Nomenclature of Inorganic Chemistry, IUPAC Recommendations 2005 is the 2005 version of Nomenclature of Inorganic Chemistry (which is informally called the Red Book). It is a collection of rules for naming inorganic compounds, as recommended by the International Union of Pure and Applied Chemistry (IUPAC).
The 2005 edition replaces their previous recommendations Nomenclature The Red Book of Inorganic Chemistry, IUPAC Recommendations 1990 (Red Book I), and "where appropriate" (sic) Nomenclature of Inorganic Chemistry II, IUPAC Recommendations 2000 (Red Book II).
The recommendations take up over 300 pages [1] and the full text can be downloaded from IUPAC. [2] Corrections have been issued. [3]
Apart from a reorganisation of the content, there is a new section on organometallics and a formal element list to be used in place of electronegativity lists in sequencing elements in formulae and names. The concept of a preferred IUPAC name (PIN), a part of the revised blue book for organic compound naming, has not yet been adopted for inorganic compounds. There are however guidelines as to which naming method should be adopted.
The recommendations describe a number of different ways in which compounds can be named. These are:
Additionally there are recommendations for the following:
For a simple compound such as AlCl3 the different naming conventions yield the following:
Throughout the recommendations the use of the electronegativity of elements for sequencing has been replaced by a formal list which is loosely based on electronegativity. The recommendations still use the terms electropositive and electronegative to refer to an element's relative position in this list.
A simple rule of thumb ignoring lanthanides and actinides is:
The full list, from highest to lowest "electronegativity" (with the addition of elements 112 through 118, that had not yet been named in 2005, to their respective groups):
Action | Addition compound? | Definite stoichiometry? | mono-atomic? | molecular? | metal present? | Bond to carbon? | transition metal group 3–12? | main group metal groups 1, 2, 3–6? |
---|---|---|---|---|---|---|---|---|
Treat each component separately use compositional | Yes | |||||||
Use solids naming | No | No | ||||||
Element or monatomic cation/anion/radical naming | No | Yes | Yes | |||||
Divide components into "electropositive"/"electronegative" Treat each component separately Use generalised stoichiometric naming | No | Yes | No | No | ||||
Use Blue book (Organic compound) | No | Yes | No | Yes | No | Yes | ||
Use additive naming for group 3- 12 organometallics | No | Yes | No | Yes | Yes | Yes | Yes | |
Use substitutive naming for group 3–6 organometallics Use compositional for groups 1–2 organometallics | No | Yes | No | Yes | Yes | Yes | No | Yes |
Use additive naming for coordination complexes | No | Yes | No | Yes | Yes | No | Yes | |
Choose either substitutive or additive | No | Yes | No | Yes | No | No |
Note "treat separately" means to use the decision table on each component
An indeterminate sample simply takes the element name. For example a sample of carbon (which could be diamond, graphite etc or a mixture) would be named carbon.
This is specified by the element symbol followed by the Pearson symbol for the crystal form. (Note that the recommendations specifically italicize the second character.)
Examples include Pn,. red phosphorus ; Asn, amorphous arsenic.
Compositional names impart little structural information and are recommended for use when structural information is not available or does not need to be conveyed. Stoichiometric names are the simplest and reflect either the empirical formula or the molecular formula. The ordering of the elements follows the formal electronegativity list for binary compounds and electronegativity list to group the elements into two classes which are then alphabetically sequenced. The proportions are specified by di-, tri-, etc. (See IUPAC numerical multiplier.) Where there are known to be complex cations or anions these are named in their own right and then these names used as part of the compound name.
In binary compounds the more electropositive element is placed first in the formula. The formal list is used. The name of the most electronegative element is modified to end in -ide and the more electropositive elements name is left unchanged.
Taking the binary compound of sodium and chlorine: chlorine is found first in the list so therefore comes last in the name. Other examples are
The following illustrate the principles.
