Chapter 3: Molecules, Compounds, and Chemical Equations

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3.7:

Organische Verbindingen

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Chemistry

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JoVE Core Chemistry

Organic Compounds

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Chemische verbindingen die voornamelijk bestaan uit koolstofatomen die zijn gebonden aan waterstof-zuurstof-stikstof-of zwavelatomen, worden organische verbindingen genoemd. Organische verbindingen vormen een grote verscheidenheid aan moleculen van fundamentele bouwstenen van het leven zoals DNA of plantencelwanden tot energie-vrijmakende materialen zoals brandstoffen. Ze worden meestal gemakkelijk afgebroken.Koolstofatomen vormen de ruggengraat van elke organische verbinding, die verschillende structuren kan aannemen met ringvormige, vertakte en rechte ketens vanwege de veelzijdigheid van koolstof om vier bindingen te vormen, als enkele, dubbele of drievoudige bindingen. Organische verbindingen kunnen koolwaterstoffen of gefunctionaliseerde koolwaterstoffen zijn. Koolwaterstoffen bestaan volledig uit koolstof-en waterstofatomen.Alkanen zijn koolwaterstoffen die enkelvoudige bindingen bevatten. Alkenen bevatten een of meer dubbele bindingen, terwijl alkynen een of meer drievoudige bindingen bevatten. Koolwaterstofnomenclatuur volgt een patroon waarbij de basisnaam eerst wordt vermeld met een voorvoegsel dat wordt bepaald door het aantal koolstofatomen.De naam eindigt met het achtervoegsel aan, een of yn, afhankelijk van de aanwezigheid van respectievelijk enkele, dubbele of drievoudige bindingen. De enkelvoudige binding die alkaan met drie koolstofatomen bevat, is bijvoorbeeld propaan. Een dubbele binding die alkeen met drie koolstofatomen bevat, is propeen, terwijl een drievoudige binding die alkyn met drie koolstofatomen bevat, propyn is.Koolwaterstoffen waarvan een of meer waterstofatomen zijn gesubstitueerd door een specifieke groep atomen of functionele groepen, worden gefunctionaliseerde koolwaterstoffen genoemd. De algemene formule van gefunctionaliseerde koolwaterstoffen geeft het koolwaterstofgedeelte aan met de letter R’en de specifieke functionele groep. Functionele groepen kunnen van vele soorten zijn en hebben specifieke fysische en chemische eigenschappen.Alle organische verbindingen die een gemeenschappelijke functionele groep hebben, vallen onder dezelfde familie van koolwaterstoffen, vertonen vergelijkbare eigenschappen en volgen een vergelijkbare nomenclatuur. Alle organische verbindingen met een OH functionele groep worden bijvoorbeeld alcoholen genoemd. De nomenclatuur vermeldt de stam-alkaan-base-naam die eindigt op het achtervoegsel ol, specifiek voor de functionele alcoholgroep.Daarom wordt propaan met een OH functionele groep propanol genoemd. Daarentegen worden alle organische verbindingen die carboxylfunctionele groepen dragen, carbonzuren genoemd. De nomenclatuur vermeldt de stam-alkaan-base-naam die eindigt met het achtervoegsel zuur, uniek voor de functionele carboxylgroep.Daarom wordt propaan met een carboxyl-functionele groep propaanzuur genoemd.

3.7:

Organische Verbindingen

All living things are formed mostly of carbon compounds called organic compounds. The category of organic compounds includes both natural and synthetic compounds that contain carbon. Although a single, precise definition has yet to be identified by the chemistry community, most agree that a defining trait of organic molecules is the presence of carbon as the principal element, bonded to hydrogen and other carbon atoms. However, some carbon-containing compounds such as carbonates, cyanides, and simple oxides (CO and CO₂) are not classified as organic compounds.

Organic compounds are key components of plastics, soaps, perfumes, sweeteners, fabrics, pharmaceuticals, and many other substances used daily. Organic compounds include compounds originating from living organisms and those synthesized by chemists. The existence of a wide array of organic molecules is a consequence of carbon atoms' ability to form up to four strong bonds to other carbon atoms, resulting in chains and rings of many different sizes, shapes, and complexities.

Hydrocarbons

The simplest organic compounds contain only the elements carbon and hydrogen and are called hydrocarbons. Hydrocarbons may differ in the types of carbon-carbon bonds present in their molecules. Those containing only single bonds are called alkanes, while those containing double or triple bonds are alkenes and alkynes, respectively. Although all hydrocarbons are composed of only two types of atoms (carbon and hydrogen), there is a wide variety of hydrocarbons because they may consist of varying lengths of chains, branched chains, and rings of carbon atoms, or combinations of these structures.


