line formula|line-angle formula]], which achieves simplicity without introducing ambiguity.  In this system, the endpoints and intersections of each line represent one carbon, and hydrogens can either be notated or assumed to be present by implication. Some disadvantages of chemical notation are that they are not easily described by words and they are not easily printable.  These problems have been addressed by describing molecular structures using [[organic nomenclature]] .   
  
Because of the difficulty due to the very large number and variety of organic compounds, chemists realized early on that the establishment of an internationally accepted system of naming organic compounds was of paramount importance. The Geneva Nomenclature was born in 1892 as a result of a number of international meetings on the subject.
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Because of the difficulties arising from the very large number and variety of organic compounds, chemists realized early on that the establishment of an internationally accepted system of naming organic compounds was of paramount importance. The Geneva Nomenclature was born in 1892 as a result of a number of international meetings on the subject.
  
It was also realized that as the family of organic compounds grew, the system would have to be expanded and modified. This task was ultimately taken on by the International Union on Pure and Applied Chemistry, [[IUPAC]].  
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It was also realized that as the family of organic compounds grew, the system would have to be expanded and modified. This task was ultimately taken on by the International Union on Pure and Applied Chemistry ([[IUPAC]]). Recognizing the fact that in the branch of biochemistry the complexity of organic structures increases, the IUPAC organization joined forces with the [[International Union of Biochemistry and Molecular Biology]], IUBMB, to produce a list of joint recommendations on nomenclature.
  
Recognizing the fact that in the branch of Biochemistry, the complexity of organic structures increases, the IUPAC organisation joined forces with [[IUBMB]], the [[International Union of Biochemistry and Molecular Biology]], to produce a list of joint recommendations on nomenclature.
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Later, as the numbers and complexities of organic molecules grew, new recommendations were made within IUPAC for simplification. The first such recommendation was presented in 1951 when a cyclic benzene structure was named a [[cyclophane]]. Later recommendations extended the method to the simplification of other complex cyclic structures, including heterocyclics, and named such structures ''[[phanes (organic chemistry)|phanes]]''.
  
Further on, as number and complexity grew, new recommendations were made within IUPAC for simplification. The first such recommendation was presented in 1951 when a cyclic benzene structure was named a [[cyclophane]]. Later recommendations extended the method to the simplification of other complex cyclic structures, including for instance heterocyclics as well, and named such structures ''[[phanes (organic chemistry)|phanes]]''.
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For ordinary communication, to spare a tedious description, the official IUPAC naming recommendations are not always followed in practice except when it is necessary to give a concise definition to a compound, or when the IUPAC name is simpler (viz. ''ethanol'' versus ''ethyl alcohol''). Otherwise the ''common'' or [[trivial name]] may be used, often derived from the source of the compound.
  
For ordinary communication, to spare a tedious description, the official IUPAC naming recommendations are not always followed in practice except when it is necessary to give a concise definition to a compound, or when the IUPAC name is simpler (viz. ''ethanol'' against ''ethyl alcohol''). Otherwise the ''common'' or [[trivial name]] may be used, often derived from the source of the compound.
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In summary, organic substances are classified by their molecular structural arrangement and by what other atoms are present along with the chief (carbon) constituent in their makeup, whilst in a structural formula, hydrogen is implicitly assumed to occupy all free valences of an appropriate carbon atom which remain after accounting for branching, other element(s) and/or multiple bonding.
  
=== Classification ===  
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=== Hydrocarbons  and functional groups ===
'''In summary''': organic substances are classified by their molecular structural arrangement and by what other atoms are present with the chief (carbon) constituent in their makeup, whilst in a structural formula, hydrogen is implicitly assumed to occupy all free valencies of an appropriate carbon atom, which remain after accounting for branching, other element(s) and/or multiple bonding.
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{{Main|Hydrocarbon|Functional group}}
 
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[[Image:Acetic acid atoms.svg|right|thumb|The family of [[carboxylic]] acids contains a carboxyl (-COOH) [[functional group]]. [[Acetic acid]] is an example.]]
==== Hydrocarbons  and Functional Groups ====
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Classification normally starts with the hydrocarbons: compounds which contain only carbon and hydrogen. For sub-classes see below. Other elements present themselves in atomic configurations called functional groups which have decisive influence on the chemical and physical characteristics of the compound; thus those containing the same atomic formations have similar characteristics, which may be: [[miscibility]] with water, [[acidity]]/[[alkalinity]], chemical [[reactivity]], [[oxidation]] resistance, and others. Some functional groups are also [[Radical (chemistry)|radicals]], similar to those in inorganic chemistry, defined as ''[[Chemical polarity|polar]]'' atomic configurations which pass during chemical reactions from one chemical compound into another without change.
Classification normally starts with the [[hydrocarbons]]: compounds which contain only carbon and hydrogen. For sub-classes see below. Other elements, present themselves in atomic configurations called [[functional groups]] which have decisive influence on the chemical and physical characteristics of the compound; thus those containing the same atomic formations have similar characteristics, which may be [[miscibility]] with water, [[acidity]]/ [[alkalinity]], chemical [[reactivity]], [[oxidation]] resistance, or others. Some functional groups are also radicals, similar to those in inorganic chemistry, defined as ''polar'' atomic configurations which pass during chemical reactions from one chemical compound into another without change.
 
  
 
Some of the elements of the functional groups (O, S, N, [[halogens]]) may stand alone and the ''group'' name is not strictly appropriate, but because of their decisive effect on the way they modify the characteristics of the hydrocarbons in which they are present they are classed with the functional groups, and their specific effect on the properties lends excellent means for characterisation and classification.
 
Some of the elements of the functional groups (O, S, N, [[halogens]]) may stand alone and the ''group'' name is not strictly appropriate, but because of their decisive effect on the way they modify the characteristics of the hydrocarbons in which they are present they are classed with the functional groups, and their specific effect on the properties lends excellent means for characterisation and classification.
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Reference is made here again to the [[organic nomenclature]], which shows an extensive (if not comprehensive) number of classes of compounds according to the presence of various functional groups, based on the [[IUPAC]] recommendations, but also some based on [[trivial name]]s. Putting compounds in sub-classes becomes more difficult when more than one functional group is present.
 
Reference is made here again to the [[organic nomenclature]], which shows an extensive (if not comprehensive) number of classes of compounds according to the presence of various functional groups, based on the [[IUPAC]] recommendations, but also some based on [[trivial name]]s. Putting compounds in sub-classes becomes more difficult when more than one functional group is present.
  
Two overarching chain type categories exist: Open Chain [[aliphatic]] compounds and Closed Chain [[cyclic compound]]s. Those in which both open chain and cyclic parts are present are normally classed with the latter.
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Two overarching chain type categories exist: open chain [[aliphatic]] compounds and closed chain [[cyclic compound]]s. Those in which both open chain and cyclic parts are present are normally classed with the latter.
  
