- Chemical state
-
Contents
Overview
The chemical state of a chemical element is its electronic, chemical and physical nature as it exists in combination with a group of one or more other elements or in its natural "elemental state"[1][2][3][4][5][6][7]. Material scientists, solid state physicists, analytical chemists, surface scientists and spectroscopists describe or characterize the chemical, physical and/or electronic nature of the surface or the bulk regions of a material as having or existing as one or more chemical states.
The chemical state set comprises and encompasses these subordinate groups and entities: chemical species, functional group, anion, cation, oxidation state, chemical compound and elemental forms of an element.
This term or phrase is commonly used when interpreting data from analytical techniques such as:
- Auger electron spectroscopy (AES)
- Electron probe micro analysis (EPMA)
- Electron spectroscopy for chemical analysis (ESCA, XPS)
- Energy dispersive spectroscopy (EDS, EDX)
- Infrared spectroscopy (IR, FT-IR, ATR)
- Liquid chromatography (LC, HPLC)
- Mass spectrometry (MS, ToF-SIMS, D-SIMS)
- Nuclear magnetic resonance (NMR, H-NMR, C-NMR, X-NMR)
- Photoemission spectroscopy (PES, UPS)
- Raman spectroscopy (FT-Raman)
- Ultraviolet-visible spectroscopy (UV-Vis)
- X-ray photoelectron spectoscopy (XPS, ESCA)
- Wavelength dispersive spectroscopy (WDX, WDS)
Measurement and Interpretation
A material was analyzed by a spectroscopic method and found to contain the elements: Si, C, and O.
- A natural question is: What is the chemical state of the silicon (Si) in that material?
- After measuring the material under high energy resolution conditions (or something similar), the energy or frequency based data (e.g. eV, cm−1) from the silicon signal revealed the presence of 2 distinct signals (peaks) and one shoulder which indicates the presence of three different chemical states of silicon (Si). For the sake of this example, those three signals are consistent with the presence of the chemical states of silicon known as: silicon di-oxide (SiO2), elemental silicon (Si), and a di-alkyl silicone oil.
Significance
The chemical state of a group of elements, can be similar to, but is different from, the chemical state of another very similar group of elements because the two groups have different ratios of the same elements and exhibit different chemical, electronic, and physical properties that can be detected by various spectroscopic techniques.
A chemical state can exist on or inside the surface of a solid state material and can often, but not always, be isolated or separated from the other chemical species found on the surface of that material. Surface scientists, spectroscopists, chemical analysts, and material scientists frequently describe the chemical nature of the chemical species, functional group, anion, or cation detected on the surface and near the surface of a solid state material as its chemical state.
To understand how a chemical state differs from an oxidation state, anion, or cation, we compare sodium fluoride (NaF) to poly-tetrafluoro-ethylene (PTFE, Teflon TM). Both contain fluorine, the most electronegative element, but only NaF dissolves in water to form separate ions, Na+ and F-. The electronegativity of the fluorine strongly polarizes the electron density that exists between the carbon, C, and the fluorine, F, but not enough to produce ions which would allow it to dissolve in the water. The carbon and fluorine in Teflon (PTFE) both have a zero (0) electronic charge since they form a covalent bond, but few scientists describe those elements as has having a zero (0) oxidation state. On the other hand, many elements, in their pure form, are often described as existing with a zero oxidation state. This is one of those quirks of nomenclature that have survived over the years.
The chemical state of an element is often confused with its oxidation state. The chemical state of an element or a group of elements that has a non-zero ionic charge, e.g. (1+), (2+), (3+), (1-), (2-) (3-), is defined as the oxidation state of that element or group of elements. Elements or chemical groups that have an ionic charge can usually be dissolved to form ions in either water or another polar solvent. Such a compound or salt is described as an ionic compound with ionic bonds which means that, in effect, all of the electron density of one or more valence electrons has been transferred from the less electronegative group of elements to the more electronegative group of elements. In the case of a non-ionic compound the chemical bonds are non-ionic such that the compound will probably not dissolve in water or another polar solvent. Many non-ionic compounds have chemical bonds that share the electron density that binds them together. This type of chemical bond is either a non-polar covalent bond or a polar covalent bond.
A functional group is very similar to a chemical species and a chemical group. A chemical group or chemical species exhibits a distinctive reaction behavior or a distinctive spectral signal when analyzed by various spectroscopic methods. These three groupings are often used to describe the groups of elements that exist within an organic molecule.
Examples of chemical names that describe the chemical state of a group of elements
The following list of neutral compounds, anions, cations, functional groups and chemical species is a partial list of the many groups of elements that can exhibit or have a unique "chemical state" while being part of the surface or the bulk of a solid state material.
- Castro acid
- somera
- Metal oxide
- Metal hydroxide
- Metal carbonate
- Inorganic carbonate
- Fluoro-ether
- Organofluoride
- Organic type chlorine
- Inorganic type chlorine
- Trifluoromethyl
- Difluoromethyl
- Benzyl group
- Phenyl group
- Carbonyl bond
- Ether group
- Alcohol bond
- Organic acid
- Double bond
- Triple bond
- Inorganic acid
- Organic ester
- Metal ester
- Organic carbonate
- Nitrile group
- Cyanide ion
- Perchlorate ion
- Sodium ion
- Lithium ion
- Magnesium ion
- Calcium ion
- Lead ion
- Sulfate ion
- Phosphate ion
- Silicate group
- Stannate group
- Halide ion
- Fluoride ion
- Chloride ion
- Bromide ion
- Iodide ion
- Chalcogenide group
- Sulfide group
- Halide group
- Metal sulfide
- Organic sulfide
- Metal selenide
- Telluride
- Nitride
- Nitrite ion
- Nitrate ion
- Phosphide
- Arsenide
- Antimonide
- Silicide
- Silicate
- Gallate
- Germanate
- Tungstate
- Niobate
- Ferric ion
- Ferrous ion
- Ferride
- Ferrate
- Rhenate
- Mercurous
- Mercuric ion
- Mercurate
- Thallate
- Thallic ion
See also
References
- ^ John T. Grant and David Briggs (2003). Surface Analysis by Auger and X-ray Photoelectron Spectroscopy. IM Publications, ISBN 1-901019-04-7.
- ^ Martin P. Seah and David Briggs (1983). Practical Surface Analysis by Auger and X-ray Photoelectron Spectroscopy. Wiley & Sons, ISBN 0-471-26279-X.
- ^ Martin P. Seah and David Briggs (1992). Practical Surface Analysis by Auger and X-ray Photoelectron Spectroscopy (2nd ed.). Wiley & Sons, ISBN 0-471-92082-7.
- ^ ISO 18115:2001 — Surface Chemical Analysis — Vocabulary. International Organisation for Standardisation, TC/201, [1].
- ^ C.D.Wagner, W.M.Riggs, L.E.Davis, J.F.Moulder, and G.E.Mullenberg (1979). Handbook of X-ray Photoelectron Spectroscopy. Perkin-Elmer Corp..
- ^ B. Vincent Crist (2000). Handbook of Monochromatic XPS Spectra - The Elements and Native Oxides. Wiley & Sons, ISBN 0-471-49265-5.
- ^ B. Vincent Crist (2000). Handbook of Monochromatic XPS Spectra - Semiconductors. Wiley & Sons, ISBN 0-471-49266-3.
Categories:
Wikimedia Foundation. 2010.