The 1:1:1:1 quaternary compound between bromine, chlorine, iodine and phosphorus:
The ternary 2:1:5 compound of antimony, copper and potassium can be named in two ways depending on which element(s) are designated as electronegative.
Monatomic cations are named by taking the element name and following it with the charge in brackets e.g
Sometimes an abbreviated form of the element name has to be taken, e.g. germide for germanium as germanide refers to GeH−
3.
Polyatomic cations of the same element are named as the element name preceded by di-, tri-, etc., e.g.:
Polyatomic cations made up of different elements are named either substitutively or additively, e.g.:
Monatomic anions are named as the element modified with an -ide ending. The charge follows in brackets, (optional for 1−) e.g.:
Some elements take their Latin name as the root e.g
Polyatomic anions of the same element are named as the element name preceded by di-, tri-, etc., e.g.:
or sometimes as an alternative derived from a substitutive name e.g.
Polyatomic anions made up of different elements are named either substitutively or additively, the name endings are -ide and -ate respectively e.g. :
A full list of the alternative acceptable non-systematic names for cations and anions is in the recommendations. Many anions have names derived from inorganic acids and these are dealt with later.
The presence of unpaired electrons can be indicated by a "·". For example:
The use of the term hydrate is still acceptable e.g. Na2SO4·10H2O, sodium sulfate decahydrate. The recommended method would be to name it sodium sulfate—water(1/10). Similarly other examples of lattice compounds are:
As an alternative to di-, tri- prefixes either charge or oxidation state can be used. Charge is recommended as oxidation state may be ambiguous and open to debate.
This naming method generally follows established IUPAC organic nomenclature. Hydrides of the main group elements (groups 13–17) are given -ane base names, e.g. borane, BH3. Acceptable alternative names for some of the parent hydrides are water rather than oxidane and ammonia rather than azane. In these cases the base name is intended to be used for substituted derivatives.
This section of the recommendations covers the naming of compounds containing rings and chains.
BH3 | borane | CH4 | methane | NH3 | azane (ammonia) | H2O | oxidane (water) | HF | fluorane (hydrogen fluoride) |
AlH3 | alumane | SiH4 | silane | PH3 | phosphane (phosphine) | H2S | sulfane (hydrogen sulfide or dihydrogen sulfide) | HCl | chlorane (hydrogen chloride) |
GaH3 | gallane | GeH4 | germane | AsH3 | arsane (arsine) | H2Se | selane (hydrogen selenide or dihydrogen selenide) | HBr | bromane (hydrogen bromide) |
InH3 | indigane | SnH4 | stannane | SbH3 | stibane (stibine) | H2Te | tellane (hydrogen telluride or dihydrogen telluride) | HI | iodane (hydrogen iodide) |
TlH3 | thallane | PbH4 | plumbane | BiH3 | bismuthane (bismuthine) | H2Po | polane (hydrogen polonide or dihydrogen polonide) | HAt | astatane (hydrogen astatide) |
Where a compound has non standard bonding as compared to the parent hydride for example PCl5 the lambda convention is used. For example:
A prefix di-, tri- etc. is added to the parent hydride name. Examples are:
The recommendations describe three ways of assigning "parent" names to homonuclear monocyclic hydrides (i.e single rings consisting of one element):
The stoichiometric name is followed by the number of hydrogen atoms in brackets. For example B2H6, diborane(6). More structural information can be conveyed by adding the "structural descriptor" closo-, nido-, arachno-, hypho-, klado- prefixes.
There is a fully systematic method of numbering the atoms in the boron hydride clusters, and a method of describing the position of bridging hydrogen atoms using the μ symbol.
Use of substitutive nomenclature is recommended for group 13–16 main group organometallic compounds. Examples are:
For organometallic compounds of groups 1–2 can use additive (indicating a molecular aggregate) or compositional naming. Examples are:
However the recommendation notes that future nomenclature projects will be addressing these compounds.