==== Aliphatic compounds ====
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=== Aliphatic compounds ===
The aliphatic hydrocarbons are subdivided into three groups, [[homologous series]] according to their state of [[Saturation (chemistry)|saturation]]: paraffins [[alkane]]s without any double or triple bonds, olefins [[alkene]]s with double bonds, which can be mono-olefins  with a single double bond, di-olefins, or di-enes with two, or poly-olefins with more. The third group with a triple bond is named after the name of the shortest member of the homologue series as the acetylenes [[alkyne]]s. The rest of the group is classed according to the functional groups present.
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{{Main|Aliphatic compound}}
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The aliphatic hydrocarbons are subdivided into three groups of [[homologous series]] according to their state of [[Saturation (chemistry)|saturation]]: paraffins [[alkane]]s without any double or triple bonds, olefins [[alkene]]s with double bonds, which can be mono-olefins  with a single double bond, di-olefins, or di-enes with two, or poly-olefins with more. The third group with a triple bond is named after the name of the shortest member of the homologue series as the acetylenes [[alkyne]]s. The rest of the group is classed according to the functional groups present.
  
 
From another aspect aliphatics can be straight chain or branched chain compounds, and the degree of branching also affects characteristics, like  [[octane number]] or [[cetane number]] in petroleum chemistry.
 
From another aspect aliphatics can be straight chain or branched chain compounds, and the degree of branching also affects characteristics, like  [[octane number]] or [[cetane number]] in petroleum chemistry.
  
==== Aromatic and alicyclic compounds ====
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=== Aromatic and alicyclic compounds ===
Cyclic compounds can, again, be saturated or unsaturated. Because of the bonding angle of carbon, the most stable configurations contain six carbon atoms, but while rings with five carbon atoms are also frequent, others are rarer. The cyclic hydrocarbons divide into [[alicyclic]]s and [[aromatic]]s (also called [[arene]]s).
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[[Image:Benzene-resonance-structures.svg|right|thumb|[[Benzene]] is one of the best-known aromatic compounds as it is one of the simplest aromatics.]]
 
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Cyclic compounds can, again, be saturated or unsaturated. Because of the bonding angle of carbon, the most stable configurations contain six carbon atoms, but while rings with five carbon atoms are also frequent, others are rarer. The cyclic hydrocarbons divide into [[alicyclic]]s and [[aromatic]]s (also called [[arene compound|arene]]s).  
Of the [[alicyclic]] compounds the [[cycloalkane]]s do not contain multiple bonds, whilst the [[cycloalkene]]s and  the [[cycloalkyne]]s do. Typically this latter type only exists in the form of large rings, called macrocycles. The simplest member of the cycloalkane family is the three-membered [[cyclopropane]].
 
  
[[Aromatic]] hydrocarbons contain [[conjugation|conjugated]] double bonds. One of the simplest examples of these is [[benzene]], the structure of which was formulated by [[Kekulé]] who first proposed the [[delocalization]] or [[Resonance (chemistry)|resonance]] principle for explaining its structure.  For "conventional" cyclic compounds, [[aromaticity]] is conferred by the presence of 4n + 2 delocalized pi electrons, where n is an integer.  Particular instability (antiaromaticity) is conferred by the presence of 4n conjugated pi electrons.
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Of the alicyclic compounds the [[cycloalkane]]s do not contain multiple bonds, whilst the [[cycloalkene]]s and the cycloalkynes do. Typically this latter type only exists in the form of large rings, called [[macrocycle]]s. The simplest member of the cycloalkane family is the three-membered [[cyclopropane]].
  
The characteristics of the cyclic hydrocarbons are again altered if heteroatoms are present, which can exist as either substituents attached externally to the ring (exocyclic) or as a member of the ring itself (endocyclic). In the case of the latter, the ring is termed a [[heterocycle]][[Pyridine]] and [[furan]] are examples of aromatic heterocycles while [[piperidine]] and [[tetrahydrofuran]] are the corresponding alicyclic heterocycles.  
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[[Aromatic]] hydrocarbons contain [[Conjugated system|conjugated]] double bonds. One of the simplest examples of these is [[benzene]], the structure of which was formulated by [[Kekulé]] who first proposed the [[Delocalized electron|delocalization]] or [[Resonance (chemistry)|resonance]] principle for explaining its structure.  For "conventional" cyclic compounds, aromaticity is conferred by the presence of 4n + 2 delocalized pi electrons, where n is an integer.  Particular instability ([[antiaromaticity]]) is conferred by the presence of 4n conjugated pi electrons.
  
The heteroatom of heterocyclic molecules is generally oxygen, sulfur, or nitrogen, with the latter being particularly common in biochemical systems.
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The characteristics of the cyclic hydrocarbons are again altered if heteroatoms are present, which can exist as either substituents attached externally to the ring (exocyclic) or as a member of the ring itself (endocyclic). In the case of the latter, the ring is termed a [[heterocycle]].  [[Pyridine]] and [[furan]] are examples of aromatic heterocycles while [[piperidine]] and [[tetrahydrofuran]] are the corresponding alicyclic heterocycles. The heteroatom of heterocyclic molecules is generally oxygen, sulfur, or nitrogen, with the latter being particularly common in biochemical systems.
  
Rings can fuse with other rings on an edge to give polycyclic compounds. The [[purine]] nucleoside bases are notable polycyclic aromatic heterocycles.  Rings can also fuse on a "corner" such that one atom (almost always carbon) has two bonds going to one ring and two to another.  Such compounds are termed [[spiro compound|spiro]] and are important in a number of [[natural product]]s.
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Rings can fuse with other rings on an edge to give [[polycyclic compound]]s. The [[purine]] nucleoside bases are notable polycyclic aromatic heterocycles.  Rings can also fuse on a "corner" such that one atom (almost always carbon) has two bonds going to one ring and two to another.  Such compounds are termed [[spiro compound|spiro]] and are important in a number of [[natural product]]s.
  
====Polymers====
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===Polymers===
One important property of carbon in organic chemistry is that it can form certain compounds, the individual molecules of which are capable of attaching themselves to one another, thereby forming  a chain or a network. The process is called [[polymerisation]] and the chains or networks [[polymers]], whilst the source compound is a [[monomer]]. Two main groups of polymers exist: those artificially manufactured are referred to as [[plastics|industrial polymers]] <ref>"industrial polymers, chemistry of." Encyclopædia Britannica. 2006 </ref>
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{{Main|Polymer}}
or synthetic [[polymers]] and those naturally occurring as [[biopolymer]]s.   
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[[Image:Girl with styrofoam swimming board.jpg|right|thumb|This swimming board is made of [[polystyrene]], an example of a polymer]]
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One important property of carbon in organic chemistry is that it can form certain compounds, the individual molecules of which are capable of attaching themselves to one another, thereby forming  a chain or a network. The process is called [[polymerization]] and the chains or networks polymers, while the source compound is a [[monomer]]. Two main groups of polymers exist: those artificially manufactured are referred to as [[plastic|industrial polymers]] <ref>"industrial polymers, chemistry of." Encyclopædia Britannica. 2006 </ref>
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or synthetic polymers and those naturally occurring as [[biopolymer]]s.   
  
