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Organic matter, organic material, or natural organic matter refers to the large source of carbon-based compounds found within natural and engineered, terrestrial, and aquatic environments. It is matter composed of organic compounds that have come from the feces and remains of organisms such as plants and animals. [1]
Jul 12, 2023 · In our study of organic chemistry, it will become extremely important to be able to quickly recognize the most common functional groups, because they are the key structural elements that define how organic molecules react.
Jun 16, 2022 · Organic matter pertains to any of the carbon-based compounds that abound in nature. Living things are described as organic since they are composed of organic compound s. Examples of organic compounds are carbohydrates, lipid s, protein s and nucleic acid s.
It consists of three distinctly different parts: living organisms, fresh residues and molecules derived from well-decomposed residues. These three parts of soil organic matter have been described as the living, the dead and the very dead.
- Overview
- Historical developments
- Carbon bonding
- Functional groups
- Alkanes
- Alkenes
- Alkynes
- Aromatic hydrocarbons (arenes)
- Alcohols and phenols
- Ethers and epoxides
organic compound, any of a large class of chemical compounds in which one or more atoms of carbon are covalently linked to atoms of other elements, most commonly hydrogen, oxygen, or nitrogen. The few carbon-containing compounds not classified as organic include carbides, carbonates, and cyanides.
In general, organic compounds are substances that contain carbon (C), and carbon atoms provide the key structural framework that generates the vast diversity of organic compounds. All things on Earth (and most likely elsewhere in the universe) that can be described as living have a crucial dependence on organic compounds. Foodstuffs—namely, fats, proteins, and carbohydrates—are organic compounds, as are such vital substances as hemoglobin, chlorophyll, enzymes, hormones, and vitamins. Other materials that add to the comfort, health, or convenience of humans are composed of organic compounds, including clothing made of cotton, wool, silk, and synthetic fibres; common fuels, such as wood, coal, petroleum, and natural gas; components of protective coatings, such as varnishes, paints, lacquers, and enamels; antibiotics and synthetic drugs; natural and synthetic rubber; dyes; plastics; and pesticides.
When chemistry took on many of the characteristics of a rational science at the end of the 18th century, there was general agreement that experiment could reveal the laws that governed the chemistry of inanimate, inorganic compounds. The compounds that could be isolated from living organic entities, however, appeared to have compositions and properties entirely different from inorganic ones. Very few of the concepts that enabled chemists to understand and manipulate the chemistry of inorganic compounds were applicable to organic compounds. This great difference in chemical behaviour between the two classes of compounds was thought to be intimately related to their origin. Inorganic substances could be extracted from the rocks, sediments, or waters of the Earth, whereas organic substances were found only in the tissues or remains of living organisms. It was therefore suspected that organic compounds could be produced only by organisms under the guidance of a power present exclusively in living things. This power was referred to as a vital force.
This vital force was thought to be a property inherent to all organic substances and incapable of being measured or extracted by chemical operations. Thus, most chemists of the time believed that it was impossible to produce organic substances entirely from inorganic ones. By about the middle of the 19th century, however, several simple organic compounds had been produced by the reaction of purely inorganic materials, and the unique character of organic compounds was recognized as the consequence of an intricate molecular architecture rather than of an intangible vital force.
The first significant synthesis of an organic compound from inorganic materials was an accidental discovery of Friedrich Wöhler, a German chemist. Working in Berlin in 1828, Wöhler mixed two salts (silver cyanate and ammonium chloride) in an attempt to make the inorganic substance ammonium cyanate. To his complete surprise, he obtained a product that had the same molecular formula as ammonium cyanate but was instead the well-known organic compound urea. From this serendipitous result, Wöhler correctly concluded that atoms could arrange themselves into molecules in different ways, and the properties of the resulting molecules were critically dependent on the molecular architecture. (The inorganic compound ammonium cyanate is now known to be an isomer of urea; both contain the same type and number of atoms but in different structural arrangements.) Encouraged by Wöhler’s discovery, others succeeded in making simple organic compounds from inorganic ones, and by roughly 1860 it was generally recognized that a vital force was unnecessary for the synthesis and interconversion of organic compounds.