This naming has been developed principally for coordination compounds although it can be more widely applied. Examples are:
The recommendations include a flow chart which can be summarised very briefly:
If the anion name ends in -ide then as a ligand its name is changed to end in -o. For example the chloride anion, Cl− becomes chlorido. This is a difference from organic compound naming and substitutive naming where chlorine is treated as neutral and it becomes chloro, as in PCl3, which can be named as either substitutively or additively as trichlorophosphane or trichloridophosphorus respectively.
Similarly if the anion names end in -ite, -ate then the ligand names are -ito, -ato.
Neutral ligands do not change name with the exception of the following:
Formula | name |
---|---|
Cl− | chlorido |
CN− | cyanido |
H− | hydrido |
D−or 2H− | deuterido or [2H]hydrido |
PhCH2CH2Se− | 2-phenylethane-1-selenolato |
MeCOO− | acetato or ethanoato |
Me2As− | dimethylarsanido |
MePH− | methylphosphanido |
MeCONH2 | acetamide (not acetamido) |
MeCONH− | acetylazanido or acetylamido (not acetamido) |
MeNH2 | methanamine |
MeNH− | methylazanido, or methylamido, or methanaminido |
MePH2 | methylphosphane |
CO | carbonyl |
Ligands are ordered alphabetically by name and precede the central atom name. The number of ligands coordinating is indicated by the prefixes di-, tri-, tetra- penta- etc. for simple ligands or bis-, tris-, tetrakis-, etc. for complex ligands. For example:
Where there are different central atoms they are sequenced using the electronegativity list.
Ligands may bridge two or more centres. The prefix μ is used to specify a bridging ligand in both the formula and the name. For example the dimeric form of aluminium trichloride:
This example illustrates the ordering of bridging and non bridging ligands of the same type. In the formula the bridging ligands follow the non bridging whereas in the name the bridging ligands precede the non bridging. Note the use of the kappa convention to specify that there are two terminal chlorides on each aluminium.
Where there are more than two centres that are bridged a bridging index is added as a subscript. For example in basic beryllium acetate which can be visualised as a tetrahedral arrangement of Be atoms linked by 6 acetate ions forming a cage with a central oxide anion, the formula and name are as follows:
The μ4 describes the bridging of the central oxide ion. (Note the use of the kappa convention to describe the bridging of the acetate ion where both oxygen atoms are involved.) In the name where a ligand is involved in different modes of bridging, the multiple bridging is listed in decreasing order of complexity, e.g. μ3 bridging before μ2 bridging.
The kappa convention is used to specify which ligand atoms are bonding to the central atom and in polynuclear species which atoms, both bridged and unbridged, link to which central atom. For monodentate ligands there is no ambiguity as to which atom is forming the bond to the central atom. However when a ligand has more than one atom that can link to a central atom the kappa convention is used to specify which atoms in a ligand are forming a bond. The element atomic symbol is italicised and preceded by kappa, κ. These symbols are placed after the portion of the ligand name that represents the ring, chain etc where the ligand is located. For example:
Where there is more than one bond formed from a ligand by a particular element a numerical superscript gives the count. For example:
In polynuclear complexes the use of the kappa symbol is extended in two related ways. Firstly to specify which ligating atoms bind to which central atom and secondly to specify for a bridging ligand which central atoms are involved. The central atoms must be identified, i.e. by assigning numbers to them. (This is formally dealt with in the recommendations). To specify which ligating atoms in a ligand link to which central atom, the central atom numbers precede the kappa symbol, and numerical superscript specifies the number of ligations and this is followed by the atomic symbol. Multiple occurrences are separated by commas.