Since the invention of the first artificial polymer, [[bakelite]], the family has quickly grown with the invention of others. Common synthetic organic polymers are [[polyethylene]] or polythene, [[polypropylene]], [[nylon]], [[teflon]] or PTFE, [[polystyrene]], [[polyester]]s,  [[polymethylmethacrylate]] (commonly known as perspex or plexiglas) [[polyvinylchloride]] or PVC, and [[polyisobutylene]]  important artificial or synthetic [[rubber]] also the polymerised [[butadiene]], a rubber component.
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Since the invention of the first artificial polymer, [[bakelite]], the family has quickly grown with the invention of others. Common synthetic organic polymers are [[polyethylene]] or polythene, [[polypropylene]], [[nylon]], [[polytetrafluoroethylene|teflon]] or PTFE, [[polystyrene]], [[polyester]]s,  [[polymethylmethacrylate]] (commonly known as perspex or plexiglas) [[polyvinylchloride]] or PVC, and [[polyisobutylene]]  an important artificial or synthetic [[rubber]] also the polymerised [[butadiene]], a rubber component.
  
The examples are generic terms, and many varieties of each of these may exist, with their physical characteristics fine tuned for a specific use. Changing the conditions of polymerisation changes the chemical composition of the product by altering [[degree of polymerization|chain length]], or [[branching]], or the [[tacticity]]. With a single monomer as a start the product is a [[homopolymer]]. Further, secondary component(s) may be added to create a [[copolymer|heteropolymer]] (co-polymer) and the degree of clustering of the different components can also be controlled. Physical characteristics, such as hardness, [[density]], mechanical or [[tensile strength]], abrasion resistance, heat resistance, transparency, colour, etc. will depend on the final composition.  
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The examples are generic terms, and many varieties of each of these may exist, with their physical characteristics fine tuned for a specific use. Changing the conditions of polymerisation changes the chemical composition of the product by altering [[degree of polymerization|chain length]], or [[branching]], or the [[tacticity]]. With a single monomer as a start the product is a [[homopolymer]]. Further, secondary component(s) may be added to create a [[copolymer|heteropolymer]] (co-polymer) and the degree of clustering of the different components can also be controlled. Physical characteristics, such as hardness, [[density]], mechanical or [[tensile strength]], abrasion resistance, heat resistance, transparency, colour, etc. will depend on the final composition.
  
The only other element that can produce polymers is silicon. The [[silicones]], however, show one major difference from carbon based polymers, inasmuch as  unlike the direct C-C bonds of those based on carbon in silicones the Si atoms are joined indirectly through oxygen links.
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===Biomolecules===
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[[Image:Maitotoxin.png|400px|thumb|right|[[Maitotoxin]], a complex organic biological toxin.]]
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[[Biomolecule|Biomolecular chemistry]] is a major category within organic chemistry which is frequently studied by [[biochemists]].  Many complex multi-functional group molecules are important in living organisms. Some are long-chain [[biopolymers]], and these include [[proteins]], [[DNA]], [[RNA]] and the [[polysaccharides]] such as [[starch]]es in animals and [[cellulose]]s in plants. The other main classes are [[amino acid]]s (monomer building blocks of proteins), [[carbohydrates]] (which includes the polysaccharides), the [[nucleic acids]] (which include DNA and RNA as polymers), and the [[lipid]]s. In addition, animal biochemistry contains many small molecule intermediates which assist in energy production through the [[Krebs cycle]], and produces [[isoprene]], the most common hydrocarbon in animals. Isoprenes in animals form the important [[steroid]] structural ([[cholesterol]]) and steroid hormone compounds; and in plants form [[terpene]]s, [[terpenoids]], some [[alkaloids]], and a unique set of
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structural hydrocarbons called biopolymer polyisoprenoids present in [[latex]] sap which is the basis for making [[rubber]].
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===Small molecules===
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In pharmacology, an important group of organic compounds is [[small molecule]]s, also referred to as 'small organic compounds'. In this context, a small molecule is a small organic compound that is biologically active, but is not a [[polymer]]. In practice, small molecules have a [[molar mass]] less than approximately 1000 g/mol.
  
====Biomolecules====
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===Fullerenes===
[[Biomolecule|Biomolecular chemistry]] is a major category within organic chemistry.  Many complex multi-functional group molecules are important in living organisms. Some are long-chain [[biopolymers]]. The main classes are [[carbohydrate]]s, [[amino acid]]s and [[protein]]s, [[polysaccharide]]s, [[lipid]]s, and [[nucleic acid]]s.
+
[[Fullerene]]s are among the types of compounds engineered by organic chemists that have generated the most interest. The discovery of their unique electronic properties due to their spherical structure has stimulated new research into related fields such as [[carbon nanotube]]s.
  
====Others====
+
===Others===
Organic compounds containing bonds of carbon to nitrogen, oxygen and the halogens are not normally grouped separately. Others are sometimes put into major groups within organic chemistry and discussed under titles such as [[organosulfur chemistry]], [[organometallic chemistry]], [[organophosphorus chemistry]] and [[organosilicon chemistry]].
+
Organic compounds containing bonds of carbon to nitrogen, oxygen and the halogens are not normally grouped separately. Others are sometimes put into major groups within organic chemistry and discussed under titles such as [[organosulfur chemistry]], [[organometallic chemistry]], [[organophosphorus chemistry]] and [[Organosilicon|organosilicon chemistry]].
  
 
==Characteristics of organic substances==
 
==Characteristics of organic substances==
Organic compounds are generally [[covalent bond|covalently bonded]].  This allows for unique structures such as long carbon chains and rings. The reason carbon is excellent at forming unique structures and that there are so many carbon compounds is that carbon atoms form very stable covalent bonds with one another ([[catenation]]). In contrast to inorganic materials, organic compounds typically melt, boil, sublimate, or decompose below 300&nbsp;°C. Neutral organic compounds tend to be less [[soluble]] in [[water]] compared to many inorganic [[salts]], with the exception of certain compounds such as ionic organic compounds and low [[molecular weight]] [[alcohols]] and [[carboxylic acids]] where [[hydrogen bonding]] occurs.
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[[Image:Covalent.svg|right|thumb|The structure of [[methane]] by pictorial representation of a [[Lewis diagram]] showing the sharing of electronpairs between atomic nuclei in a covalent  bond.  However, in reality, the structure is not two-dimensional.]]
 +
Organic compounds are generally [[covalent bond|covalently bonded]].  This allows for unique structures such as long carbon chains and rings. The reason carbon is excellent at forming unique structures and that there are so many carbon compounds is that carbon atoms form very stable covalent bonds with one another ([[catenation]]). In contrast to inorganic materials, organic compounds typically melt, boil, sublimate, or decompose below 300 °C. Neutral organic compounds tend to be less [[soluble]] in [[water]] compared to many inorganic [[salts]], with the exception of certain compounds such as ionic organic compounds and low [[molecular weight]] [[alcohols]] and [[carboxylic acids]] where [[hydrogen bonding]] occurs.
  