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Although a large number of organic compounds have since been synthesized, the structural complexity of certain compounds continues to pose major problems for the laboratory synthesis of complicated molecules. But modern spectroscopic techniques allow chemists to determine the specific architecture of complicated organic molecules, and molecular properties can be correlated with carbon bonding patterns and characteristic structural features known as functional groups.
The carbon atom is unique among elements in its tendency to form extensive networks of covalent bonds not only with other elements but also with itself. Because of its position midway in the second horizontal row of the periodic table, carbon is neither an electropositive nor an electronegative element; it therefore is more likely to share electrons than to gain or lose them. Moreover, of all the elements in the second row, carbon has the maximum number of outer shell electrons (four) capable of forming covalent bonds. (Other elements, such as phosphorus [P] and cobalt [Co], are able to form five and six covalent bonds, respectively, with other elements, but they lack carbon’s ability to bond indefinitely with itself.) When fully bonded to other atoms, the four bonds of the carbon atom are directed to the corners of a tetrahedron and make angles of about 109.5° with each other. The result is that not only can carbon atoms combine with one another indefinitely to give compounds of extremely high molecular weight, but the molecules formed can exist in an infinite variety of three-dimensional structures. The possibilities for diversity are increased by the presence of atoms other than carbon in organic compounds, especially hydrogen (H), oxygen (O), nitrogen (N), halogens (fluorine [F], chlorine [Cl], bromine [Br], and iodine [I]), and sulfur (S). It is the enormous potential for variation in chemical properties that has made organic compounds essential to life on Earth.
The structures of organic compounds commonly are represented by simplified structural formulas, which show not only the kinds and numbers of atoms present in the molecule but also the way in which the atoms are linked by the covalent bonds—information that is not given by simple molecular formulas, which specify only the number and type of atoms contained in a molecule. (With most inorganic compounds, the use of structural formulas is not necessary, because only a few atoms are involved and only a single arrangement of the atoms is possible.) In the structural formulas of organic compounds, short lines are used to represent the covalent bonds. Atoms of the individual elements are represented by their chemical symbols, as in molecular formulas.
Structural formulas vary widely in the amount of three-dimensional information they convey, and the type of structural formula used for any one molecule depends on the nature of the information the formula is meant to display. The different levels of sophistication can be illustrated by considering some of the least complex organic compounds, the hydrocarbons. The gas ethane, for example, has the molecular formula C2H6. The simplest structural formula, drawn either in a condensed or in an expanded version, reveals that ethane consists of two carbon atoms bonded to one another, each carbon atom bearing three hydrogen atoms. Such a two-dimensional representation correctly shows the bonding arrangement in ethane, but it does not convey any information about its three-dimensional architecture. A more sophisticated structural formula can be drawn to better represent the three-dimensional structure of the molecule. Such a structural formula correctly shows the tetrahedral orientation of the four atoms (one carbon and three hydrogens) bonded to each carbon, and the specific architecture of the molecule.
Larger organic molecules are formed by the addition of more carbon atoms. Butane, for example, is a gaseous hydrocarbon with the molecular formula C4H10, and it exists as a chain of four carbon atoms with 10 attached hydrogen atoms. As carbon atoms are added to a molecular framework, the carbon chain can develop branches or form cyclic structures. A very common ring structure contains six carbon atoms in a ring, each bonded in a tetrahedral arrangement, as in the hydrocarbon cyclohexane, C6H12. Such ring structures are often very simply represented as regular polygons in which each apex represents a carbon atom, and the hydrogen atoms that complete the bonding requirements of the carbon atoms are not shown. The polygon convention for cyclic structures reveals concisely the bonding arrangement of the molecule but does not explicitly convey information about the actual three-dimensional architecture. It should be noted that the polygon is only a two-dimensional symbol for the three-dimensional molecule.