Examples:
The use of η to denote hapticity is systematised. The use of η1 is not recommended. When the specification of the atoms involved is ambiguous the position of the atoms must be specified. This is illustrated by the examples:
For any coordination number above 2 more than one coordination geometry is possible. For example four coordinate coordination compounds can be tetrahedral, square planar, square pyramidal or see-saw shaped. The polyhedral symbol is used to describe the geometry. A configuration index is determined from the positions of the ligands and together with the polyhedral symbol is placed at the beginning of the name. For example in the complex (SP-4-3)-(acetonitrile)dichlorido(pyridine)platinum(II) the (SP-4-3) at the beginning of the name describes a square planar geometry, 4 coordinate with a configuration index of 3 indicating the position of the ligands around the central atom. For more detail see polyhedral symbol.
Additive nomenclature is generally recommended for organometallic compounds of groups 3-12 (transition metals and zinc, cadmium and mercury).
Following on from ferrocene—the first sandwich compound with a central Fe atom coordinated to two parallel cyclopentadienyl rings—names for compounds with similar structures such as osmocene and vanadocene are in common usage. The recommendation is that the name-ending ocene should be restricted to compounds where there are discrete molecules of bis(η5-cyclopentadienyl)metal (and ring-substituted analogues), where the cyclopentadienyl rings are essentially parallel, and the metal is in the d-block. The terminology does NOT apply to compounds of the s- or p-block elements such as Ba(C5H5)2 or Sn(C5H5)2.
Examples of compounds that meet the criteria are:
Examples of compounds that should not be named as metallocenes are:
In polynuclear compounds with metal-metal bonds these are shown after the element name as follows: (3 Os—Os) in Decacarbonyldihydridotriosmium. A pair of brackets contain a count of the bonds formed (if greater than 1), followed by the italicised element atomic symbols separated by an "em-dash".
The geometries of polynuclear clusters can range in complexity. A descriptor e.g. tetrahedro or the CEP descriptor e.g. Td-(13)-Δ4-closo] can be used. this is determined by the complexity of the cluster. Some examples are shown below of descriptors and CEP equivalents. (The CEP descriptors are named for Casey, Evans and Powell who described the system. [4]
number of atoms | descriptor | CEP descriptor |
---|---|---|
3 | triangulo | |
4 | quadro | |
4 | tetrahedro | [Td-(13)-Δ4-closo] |
5 | [D3h-(131)-Δ6-closo] | |
6 | octahedro | [Oh-(141)-Δ8-closo] |
6 | triprismo | |
8 | antiprismo | |
8 | dodecahedro | [D2d-(2222)-Δ6-closo] |
12 | icosahedro | [Ih-(1551)-Δ20-closo] |
Examples:
decacarbonyldimanganese bis(pentacarbonylmanganese)(Mn—Mn)
dodecacarbonyltetrarhodium tri-μ-carbonyl-1:2κ2C;1:3κ2C;2:3κ2C-nonacarbonyl- 1κ2C,2κ2C,3κ2C,4κ3C-[Td-(13)-Δ4-closo]-tetrarhodium(6 Rh—Rh)
or tri-μ-carbonyl-1:2κ2C;1:3κ2C;2:3κ2C-nonacarbonyl- 1κ2C,2κ2C,3κ2C,4κ3C-tetrahedro-tetrarhodium(6 Rh—Rh)
The recommendations include a description of hydrogen names for acids. The following examples illustrate the method:
Note that the difference from the compositional naming method (hydrogen sulfide) as in hydrogen naming there is NO space between the electropositive and electronegative components.
This method gives no structural information regarding the position of the hydrons (hydrogen atoms). If this information is to be conveyed then the additive name should be used (see the list below for examples).