Organic compounds tend rather to dissolve in organic [[solvent]]s which are either pure substances like [[diethyl ether|ether]] or [[ethanol|ethyl alcohol]], or mixtures, such as the paraffinic solvents such as the various [[petroleum ether]]s and [[white spirit]]s, or the range of pure or mixed aromatic solvents obtained from petroleum or tar [[fraction]]s by physical separation or by chemical conversion. Solubility in the different solvents depends upon the solvent type and on the [[functional groups]] if present. Solutions are studied by the science of [[Physical Chemistry]]. Like inorganic salts, organic compounds may also form [[crystal]]s. Unique property of carbon in [[organic compound]]s is that its valency does not always have to be taken up by atoms of other elements, and when it is not, a condition termed [[unsaturation]] results. In such cases we talk about carbon carbon [[double bonds]] or [[alkyne|triple bonds]]. Double bonds alternating with single in a chain are called [[Conjugated system|conjugated]] double bonds. An [[aromatic]] structure is a special case in which the conjugated chain is a closed ring.
+
Organic compounds tend to dissolve in organic [[solvent]]s which are either pure substances like [[diethyl ether|ether]] or [[ethanol|ethyl alcohol]], or mixtures, such as the paraffinic solvents such as the various [[petroleum ether]]s and [[white spirit]]s, or the range of pure or mixed aromatic solvents obtained from petroleum or tar [[Fraction (chemistry)|fraction]]s by physical separation or by chemical conversion. Solubility in the different solvents depends upon the solvent type and on the [[functional groups]] if present. Solutions are studied by the science of [[physical chemistry]]. Like inorganic salts, organic compounds may also form [[crystal]]s. A unique property of carbon in [[organic compound]]s is that its valency does not always have to be taken up by atoms of other elements, and when it is not, a condition termed [[unsaturation]] results. In such cases we talk about carbon carbon [[double bonds]] or [[alkyne|triple bonds]]. Double bonds alternating with single in a chain are called
 +
[[Conjugated system|conjugated]] double bonds. An [[aromatic]] structure is a special case in which the conjugated chain is a closed ring.
  
 
==Molecular structure elucidation==
 
==Molecular structure elucidation==
 +
[[Image:Cafeïne.png|right|thumb|Molecular models of [[caffeine]]]]
 
[[Organic compounds]] consist of carbon atoms, hydrogen atoms, and [[functional groups]]. The [[valence (chemistry)|valence]] of carbon is 4, and hydrogen is 1, functional groups are generally 1. From the number of carbon atoms and hydrogen atoms in a molecule the [[degree of unsaturation]] can be obtained. Many, but not all structures can be envisioned by the simple valence rule that there will be one bond for each valence number. The knowledge of the [[chemical formula]] for an organic compound is not sufficient information because many [[isomer]]s can exist.  
 
[[Organic compounds]] consist of carbon atoms, hydrogen atoms, and [[functional groups]]. The [[valence (chemistry)|valence]] of carbon is 4, and hydrogen is 1, functional groups are generally 1. From the number of carbon atoms and hydrogen atoms in a molecule the [[degree of unsaturation]] can be obtained. Many, but not all structures can be envisioned by the simple valence rule that there will be one bond for each valence number. The knowledge of the [[chemical formula]] for an organic compound is not sufficient information because many [[isomer]]s can exist.  
 
Organic compounds often exist as [[mixture]]s. Because many organic compounds have relatively low [[boiling point]]s and/or dissolve easily in organic [[solvent]]s there exist many methods for separating mixtures into pure constituents that are specific to organic chemistry such as [[distillation]], [[crystallization]] and [[chromatography]] techniques.
 
Organic compounds often exist as [[mixture]]s. Because many organic compounds have relatively low [[boiling point]]s and/or dissolve easily in organic [[solvent]]s there exist many methods for separating mixtures into pure constituents that are specific to organic chemistry such as [[distillation]], [[crystallization]] and [[chromatography]] techniques.
There exist several methods for deducing the structure an organic compound.  In general usage are (in alphabetical order):
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There exist several methods for deducing the structure of an organic compound.  In general usage are (in alphabetical order):
  
* [[Crystallography]]: This is the most precise method for determining [[molecular geometry]]; however, it is very difficult to grow crystals of sufficient size and high quality to get a clear picture, so it remains a secondary form of analysis.
+
* [[Crystallography]]: This is the most precise method for determining [[molecular geometry]]; however, it is very difficult to grow crystals of sufficient size and high quality to get a clear picture, so it remains a secondary form of analysis.  Crystallography has seen especially extensive use in biochemistry (for protein structure determination) and in the characterization of organometallic catalysts, which often possess significant [[molecular symmetry]].
* [[Elemental Analysis]]: A destructive method used to determine the elemental composition of a molecule.
+
* [[Elemental analysis]]: A destructive method used to determine the elemental composition of a molecule.  See also mass spectrometry, below.
 
* [[Infrared spectroscopy]]: Chiefly used to determine the presence (or absence) of certain [[functional groups]].
 
* [[Infrared spectroscopy]]: Chiefly used to determine the presence (or absence) of certain [[functional groups]].
* [[Mass spectrometry]]: Used to determine the [[molecular weight]] of a compound and from the fragmentation pattern its structure.
+
* [[Mass spectrometry]]: Used to determine the [[molecular weight]] of a compound and from [[mass spectrum analysis]] its structure.  High resolution mass spectrometry can often identify the precise formula of a compound through knowledge of isotopic masses and abundances; it is thus sometimes used in lieu of elemental analysis.
* [[Nuclear magnetic resonance|Nuclear magnetic resonance (NMR) spectrometry]] identifies different nuclei from their chemical environment.
+
* [[Nuclear magnetic resonance|Nuclear magnetic resonance (NMR) spectroscopy]] identifies different nuclei based on their chemical environment.  This is the most important and commonly used spectroscopic technique for organic chemists, often permitting complete assignment of atom connectivity and even stereochemistry given the proper set of spectroscopy experiments (e.g. [[correlation spectroscopy]]).
* [[UV/VIS spectroscopy]]: Used to determine degree of conjugation in the system
+
* [[Optical rotation]]: Distinguishes between two [[enantiomers]] of a chiral compound based on the sign of rotation of plane polarized light.  If the [[specific rotation]] of an enantiomer is known, the magnitude of rotation also gives the ratio of enantiomers in a mixed sample, though [[HPLC]] with a chiral column also can supply this information.
 +
* [[UV/VIS spectroscopy]]: Used to determine degree of conjugation in the system.  While still sometimes used to characterize molecules, UV/VIS is more commonly used to quantitate how much of a known compound is present in a (typically liquid) sample.
  
 
Additional methods are provided by [[analytical chemistry]].
 
Additional methods are provided by [[analytical chemistry]].
  