Click Here to see full-size tableChemists observed early in the study of organic compounds that certain groups of atoms and associated bonds, known as functional groups, confer specific reactivity patterns on the molecules of which they are a part. Although the properties of each of the several million organic molecules whose structure is known are unique in some way, all molecules that contain the same functional group have a similar pattern of reactivity at the functional group site. Thus, functional groups are a key organizing feature of organic chemistry. By focusing on the functional groups present in a molecule (most molecules have more than one functional group), several of the reactions that the molecule will undergo can be predicted and understood.
Because carbon-to-carbon and carbon-to-hydrogen bonds are extremely strong and the charge of the electrons in these covalent bonds is spread more or less evenly over the bonded atoms, hydrocarbons that contain only single bonds of these two types are not very reactive. The reactivity of a molecule increases if it contains one or more weak bonds or bonds that have an unequal distribution of electrons between the two atoms. If the two electrons of a covalent bond are, for one reason or another, drawn more closely to one of the bonded atoms, that atom will develop a partial negative charge and the atom to which it is bonded will develop a partial positive charge. A covalent bond in which the electron pair linking the atoms is shared unequally is known as a polar bond. Polar bonds, and any other bonds that have unique electronic properties, confer the potential for chemical reaction on the molecule in which they are present. This is because, for every reaction, one or more bonds of a molecule must be broken and new bonds formed. The presence of a partial negative charge (a region of high electron density) will draw to itself other atoms or groups of atoms that are deficient in electron density. This initiates the process of bond breaking that is a prerequisite for a chemical reaction. For these reasons, molecules with regions of increased or decreased electron density are especially important for chemical change.
There are two major bonding features that generate the reactive sites of functional groups. The first, already mentioned, is the presence of multiple bonds. Both double and triple bonds have regions of high electron density lying outside the atom-to-atom bond axis. Double and triple bonds are known as functional groups, a term that is used to identify atoms or groups of atoms within a molecule that are sites of comparatively high reactivity. A second type of reactive site results when an atom other than carbon or hydrogen (termed a heteroatom) is bonded to carbon. All heteroatoms have a greater or lesser attraction for electrons than does carbon. Thus, each bond between a carbon and a heteroatom is polar, and the degree of polarity depends on the difference between the electron-attracting properties of the two atoms. The most important atomic groupings that contain such reactive polar bonds are also able to generate functional groups.
To emphasize the generality of reactions between molecules that contain the same functional group, chemists often represent the less reactive portions of a molecule by the symbol R. Thus, all molecules that contain a double bond, however complicated, can be represented by the general formula for an alkene—i.e.,
This type of formula suggests that the molecule will undergo those reactions that are common to double bonds and that the reaction will occur at the double bond. The rest of the molecule, represented by the four R groups, will remain unchanged by the reaction occurring at the functional group site.
Molecules with more than one functional group, called polyfunctional, may have more complicated properties that result from the identity—and interconnectedness—of the multiple functional groups. Many natural products contain several functional groups located at specific sites within a large, complicated, three-dimensional structure.
Alkanes are compounds that consist entirely of atoms of carbon and hydrogen (a class of substances known as hydrocarbons) joined to one another by single bonds. The shared electron pair in each of these single bonds occupies space directly between the two atoms; the bond generated by this shared pair is known as a sigma (σ) bond. Both carbon-carbon...
Organic compounds are termed alkenes if they contain a carbon-carbon double bond. The shared electron pair of one of the bonds is a σ bond. The second pair of electrons occupies space on both sides of the σ bond; this shared pair constitutes a pi (π) bond. A π bond forms a region of increased electron density because the electron pair is more distant from the positively charged carbon nuclei than is the electron pair of the σ bond . Even though a carbon-carbon double bond is very strong, a π bond will draw to itself atoms or atomic groupings that are electron-deficient, thereby initiating a process of bond-breaking that can lead to rupture of the π bond and formation of new σ bonds. A simple example of an alkene reaction, which illustrates the way in which the electronic properties of a functional group determine its reactivity, is the addition of molecular hydrogen to form alkanes, which contain only σ bonds.