The recommendations give a full list of acceptable names for common acids and related anions. A selection from this list is shown below.
acid acceptable name | related anions- acceptable names and additive names | ||
---|---|---|---|
boric acid, [B(OH)3] | dihydrogenborate, [BO(OH)2]− dihydroxidooxidoborate(1—) | hydrogenborate, [BO2(OH)]2− hydroxidodioxidoborate(2—) | borate, [BO3]3− trioxidoborate(3—) |
carbonic acid, [CO(OH)2] | hydrogencarbonate, [CO2(OH)]− hydroxidodioxidocarbonate(1−) | carbonate, [CO3]2− trioxidocarbonate(2−) | |
chloric acid, [ClO2(OH)] hydroxidodioxidochlorine | chlorate, [ClO3]− trioxidochlorate(1−) | ||
chlorous acid, [ClO(OH)] hydroxidooxidochlorine | chlorite, [ClO2]− dioxidochlorate(1−) | ||
nitric acid, [NO2(OH)] hydroxidodioxidonitrogen | nitrate, [NO−3] trioxidonitrate(1−) | ||
nitrous acid, [NO(OH)] hydroxidooxidonitrogen | nitrite, [NO2]− dioxidonitrate(1−) | ||
perchloric acid, [ClO3(OH)] hydroxidotrioxidochlorine | perchlorate, [ClO4]− tetraoxidochlorate(1−) | ||
phosphoric acid, [PO(OH)3] trihydroxidooxidophosphorus | dihydrogenphosphate, [PO2(OH)2]− dihydroxidodioxidophosphate(1−) | hydrogenphosphate, [PO3(OH)]2− hydroxidotrioxidophosphate(2−) | phosphate, [PO4]3− tetraoxidophosphate(3—) |
phosphonic acid, [PHO(OH)2] hydridodihydroxidooxidophosphorus | hydrogenphosphonate, [PHO2(OH)]− hydridohydroxidodioxidophosphate(1−) | phosphonate, [PHO3]2− hydridotrioxidophosphate(2−) | |
phosphorous acid, H3PO3 trihydroxidophosphorus | dihydrogenphosphite [PO(OH)2]− dihydroxidooxidophosphate(1−)) | hydrogenphosphite, [PO2(OH)]2− hydroxidodioxidophosphate(2−) | phosphite, [PO3]3− trioxidophosphate(3−) |
sulfuric acid, [SO2(OH)2] dihydroxidodioxidosulfur | hydrogensulfate, [SO3(OH)]− hydroxidotrioxidosulfate(1−) | sulfate, [SO4]2− tetraoxidosulfate(2−) |
Stoichiometric phases are named compositionally. Non-stoichiometric phases are more difficult. Where possible formulae should be used but where necessary naming such as the following may be used:
Generally mineral names should not be used to specify chemical composition. However a mineral name can be used to specify the structure type in a formula e.g.
A simple notation may be used where little information on the mechanism for variability is either available or is not required to be conveyed:
Where there is a continuous range of composition this can be written e.g., K(Br,Cl) for a mixture of KBr and KCl and (Li2,Mg)Cl2 for a mixture of LiCl and MgCl2. The recommendation is to use the following generalised method e.g.
Note that cation vacancies in CoO could be described by CoO1−x
Point defects, site symmetry and site occupancy can all be described using Kröger–Vink notation, note that the IUPAC preference is for vacancies to be specified by V rather than V (the element vanadium).
To specify the crystal form of a compound or element the Pearson symbol may be used. The use of Strukturbericht (e.g. A1 etc) or Greek letters is not acceptable. The Pearson symbol may be followed by the space group and the prototype formula. Examples are:
It is recommended that polymorphs are identified (e.g. for ZnS where the two forms zincblende (cubic) and wurtzite (hexagonal)), as ZnS(c) and ZnS(h) respectively.
A coordination complex is a chemical compound consisting of a central atom or ion, which is usually metallic and is called the coordination centre, and a surrounding array of bound molecules or ions, that are in turn known as ligands or complexing agents. Many metal-containing compounds, especially those that include transition metals, are coordination complexes.
In organic chemistry, a functional group is a substituent or moiety in a molecule that causes the molecule's characteristic chemical reactions. The same functional group will undergo the same or similar chemical reactions regardless of the rest of the molecule's composition. This enables systematic prediction of chemical reactions and behavior of chemical compounds and the design of chemical synthesis. The reactivity of a functional group can be modified by other functional groups nearby. Functional group interconversion can be used in retrosynthetic analysis to plan organic synthesis.