 
==Organic reactions==
 
==Organic reactions==
[[Organic reaction]]s are [[chemical reaction]]s involving [[organic compound]]s. While pure [[hydrocarbon]]s undergo certain limited classes of reactions, many more reactions which organic compounds undergo are largely determined by [[functional group]]s. The general theory of these reactions involves careful analysis of such properties as the [[electron affinity]] of key atoms,[[bond strength]]s and [[steric hindrance]]. These issues can determine the relative stability of short-lived [[reactive intermediate]]s, which usually directly determine the path of the reaction. An example of a common reaction is a [[substitution reaction]] written as:
+
[[Organic reaction]]s are [[chemical reaction]]s involving [[organic compound]]s. While pure [[hydrocarbon]]s undergo certain limited classes of reactions, many more reactions which organic compounds undergo are largely determined by functional groups. The general theory of these reactions involves careful analysis of such properties as the [[electron affinity]] of key atoms, [[bond strength]]s and [[steric hindrance]]. These issues can determine the relative stability of short-lived [[reactive intermediate]]s, which usually directly determine the path of the reaction. An example of a common reaction is a [[substitution reaction]] written as:
 
:Nu<sup>−</sup>  +  C-X  → C-Nu + X<sup>−</sup>
 
:Nu<sup>−</sup>  +  C-X  → C-Nu + X<sup>−</sup>
  
 
where X is some [[functional group]] and Nu is a [[nucleophile]].  
 
where X is some [[functional group]] and Nu is a [[nucleophile]].  
  
There are many important aspects of a specific reaction. Whether it will occur spontaneously or not is determined by the [[Gibbs free energy]] change of the reaction. The heat that is either produced or needed by the reaction is found from the total [[Enthalpy]] change. Other concerns include whether [[side reaction]]s occur from the same reaction conditions. Any side reactions which occur typically produce undesired compounds which may be anywhere from very easy or very difficult to separate from the desired compound.
+
There are many important aspects of a specific reaction. Whether it will occur spontaneously or not is determined by the [[Gibbs free energy]] change of the reaction. The heat that is either produced or needed by the reaction is found from the total [[enthalpy]] change. Other concerns include whether [[side reaction]]s occur from the same reaction conditions. Any side reactions which occur typically produce undesired compounds which may be anywhere from very easy or very difficult to separate from the desired compound.
 +
 
 +
==Synthetic organic chemistry==
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[[Image:Corey oseltamivir synthesis.png|thumb|right|261px|A synthesis designed by [[E.J. Corey]] for [[oseltamivir]] (Tamiflu). This synthesis has 11 distinct reactions.]]
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{{main|Organic synthesis}}
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Synthetic organic chemistry is an [[applied science]] as it borders [[engineering]], the "design, analysis, and/or construction of works for practical purposes". Organic synthesis of a novel compound is a problem solving task, where a synthesis is designed for a target molecule by selecting optimal reactions from optimal starting materials. Complex compounds can have tens of reaction steps that sequentially build the desired molecule. The synthesis proceeds by utilizing the reactivity of the functional groups in the molecule. For example, a [[carbonyl]] compound can be used as a [[nucleophile]] by converting it into an [[enolate]], or as an [[electrophile]]; the combination of the two is called the [[aldol reaction]]. Designing practically useful syntheses always requires conducting the actual synthesis in the laboratory. The scientific practice of creating novel synthetic routes for complex molecules is called [[total synthesis]].
 +
 
 +
There are several strategies to design a synthesis. The modern method of [[retrosynthesis]], developed by E.J. Corey, starts with the target molecule and splices it to pieces according to known reactions. The pieces, or the proposed precursors, receive the same treatment, until available and ideally inexpensive starting materials are reached. Then, the retrosynthesis is written in the opposite direction to give the synthesis. A "synthetic tree" can be constructed, because each compound and also each precursor has multiple syntheses.
  
 
==See also==
 
==See also==
*[[List of publications in chemistry#Organic chemistry|Important publications in organic chemistry]]
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{{main|Outline of organic chemistry}}
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*[[List of important publications in chemistry#Organic chemistry|Important publications in organic chemistry]]
 
*[[List of organic reactions]]
 
*[[List of organic reactions]]
  
 
==References==
 
==References==
<references/>
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{{reflist|2}}
  
   
 
 
==External links==
 
==External links==
 
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{{WVD}}
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{{Wikibooks}}
 
*[http://ocw.mit.edu/OcwWeb/Chemistry/5-12Spring-2005/CourseHome/index.htm MIT OpenCourseWare: Organic Chemistry I]
 
*[http://ocw.mit.edu/OcwWeb/Chemistry/5-12Spring-2005/CourseHome/index.htm MIT OpenCourseWare: Organic Chemistry I]
*[[Journal of Organic Chemistry]] ([http://pubs.acs.org/journals/joceah/index.html Table of Contents])
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*[http://www.haverford.edu/wintnerorganicchem Organic Chemistry Lectures, Videos and Text]
*[[Organic Letters]] ([http://pubs.acs.org/journals/orlef7/index.html Table of Contents])
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*''[[Journal of Organic Chemistry]]'' (subscription required) ([http://pubs.acs.org/journals/joceah/index.html Table of Contents])
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*''[[Organic Letters]]'' ([http://pubs.acs.org/journals/orlef7/index.html Table of Contents])
 
*[http://www.thieme-connect.com/ejournals/toc/synlett Synlett]
 
*[http://www.thieme-connect.com/ejournals/toc/synlett Synlett]
 
*[http://www.thieme-connect.com/ejournals/toc/synthesis Synthesis]
 
*[http://www.thieme-connect.com/ejournals/toc/synthesis Synthesis]
 
*[http://www.organic-chemistry.org Organic Chemistry Portal - Recent Abstracts and (Name)Reactions]
 
*[http://www.organic-chemistry.org Organic Chemistry Portal - Recent Abstracts and (Name)Reactions]
*[http://www.ochem4free.com Home of a full, online, peer-reviewed organic chemistry text.]
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*[http://www.ochem4free.info Home of a full, online, peer-reviewed organic chemistry text.]
 
*[http://www.cem.msu.edu/~reusch/VirtualText/intro1.htm#info Virtual Textbook of Organic Chemistry]
 
*[http://www.cem.msu.edu/~reusch/VirtualText/intro1.htm#info Virtual Textbook of Organic Chemistry]
*[http://www.organicworldwide.net Organic World Wide - A collection of Links]
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*[http://www.organicworldwide.net Organic Chemistry Resources WorldWide - A collection of Links]
*[http://library.thinkquest.org/3659/orgchem/functionalgroups.html (Organic Families and Their Functional Groups)]
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*[http://library.thinkquest.org/3659/orgchem/functionalgroups.html Organic Families and Their Functional Groups]
*[http://www.ilearnchemistry.com Roger Frost's Chemistry Teaching Tools - Organic Chemistry]
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*[http://www.organic.rogerfrost.com Roger Frost's Organic Chemistry - multimedia for teaching and learning]
 
*[http://www.chemhelper.com  Organic chemistry help]
 
*[http://www.chemhelper.com  Organic chemistry help]
*[http://www.jchem.info Free Organic Chemical Data and Name Reaction Mechanisms]
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*[http://www.organic-chemistry-tutor.com Organic Chemistry Tutor]
 +
*[http://www.acdlabs.com/download/ Chemical Freeware on http://www.acdlabs.com]
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*[http://www.chemaxon.com/download.html/ Chemical Freeware] from [[ChemAxon]].
 +
*[http://www.aceorganicchem.com/resources.html  Organic chemistry help-Best of the Web 2008]
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*[http://www.orgcheminfo.8k.com/ A collection of Organic chemistry Resources]
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{{Organic chemistry}}
 
{{Organic chemistry}}
 
{{BranchesofChemistry}}
 
{{BranchesofChemistry}}
  
 
[[Category:Organic chemistry|*]]
 