Such reactions, in which the π bond of an alkene reacts to form two new σ bonds, are energetically favourable because the new bonds formed (two carbon-hydrogen σ bonds) are stronger than the bonds broken (one carbon-carbon π bond and one hydrogen-hydrogen σ bond). Because the addition of atoms to the π bond of alkenes to form new σ bonds is a general and characteristic reaction of alkenes, alkenes are said to be unsaturated. Alkanes, which cannot be transformed by addition reactions into molecules with a greater number of σ bonds, are said to be saturated.
The alkene functional group is an important one in chemistry and is widespread in nature. Some common examples (shown here) include ethylene (used to make polyethylene), 2-methyl-1,3-butadieneisoprene (used to make rubber), and vitamin A (essential for vision).
For ethene, both the carbon atoms of an alkene and the four atoms connected to the double bond lie in a single plane.
Molecules that contain a triple bond between two carbon atoms are known as alkynes. The triple bond is made up of one σ bond and two π bonds. As in alkenes, the π bonds constitute regions of increased electron density lying parallel to the carbon-carbon bond axis. Carbon-carbon triple bonds are very strong bonds, but reactions do occur that break the π bonds to form stronger σ bonds.
The most common example of an alkyne is ethyne (also known as acetylene), used as a fuel for oxyacetylene torches in welding applications. Alkynes are not abundant in nature, but the fungicide capillan contains two alkyne functional groups.
A distinctive set of physical and chemical properties is imparted to molecules that contain a functional group composed of three pairs of doubly bonded atoms (usually all carbon atoms) bonded together in the shape of a regular planar (flat) hexagon. The hexagonal ring is usually drawn with an alternating sequence of single and double bonds. The mol...
An oxygen atom normally forms two σ bonds with other atoms; the water molecule, H2O, is the simplest and most common example. If one hydrogen atom is removed from a water molecule, a hydroxyl functional group (―OH) is generated. When a hydroxyl group is joined to an alkane framework, an alcohol such as ethanol, is produced.
When the hydroxyl group is joined to an aryl ring, a phenol results (shown above). Both alcohols and phenols are widespread in nature, with alcohols being especially ubiquitous. The hydroxyl group of alcohols and phenols is responsible for an interesting variety of physical and chemical properties. The biochemical action of vitamin E, for example, depends largely on the reactivity of the phenol functional group.
An organic molecule in which an oxygen atom is bonded to two carbon atoms through two sigma bonds is known as an ether. Ether molecules occur widely in nature. Diethyl ether was once widely used as an anesthetic. An aromatic ether known as Nerolin II (2-ethoxynaphthalene) is used in perfumes to impart the scent of orange blossoms. Cyclic ethers, such as tetrahydrofuran, are commonly used as organic solvents. Although ethers contain two polar carbon-oxygen bonds, they are much less reactive than alcohols or phenols.
Epoxides are cyclic ethers that contain a three-membered ring. The simplest example is oxirane (ethylene oxide). An epoxide is one of the functional groups in the insect hormone known as juvenile hormone.
Organic matter in soils ranges from recognizable plant parts (roots, leaves, stems) to humus, which is partly decomposed plant material that is amorphous and spongy in nature. Organic matter contributes to a soil׳s ability to retain nutrients and water (i.e., soil׳s CEC).
Extension. publications. Soil Organic Matter Does Matter. (SF1942, Nov. 2019) Publication File: Soil Organic Matter Does Matter. This publication talks about soil organic matter and its classifications and benefits. It also describes how to build organic matter and how it is destroyed. Lead Author: