Cyclic compound: Difference between revisions
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== Cyclic compound gallery == | |||
<gallery> | |||
File:Ingenol.svg|Ingenol | |||
File:First four cycloalkanes - en.svg|First four cycloalkanes | |||
File:Taxol.svg|Taxol | |||
File:Cycloctane conformations.jpg|Cycloctane conformations | |||
File:Macrocycles 2revEnglUse.jpg|Macrocycles | |||
File:Chair-Boat-Conformation general.svg|Chair-Boat Conformation | |||
File:Dieckmann condensation scheme.svg|Dieckmann condensation scheme | |||
File:Cycloheptane.png|Cycloheptane | |||
File:Benzene-6H-delocalized.svg|Benzene delocalized | |||
File:Cyclooctasulfur structural formula 3D.svg|Cyclooctasulfur structural formula | |||
</gallery> | |||
Latest revision as of 05:01, 3 March 2025
Cyclic Compound[edit]
A cyclic compound is a type of organic compound that contains a closed ring of atoms in its structure. These compounds are characterized by having at least one carbon atom forming a part of the ring. Cyclic compounds are widely studied in organic chemistry due to their unique properties and diverse applications in various fields.
Structure[edit]
The structure of a cyclic compound is defined by the number of atoms in the ring and the arrangement of these atoms. The simplest type of cyclic compound is a cycloalkane, which consists of a single ring of carbon atoms. Examples of cycloalkanes include cyclopropane, cyclobutane, and cyclopentane. These compounds are often represented using structural formulas, which show the arrangement of atoms and bonds in the molecule.
Properties[edit]
Cyclic compounds exhibit several interesting properties that distinguish them from acyclic compounds (compounds without a closed ring structure). One of the most notable properties is their ring strain. Ring strain arises from the deviation of bond angles and bond lengths from their ideal values due to the cyclic structure. This strain can affect the stability and reactivity of the compound.
Another important property of cyclic compounds is their conformational isomerism. Due to the ability of the ring to rotate around its bonds, different conformations of the same cyclic compound can exist. These conformations can have different energies and can interconvert through ring flipping or other molecular motions.
Applications[edit]
Cyclic compounds have a wide range of applications in various fields. One of the most well-known applications is in the field of pharmaceuticals. Many drugs and medications contain cyclic structures, which can provide specific interactions with biological targets. Examples include cyclosporine, a potent immunosuppressant, and cyclophosphamide, an anticancer drug.
In addition to pharmaceuticals, cyclic compounds are also used in the production of polymers and plastics. For example, polyethylene terephthalate (PET), a commonly used plastic, contains a cyclic structure in its monomer unit. Cyclic compounds are also utilized in the synthesis of various organic compounds, such as heterocycles and natural products.
See Also[edit]
- Cycloalkane
- Ring Strain
- Conformational Isomerism
- Pharmaceuticals
- Polymers
- Plastics
- Heterocycles
- Natural Products
References[edit]
<references />
Cyclic compound gallery[edit]
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Ingenol
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First four cycloalkanes
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Taxol
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Cycloctane conformations
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Macrocycles
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Chair-Boat Conformation
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Dieckmann condensation scheme
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Cycloheptane
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Benzene delocalized
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Cyclooctasulfur structural formula