[[Category:Organic chemistry|*]]
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[[Category:Chemistry]]
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{{Imported from Wikipedia|name=Organic chemistry|id=306402452}}

Latest revision as of 14:50, 9 August 2009

Organic chemistry is a discipline within chemistry which involves the scientific study of the structure, properties, composition, reactions, and preparation (by synthesis or by other means) of chemical compounds that contain carbon. These compounds may contain any number of other elements, including hydrogen, nitrogen, oxygen, the halogens as well as phosphorus, silicon and sulfur.[1][2][3]

The original definition of "organic" chemistry came from the misconception that organic compounds were always related to life processes. However, organic molecules can be produced by processes not involving life. Life as we know it also depends on inorganic chemistry. For example, many enzymes rely on transition metals such as iron and copper; and materials such as shells, teeth and bones are part organic, part inorganic in composition. Apart from elemental carbon, only certain classes of carbon compounds (such as oxides, carbonates, and carbides) are conventionally considered inorganic. Biochemistry deals mainly with the natural chemistry of biomolecules such as proteins, nucleic acids, and sugars.

Because of their unique properties, multi-carbon compounds exhibit extremely large variety and the range of application of organic compounds is enormous. They form the basis of, or are important constituents of many products (paints, plastics, food, explosives, drugs, petrochemicals, to name but a few) and (apart from a very few exceptions) they form the basis of all earthly life processes.

The different shapes and chemical reactivities of organic molecules provide an astonishing variety of functions, like those of enzyme catalysts in biochemical reactions of live systems.

Current (as of 2008) trends in organic chemistry include chiral synthesis, green chemistry, microwave chemistry, fullerenes and microwave spectroscopy.

Historical highlights

At the very beginning of the nineteenth century chemists generally thought that compounds from living organisms were too complicated in structure to be capable of artificial synthesis from non-living things, and that a 'vital force' or vitalism conferred the characteristics of living beings on this form of matter. They named these compounds 'organic', and preferred to direct their investigations toward inorganic materials that seemed more promising.

Organic chemistry received a boost when it was realized that these compounds could be treated in ways similar to inorganic compounds and could be created in the laboratory by means other than 'vital force'. Around 1816 Michel Chevreul started a study of soaps made from various fats and alkali. He separated the different acids that, in combination with the alkali, produced the soap. Since these were all individual compounds, he demonstrated that it was possible to make a chemical change in various fats (which traditionally come from organic sources), producing new compounds, without 'vital force'. In 1828 Friedrich Wöhler first manufactured the organic chemical urea (carbamide), a constituent of urine, from the inorganic ammonium cyanate NH4OCN, in what is now called the Wöhler synthesis. Although Wöhler was, at this time as well as afterwards, cautious about claiming that he had thereby destroyed the theory of vital force, most have looked to this event as the turning point.

A great next step was when in 1856 William Henry Perkin, while trying to manufacture quinine, again accidentally came to manufacture the organic dye now called Perkin's mauve, which by generating a huge amount of money greatly increased interest in organic chemistry. Another step was the laboratory preparation of DDT by Othmer Zeidler in 1874, but the insecticide properties of this compound were not discovered until much later.

The crucial breakthrough for the theory of organic chemistry was the concept of chemical structure, developed independently and simultaneously by Friedrich August Kekule and Archibald Scott Couper in 1858. Both men suggested that tetravalent carbon atoms could link to each other to form a carbon lattice, and that the detailed patterns of atomic bonding could be discerned by skillful interpretations of appropriate chemical reactions.

The history of organic chemistry continues with the discovery of petroleum and its separation into fractions according to boiling ranges. The conversion of different compound types or individual compounds by various chemical processes created the petroleum chemistry leading to the birth of the petrochemical industry, which successfully manufactured artificial rubbers, the various organic adhesives, the property-modifying petroleum additives, and plastics.

The pharmaceutical industry began in the last decade of the 19th century when acetylsalicylic acid (more commonly referred to as aspirin) manufacture was started in Germany by Bayer. The first time a drug was systematically improved was with arsphenamine (Salvarsan). Numerous derivatives of the dangerously toxic atoxyl were systematically synthesized and tested by Paul Ehrlich and his group, and the compound with best effectiveness and toxicity characteristics was selected for production.

Early examples of organic reactions and applications were serendipitous, such as Perkin's accidental discovery of Perkin's mauve. However, from the 20th century, the progress of organic chemistry allowed for synthesis of specifically selected compounds or even molecules designed with specific properties, as in drug design. The process of finding new synthesis routes for a given compound is called total synthesis. Total synthesis of complex natural compounds started with urea, increased in complexity to glucose and terpineol, and in 1907, total synthesis was commercialized the first time by Gustaf Komppa with camphor. Pharmaceutical benefits have been substantial, for example cholesterol-related compounds have opened ways to synthesis of complex human hormones and their modified derivatives. Since the start of the 20th century, complexity of total syntheses has been increasing, with examples such as lysergic acid and vitamin B12. Today's targets feature tens of stereogenic centers that must be synthesized correctly with asymmetric synthesis.

Biochemistry, the chemistry of living organisms, their structure and interactions in vitro and inside living systems, has only started in the 20th century, opening up a brand new chapter of organic chemistry with enormous scope.

Classification of organic substances

Description and nomenclature

Classification is not possible without having a full description of the individual compounds. In contrast with inorganic chemistry, in which describing a chemical compound can be achieved by simply enumerating the chemical symbols of the elements present in the compound together with the number of these elements in the molecule, in organic chemistry the relative arrangement of the atoms within a molecule must be added for a full description.

One way of describing the molecule is by drawing its structural formula. Because of molecular complexity, simplified systems of chemical notation have been developed. The latest version is the line-angle formula, which achieves simplicity without introducing ambiguity. In this system, the endpoints and intersections of each line represent one carbon, and hydrogens can either be notated or assumed to be present by implication. Some disadvantages of chemical notation are that they are not easily described by words and they are not easily printable. These problems have been addressed by describing molecular structures using organic nomenclature .

Because of the difficulties arising from the very large number and variety of organic compounds, chemists realized early on that the establishment of an internationally accepted system of naming organic compounds was of paramount importance. The Geneva Nomenclature was born in 1892 as a result of a number of international meetings on the subject.

It was also realized that as the family of organic compounds grew, the system would have to be expanded and modified. This task was ultimately taken on by the International Union on Pure and Applied Chemistry (IUPAC). Recognizing the fact that in the branch of biochemistry the complexity of organic structures increases, the IUPAC organization joined forces with the International Union of Biochemistry and Molecular Biology, IUBMB, to produce a list of joint recommendations on nomenclature.

Later, as the numbers and complexities of organic molecules grew, new recommendations were made within IUPAC for simplification. The first such recommendation was presented in 1951 when a cyclic benzene structure was named a cyclophane. Later recommendations extended the method to the simplification of other complex cyclic structures, including heterocyclics, and named such structures phanes.

For ordinary communication, to spare a tedious description, the official IUPAC naming recommendations are not always followed in practice except when it is necessary to give a concise definition to a compound, or when the IUPAC name is simpler (viz. ethanol versus ethyl alcohol). Otherwise the common or trivial name may be used, often derived from the source of the compound.