Inorganic chemistry deals with synthesis and behavior of inorganic and organometallic compounds. This field covers chemical compounds that are not carbon-based, which are the subjects of organic chemistry. The distinction between the two disciplines is far from absolute, as there is much overlap in the subdiscipline of organometallic chemistry. It has applications in every aspect of the chemical industry, including catalysis, materials science, pigments, surfactants, coatings, medications, fuels, and agriculture.
Ionic bonding is a type of chemical bonding that involves the electrostatic attraction between oppositely charged ions, or between two atoms with sharply different electronegativities, and is the primary interaction occurring in ionic compounds. It is one of the main types of bonding, along with covalent bonding and metallic bonding. Ions are atoms with an electrostatic charge. Atoms that gain electrons make negatively charged ions. Atoms that lose electrons make positively charged ions. This transfer of electrons is known as electrovalence in contrast to covalence. In the simplest case, the cation is a metal atom and the anion is a nonmetal atom, but these ions can be more complex, e.g. molecular ions like NH+
4 or SO2−
4. In simpler words, an ionic bond results from the transfer of electrons from a metal to a non-metal to obtain a full valence shell for both atoms.
A metallocene is a compound typically consisting of two cyclopentadienyl anions (C
5H−
5, abbreviated Cp) bound to a metal center (M) in the oxidation state II, with the resulting general formula (C5H5)2M. Closely related to the metallocenes are the metallocene derivatives, e.g. titanocene dichloride or vanadocene dichloride. Certain metallocenes and their derivatives exhibit catalytic properties, although metallocenes are rarely used industrially. Cationic group 4 metallocene derivatives related to [Cp2ZrCH3]+ catalyze olefin polymerization.
Organometallic chemistry is the study of organometallic compounds, chemical compounds containing at least one chemical bond between a carbon atom of an organic molecule and a metal, including alkali, alkaline earth, and transition metals, and sometimes broadened to include metalloids like boron, silicon, and selenium, as well. Aside from bonds to organyl fragments or molecules, bonds to 'inorganic' carbon, like carbon monoxide, cyanide, or carbide, are generally considered to be organometallic as well. Some related compounds such as transition metal hydrides and metal phosphine complexes are often included in discussions of organometallic compounds, though strictly speaking, they are not necessarily organometallic. The related but distinct term "metalorganic compound" refers to metal-containing compounds lacking direct metal-carbon bonds but which contain organic ligands. Metal β-diketonates, alkoxides, dialkylamides, and metal phosphine complexes are representative members of this class. The field of organometallic chemistry combines aspects of traditional inorganic and organic chemistry.
In chemistry, a hydride is formally the anion of hydrogen (H−), a hydrogen atom with two electrons. The term is applied loosely. At one extreme, all compounds containing covalently bound H atoms are called hydrides: water (H2O) is a hydride of oxygen, ammonia is a hydride of nitrogen, etc. For inorganic chemists, hydrides refer to compounds and ions in which hydrogen is covalently attached to a less electronegative element. In such cases, the H centre has nucleophilic character, which contrasts with the protic character of acids. The hydride anion is very rarely observed.
The coordination geometry of an atom is the geometrical pattern defined by the atoms around the central atom. The term is commonly applied in the field of inorganic chemistry, where diverse structures are observed. The coodination geometry depends on the number, not the type, of ligands bonded to the metal centre as well as their locations. The number of atoms bonded is the coordination number. The geometrical pattern can be described as a polyhedron where the vertices of the polyhedron are the centres of the coordinating atoms in the ligands.
A chemical nomenclature is a set of rules to generate systematic names for chemical compounds. The nomenclature used most frequently worldwide is the one created and developed by the International Union of Pure and Applied Chemistry (IUPAC).