Butane (C₄H₁₀)	Isobutane (C₄H₁₀)	Cyclobutane (C₄H₈)

Hydrocarbons are used every day, mainly as fuels, such as natural gas, acetylene, propane, butane, and the principal components of gasoline, diesel fuel, and heating oil. Alkanes, or saturated hydrocarbons, contain only single covalent bonds between their carbon atoms. Properties such as melting point and the boiling point usually change predictably as the number of carbon and hydrogen atoms in the molecules change.

To name a simple alkane, first identify the base name depending on the number of carbon atoms in the chain (meth = 1, eth = 2, prop = 3, but = 4, pent = 5, hex = 6, hept = 7, oct = 8, non = 9, and dec = 10). The base name is followed with a suffix — determined by whether the hydrocarbon is an alkane (-ane ), alkene (-ene ), or alkyne (-yne ). For example, a two-carbon alkane is called ethane; a three-carbon alkane is called propane; and a four-carbon alkane is called butane. Longer chains are named as follows: pentane (5-carbon chain), hexane (6), heptane (7), octane (8), nonane (9), and decane (10).

Alkenes and alkynes are unsaturated hydrocarbons containing double bonds and triple bonds, respectively, between at least two carbon atoms. Their nomenclature follows the same steps as that of alkane: base name + suffix. For example, a two-carbon alkene chain is called ethene, and a two-carbon alkyne is called ethyne; a three-carbon alkene is called propene, and a three-carbon alkyne is called propyne, and so on.


Ethane (C₂H₆)	Ethene (C₂H₄)	Ethyne (C₂H₂)

Functionalized Hydrocarbons

Incorporation of a functional group into carbon- and hydrogen-containing molecules leads to new families of compounds called functionalized hydrocarbons. The functional group is a characteristic atom or group of atoms that primarily determines the properties of hydrocarbon derivatives.

One type of functional group is the –OH group. Compounds that have an –OH functional group are alcohols. The name of the alcohol comes from the hydrocarbon from which it was derived. By convention, the hydrocarbon portion of the molecule is designated as 'R'; so the general formula of an alcohol is R–OH. The final ‘–e’ in the name of the hydrocarbon is replaced by ‘–ol’. In the case of a branched alcohol, the carbon atom to which the –OH group is bonded is indicated by a number placed before the name. Other common functional groups are listed below. A group of compounds containing the same functional group forms a family.

Family	Functional group	Example	Formula	Name
Alcohols			C₃H₈O	Propanol
Ethers			C₂H₆O	Dimethyl ether
Aldehydes			C₃H₆O	Propanal
Ketones			C₃H₆O	Propanone (acetone)
Carboxylic acids			C₃H₆O₂	Propanoic acid
Esters			C₄H₈O₂	Ethyl acetate
Amines			C₃H₉N	Propylamine

Ethers are compounds that contain the functional group –O–, with the general formula R–O–R’.

Another class of organic molecules contains a carbon atom connected to an oxygen atom by a double bond, commonly called a carbonyl group. The carbon in the carbonyl group can attach to two other substituents leading to several subfamilies (aldehydes, ketones, carboxylic acids, and esters).

Functional groups related to the carbonyl group include the –CHO group of an aldehyde, the –CO– group of a ketone, the –CO₂H group of a carboxylic acid, and the –CO₂R group of an ester. The carbonyl group, a carbon-oxygen double bond, is the key structure in these classes of organic molecules. Aldehydes contain at least one hydrogen atom attached to the carbonyl carbon atom, ketones contain two carbon groups attached to the carbonyl carbon atom, carboxylic acids contain a hydroxyl group attached to the carbonyl carbon atom, and esters contain an oxygen atom attached to another carbon group connected to the carbonyl carbon atom. All of these compounds contain oxidized carbon atoms relative to the carbon atom of an alcohol group.

The addition of nitrogen into an organic framework leads to two families of molecules, namely amines and amides. Compounds containing a nitrogen atom bonded in a hydrocarbon framework are classified as amines. Compounds that have a nitrogen atom bonded to one side of a carbonyl group are classified as amides. Amines are a basic functional group. Amines and carboxylic acids can combine in a condensation reaction to form amides.

This text is adapted from Openstax, Chemistry 2e, Section 20: Introduction, Openstax, Chemistry 2e, Section 20.1: Hydrocarbons, Openstax, Chemistry 2e, Section 20.2: Alcohols and Ethers, Openstax, Chemistry 2e, Section 20.2: Aldehydes, Ketones, Carboxylic Acids, and Esters, and Openstax, Chemistry 2e, Section 20.2: Amines and Amides.