In summary, organic substances are classified by their molecular structural arrangement and by what other atoms are present along with the chief (carbon) constituent in their makeup, whilst in a structural formula, hydrogen is implicitly assumed to occupy all free valences of an appropriate carbon atom which remain after accounting for branching, other element(s) and/or multiple bonding.

Hydrocarbons and functional groups

The family of carboxylic acids contains a carboxyl (-COOH) functional group. Acetic acid is an example.

Classification normally starts with the hydrocarbons: compounds which contain only carbon and hydrogen. For sub-classes see below. Other elements present themselves in atomic configurations called functional groups which have decisive influence on the chemical and physical characteristics of the compound; thus those containing the same atomic formations have similar characteristics, which may be: miscibility with water, acidity/alkalinity, chemical reactivity, oxidation resistance, and others. Some functional groups are also radicals, similar to those in inorganic chemistry, defined as polar atomic configurations which pass during chemical reactions from one chemical compound into another without change.

Some of the elements of the functional groups (O, S, N, halogens) may stand alone and the group name is not strictly appropriate, but because of their decisive effect on the way they modify the characteristics of the hydrocarbons in which they are present they are classed with the functional groups, and their specific effect on the properties lends excellent means for characterisation and classification.

Referring to the hydrocarbon types below, many, if not all of the functional groups which are typically present within aliphatic compounds are also represented within the aromatic and alicyclic group of compounds, unless they are dehydrated, which would lead to non-reacting co-optional groups.

Reference is made here again to the organic nomenclature, which shows an extensive (if not comprehensive) number of classes of compounds according to the presence of various functional groups, based on the IUPAC recommendations, but also some based on trivial names. Putting compounds in sub-classes becomes more difficult when more than one functional group is present.

Two overarching chain type categories exist: open chain aliphatic compounds and closed chain cyclic compounds. Those in which both open chain and cyclic parts are present are normally classed with the latter.

Aliphatic compounds

The aliphatic hydrocarbons are subdivided into three groups of homologous series according to their state of saturation: paraffins alkanes without any double or triple bonds, olefins alkenes with double bonds, which can be mono-olefins with a single double bond, di-olefins, or di-enes with two, or poly-olefins with more. The third group with a triple bond is named after the name of the shortest member of the homologue series as the acetylenes alkynes. The rest of the group is classed according to the functional groups present.

From another aspect aliphatics can be straight chain or branched chain compounds, and the degree of branching also affects characteristics, like octane number or cetane number in petroleum chemistry.

Aromatic and alicyclic compounds

Benzene is one of the best-known aromatic compounds as it is one of the simplest aromatics.

Cyclic compounds can, again, be saturated or unsaturated. Because of the bonding angle of carbon, the most stable configurations contain six carbon atoms, but while rings with five carbon atoms are also frequent, others are rarer. The cyclic hydrocarbons divide into alicyclics and aromatics (also called arenes).

Of the alicyclic compounds the cycloalkanes do not contain multiple bonds, whilst the cycloalkenes and the cycloalkynes do. Typically this latter type only exists in the form of large rings, called macrocycles. The simplest member of the cycloalkane family is the three-membered cyclopropane.

Aromatic hydrocarbons contain conjugated double bonds. One of the simplest examples of these is benzene, the structure of which was formulated by Kekulé who first proposed the delocalization or resonance principle for explaining its structure. For "conventional" cyclic compounds, aromaticity is conferred by the presence of 4n + 2 delocalized pi electrons, where n is an integer. Particular instability (antiaromaticity) is conferred by the presence of 4n conjugated pi electrons.

The characteristics of the cyclic hydrocarbons are again altered if heteroatoms are present, which can exist as either substituents attached externally to the ring (exocyclic) or as a member of the ring itself (endocyclic). In the case of the latter, the ring is termed a heterocycle. Pyridine and furan are examples of aromatic heterocycles while piperidine and tetrahydrofuran are the corresponding alicyclic heterocycles. The heteroatom of heterocyclic molecules is generally oxygen, sulfur, or nitrogen, with the latter being particularly common in biochemical systems.

Rings can fuse with other rings on an edge to give polycyclic compounds. The purine nucleoside bases are notable polycyclic aromatic heterocycles. Rings can also fuse on a "corner" such that one atom (almost always carbon) has two bonds going to one ring and two to another. Such compounds are termed spiro and are important in a number of natural products.

Polymers

This swimming board is made of polystyrene, an example of a polymer

One important property of carbon in organic chemistry is that it can form certain compounds, the individual molecules of which are capable of attaching themselves to one another, thereby forming a chain or a network. The process is called polymerization and the chains or networks polymers, while the source compound is a monomer. Two main groups of polymers exist: those artificially manufactured are referred to as industrial polymers [4] or synthetic polymers and those naturally occurring as biopolymers.

Since the invention of the first artificial polymer, bakelite, the family has quickly grown with the invention of others. Common synthetic organic polymers are polyethylene or polythene, polypropylene, nylon, teflon or PTFE, polystyrene, polyesters, polymethylmethacrylate (commonly known as perspex or plexiglas) polyvinylchloride or PVC, and polyisobutylene an important artificial or synthetic rubber also the polymerised butadiene, a rubber component.

The examples are generic terms, and many varieties of each of these may exist, with their physical characteristics fine tuned for a specific use. Changing the conditions of polymerisation changes the chemical composition of the product by altering chain length, or branching, or the tacticity. With a single monomer as a start the product is a homopolymer. Further, secondary component(s) may be added to create a heteropolymer (co-polymer) and the degree of clustering of the different components can also be controlled. Physical characteristics, such as hardness, density, mechanical or tensile strength, abrasion resistance, heat resistance, transparency, colour, etc. will depend on the final composition.

Biomolecules

File:Maitotoxin.png
Maitotoxin, a complex organic biological toxin.

Biomolecular chemistry is a major category within organic chemistry which is frequently studied by biochemists. Many complex multi-functional group molecules are important in living organisms. Some are long-chain biopolymers, and these include proteins, DNA, RNA and the polysaccharides such as starches in animals and celluloses in plants. The other main classes are amino acids (monomer building blocks of proteins), carbohydrates (which includes the polysaccharides), the nucleic acids (which include DNA and RNA as polymers), and the lipids. In addition, animal biochemistry contains many small molecule intermediates which assist in energy production through the Krebs cycle, and produces isoprene, the most common hydrocarbon in animals. Isoprenes in animals form the important steroid structural (cholesterol) and steroid hormone compounds; and in plants form terpenes, terpenoids, some alkaloids, and a unique set of structural hydrocarbons called biopolymer polyisoprenoids present in latex sap which is the basis for making rubber.

Small molecules

In pharmacology, an important group of organic compounds is small molecules, also referred to as 'small organic compounds'. In this context, a small molecule is a small organic compound that is biologically active, but is not a polymer. In practice, small molecules have a molar mass less than approximately 1000 g/mol.

Fullerenes

Fullerenes are among the types of compounds engineered by organic chemists that have generated the most interest. The discovery of their unique electronic properties due to their spherical structure has stimulated new research into related fields such as carbon nanotubes.