In chemical nomenclature, the IUPAC nomenclature of inorganic chemistry is a systematic method of naming inorganic chemical compounds, as recommended by the International Union of Pure and Applied Chemistry (IUPAC). It is published in Nomenclature of Inorganic Chemistry. Ideally, every inorganic compound should have a name from which an unambiguous formula can be determined. There is also an IUPAC nomenclature of organic chemistry.
An oxyacid, oxoacid, or ternary acid is an acid that contains oxygen. Specifically, it is a compound that contains hydrogen, oxygen, and at least one other element, with at least one hydrogen atom bonded to oxygen that can dissociate to produce the H+ cation and the anion of the acid.
Titanocene dichloride is the organotitanium compound with the formula (η5-C5H5)2TiCl2, commonly abbreviated as Cp2TiCl2. This metallocene is a common reagent in organometallic and organic synthesis. It exists as a bright red solid that slowly hydrolyzes in air. It shows antitumour activity and was the first non-platinum complex to undergo clinical trials as a chemotherapy drug.
In coordination chemistry, a bridging ligand is a ligand that connects two or more atoms, usually metal ions. The ligand may be atomic or polyatomic. Virtually all complex organic compounds can serve as bridging ligands, so the term is usually restricted to small ligands such as pseudohalides or to ligands that are specifically designed to link two metals.
In coordination chemistry, hapticity is the coordination of a ligand to a metal center via an uninterrupted and contiguous series of atoms. The hapticity of a ligand is described with the Greek letter η ('eta'). For example, η2 describes a ligand that coordinates through 2 contiguous atoms. In general the η-notation only applies when multiple atoms are coordinated. In addition, if the ligand coordinates through multiple atoms that are not contiguous then this is considered denticity, and the κ-notation is used once again. When naming complexes care should be taken not to confuse η with μ ('mu'), which relates to bridging ligands.
Organotitanium chemistry is the science of organotitanium compounds describing their physical properties, synthesis, and reactions. Organotitanium compounds in organometallic chemistry contain carbon-titanium chemical bonds. They are reagents in organic chemistry and are involved in major industrial processes.
Cyclopentadienylindium(I), C5H5In, is an organoindium compound containing indium in the +1 oxidation state. Commonly abbreviated to CpIn, it is a cyclopentadienyl complex with a half-sandwich structure. It was the first (1957) low valent organoindium compound reported.
Sodium cyclopentadienide is an organosodium compound with the formula C5H5Na. The compound is often abbreviated as NaCp, where Cp− is the cyclopentadienide anion. Sodium cyclopentadienide is a colorless solid, although samples often are pink owing to traces of oxidized impurities.
Rhodocene is a chemical compound with the formula [Rh(C5H5)2]. Each molecule contains an atom of rhodium bound between two planar aromatic systems of five carbon atoms known as cyclopentadienyl rings in a sandwich arrangement. It is an organometallic compound as it has (haptic) covalent rhodium–carbon bonds. The [Rh(C5H5)2] radical is found above 150 °C (302 °F) or when trapped by cooling to liquid nitrogen temperatures (−196 °C [−321 °F]). At room temperature, pairs of these radicals join via their cyclopentadienyl rings to form a dimer, a yellow solid.
Cyclopentadienyliron dicarbonyl dimer is an organometallic compound with the formula [(η5-C5H5)Fe(CO)2]2, often abbreviated to Cp2Fe2(CO)4, [CpFe(CO)2]2 or even Fp2, with the colloquial name "fip dimer". It is a dark reddish-purple crystalline solid, which is readily soluble in moderately polar organic solvents such as chloroform and pyridine, but less soluble in carbon tetrachloride and carbon disulfide. Cp2Fe2(CO)4 is insoluble in but stable toward water. Cp2Fe2(CO)4 is reasonably stable to storage under air and serves as a convenient starting material for accessing other Fp (CpFe(CO)2) derivatives (described below).
Organothorium chemistry describes the synthesis and properties of organothorium compounds, chemical compounds containing a carbon to thorium chemical bond.