Others

Organic compounds containing bonds of carbon to nitrogen, oxygen and the halogens are not normally grouped separately. Others are sometimes put into major groups within organic chemistry and discussed under titles such as organosulfur chemistry, organometallic chemistry, organophosphorus chemistry and organosilicon chemistry.

Characteristics of organic substances

The structure of methane by pictorial representation of a Lewis diagram showing the sharing of electronpairs between atomic nuclei in a covalent bond. However, in reality, the structure is not two-dimensional.

Organic compounds are generally covalently bonded. This allows for unique structures such as long carbon chains and rings. The reason carbon is excellent at forming unique structures and that there are so many carbon compounds is that carbon atoms form very stable covalent bonds with one another (catenation). In contrast to inorganic materials, organic compounds typically melt, boil, sublimate, or decompose below 300 °C. Neutral organic compounds tend to be less soluble in water compared to many inorganic salts, with the exception of certain compounds such as ionic organic compounds and low molecular weight alcohols and carboxylic acids where hydrogen bonding occurs.

Organic compounds tend to dissolve in organic solvents which are either pure substances like ether or ethyl alcohol, or mixtures, such as the paraffinic solvents such as the various petroleum ethers and white spirits, or the range of pure or mixed aromatic solvents obtained from petroleum or tar fractions by physical separation or by chemical conversion. Solubility in the different solvents depends upon the solvent type and on the functional groups if present. Solutions are studied by the science of physical chemistry. Like inorganic salts, organic compounds may also form crystals. A unique property of carbon in organic compounds is that its valency does not always have to be taken up by atoms of other elements, and when it is not, a condition termed unsaturation results. In such cases we talk about carbon carbon double bonds or triple bonds. Double bonds alternating with single in a chain are called conjugated double bonds. An aromatic structure is a special case in which the conjugated chain is a closed ring.

Molecular structure elucidation

Molecular models of caffeine

Organic compounds consist of carbon atoms, hydrogen atoms, and functional groups. The valence of carbon is 4, and hydrogen is 1, functional groups are generally 1. From the number of carbon atoms and hydrogen atoms in a molecule the degree of unsaturation can be obtained. Many, but not all structures can be envisioned by the simple valence rule that there will be one bond for each valence number. The knowledge of the chemical formula for an organic compound is not sufficient information because many isomers can exist. Organic compounds often exist as mixtures. Because many organic compounds have relatively low boiling points and/or dissolve easily in organic solvents there exist many methods for separating mixtures into pure constituents that are specific to organic chemistry such as distillation, crystallization and chromatography techniques. There exist several methods for deducing the structure of an organic compound. In general usage are (in alphabetical order):

  • Crystallography: This is the most precise method for determining molecular geometry; however, it is very difficult to grow crystals of sufficient size and high quality to get a clear picture, so it remains a secondary form of analysis. Crystallography has seen especially extensive use in biochemistry (for protein structure determination) and in the characterization of organometallic catalysts, which often possess significant molecular symmetry.
  • Elemental analysis: A destructive method used to determine the elemental composition of a molecule. See also mass spectrometry, below.
  • Infrared spectroscopy: Chiefly used to determine the presence (or absence) of certain functional groups.
  • Mass spectrometry: Used to determine the molecular weight of a compound and from mass spectrum analysis its structure. High resolution mass spectrometry can often identify the precise formula of a compound through knowledge of isotopic masses and abundances; it is thus sometimes used in lieu of elemental analysis.
  • Nuclear magnetic resonance (NMR) spectroscopy identifies different nuclei based on their chemical environment. This is the most important and commonly used spectroscopic technique for organic chemists, often permitting complete assignment of atom connectivity and even stereochemistry given the proper set of spectroscopy experiments (e.g. correlation spectroscopy).
  • Optical rotation: Distinguishes between two enantiomers of a chiral compound based on the sign of rotation of plane polarized light. If the specific rotation of an enantiomer is known, the magnitude of rotation also gives the ratio of enantiomers in a mixed sample, though HPLC with a chiral column also can supply this information.
  • UV/VIS spectroscopy: Used to determine degree of conjugation in the system. While still sometimes used to characterize molecules, UV/VIS is more commonly used to quantitate how much of a known compound is present in a (typically liquid) sample.

Additional methods are provided by analytical chemistry.

Organic reactions

Organic reactions are chemical reactions involving organic compounds. While pure hydrocarbons undergo certain limited classes of reactions, many more reactions which organic compounds undergo are largely determined by functional groups. The general theory of these reactions involves careful analysis of such properties as the electron affinity of key atoms, bond strengths and steric hindrance. These issues can determine the relative stability of short-lived reactive intermediates, which usually directly determine the path of the reaction. An example of a common reaction is a substitution reaction written as:

Nu + C-X → C-Nu + X

where X is some functional group and Nu is a nucleophile.

There are many important aspects of a specific reaction. Whether it will occur spontaneously or not is determined by the Gibbs free energy change of the reaction. The heat that is either produced or needed by the reaction is found from the total enthalpy change. Other concerns include whether side reactions occur from the same reaction conditions. Any side reactions which occur typically produce undesired compounds which may be anywhere from very easy or very difficult to separate from the desired compound.

Synthetic organic chemistry

A synthesis designed by E.J. Corey for oseltamivir (Tamiflu). This synthesis has 11 distinct reactions.

Synthetic organic chemistry is an applied science as it borders engineering, the "design, analysis, and/or construction of works for practical purposes". Organic synthesis of a novel compound is a problem solving task, where a synthesis is designed for a target molecule by selecting optimal reactions from optimal starting materials. Complex compounds can have tens of reaction steps that sequentially build the desired molecule. The synthesis proceeds by utilizing the reactivity of the functional groups in the molecule. For example, a carbonyl compound can be used as a nucleophile by converting it into an enolate, or as an electrophile; the combination of the two is called the aldol reaction. Designing practically useful syntheses always requires conducting the actual synthesis in the laboratory. The scientific practice of creating novel synthetic routes for complex molecules is called total synthesis.

There are several strategies to design a synthesis. The modern method of retrosynthesis, developed by E.J. Corey, starts with the target molecule and splices it to pieces according to known reactions. The pieces, or the proposed precursors, receive the same treatment, until available and ideally inexpensive starting materials are reached. Then, the retrosynthesis is written in the opposite direction to give the synthesis. A "synthetic tree" can be constructed, because each compound and also each precursor has multiple syntheses.

See also

References

  1. Robert T. Morrison, Robert N. Boyd, and Robert K. Boyd, Organic Chemistry, 6th edition (Benjamin Cummings, 1992, ISBN 0-13-643669-2) - this is "Morrison and Boyd", a classic textbook
  2. John D. Roberts, Marjorie C. Caserio, Basic Principles of Organic Chemistry,(W. A. Benjamin,Inc.,1964) - another classic textbook
  3. Richard F. and Sally J. Daley, Organic Chemistry, Online organic chemistry textbook. http://www.ochem4free.info
  4. "industrial polymers, chemistry of." Encyclopædia Britannica. 2006

External links

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