Hydroxyl radical

The hydroxyl radical is the diatomic molecule
OH. The hydroxyl radical is very stable as a dilute gas, but it decays very rapidly in the condensed phase. It is pervasive in some situations.[2] Most notably the hydroxyl radicals are produced from the decomposition of hydroperoxides (ROOH) or, in atmospheric chemistry, by the reaction of excited atomic oxygen with water. It is also important in the field of radiation chemistry, since it leads to the formation of hydrogen peroxide and oxygen, which can enhance corrosion and SCC in coolant systems subjected to radioactive environments. The unpaired electron of the hydroxyl radical is officially represented by a middle dot, •, beside the O.[3]

Hydroxyl radical
Stick model of the hydroxyl radical with molecular orbitals
Names
IUPAC name
Hydroxyl radical
Systematic IUPAC name
  • Oxidanyl[1] (substitutive)
  • Hydridooxygen(•)[1] (additive)
Other names
  • Hydroxy
  • Hydroxyl
  • λ1-Oxidanyl
Identifiers
3D model (JSmol)
ChEBI
ChemSpider
105
KEGG
  • InChI=1S/HO/h1H checkY
    Key: TUJKJAMUKRIRHC-UHFFFAOYSA-N checkY
  • [OH]
Properties
HO
Molar mass 17.007 g·mol−1
Thermochemistry
183.71 J K−1 mol−1
38.99 kJ mol−1
Related compounds
Related compounds
 O2H+
OH
O22−
Except where otherwise noted, data are given for materials in their standard state (at 25 °C [77 °F], 100 kPa).
Infobox references

Structure and bonding

The O-H distance is 0.97 Å. The O-H vibrational frequency is 3570 cm-1. These data are very similar to those for water.[4] The radical resides on the oxygen atom. With nine electrons, hydroxyl's electronic structure is described by (1s)2(2sσ)2(2pσ)2(2pπ)3.[5]

The electronic angular momentum along the molecular axis is +1 or −1, and the electronic spin angular momentum S = 12. Because of the orbit-spin coupling, the spin angular momentum can be oriented in parallel or anti parallel directions to the orbital angular momentum, producing the splitting into Π12 and Π32 states. The 2Π32 ground state of OH is split by lambda doubling interaction (an interaction between the nuclei rotation and the unpaired electron motion around its orbit). Hyperfine interaction with the unpaired spin of the proton further splits the levels.

Production

Hydroxyl radicals can be generated in several ways.[6]

Photolysis of H2O2

Laser photolysis of hydrogen peroxide proceeds with a quantum yield of 0.4-0.5:

H2O2 → 2 HO·

The recombination of hydroxyl radicals proceeds with a second order rate constant of 4.7 × 109 M−1s−1 (25 °C).

Hydroxyl radicals undergo a series of reactions with hydrogen peroxide, initially giving hydroperoxo radical:

H2O2 + HO· → H2O + HO2·

and subsequently regenerating the hydroxyl radical together with oxygen:

H2O2 + HO2· → H2O + O2 + HO·

Fenton reaction

The Fenton reaction produces hydroxyl radicals by this stoichiometry:

H2O2 + Fe+2 → HO· + FeOH+2

In this equation Fe2+ is the aquo complex [Fe(H2O)6]2+ and FeOH2+ is a ferric derivative [Fe(OH)(H2O)5]2+. The reaction is often conduced at pH 3−4, and proceeds with concomitant rrecipitation of solid ferric hydroxide. Many variations of this process have been developed such as the use of ferrous complex of edta. The complexant edta allows one to generate hydroxyl radicals at pH 7, which is compatible with DNA and other biomolecules. This approach is used in DNA footprinting.[6]

Radiolysis

Pulse radiolysis of water produces hydroxyl radicals as well as solvated electrons.

H2O → e + H2O+
H2O+ → HO· + H+

Quenching occurs by formation of hydrogen peroxide and hydroxide formation: HO· + e → OH


Chemical and biochemical reactions

The hydroxyl radical reacts at nearly diffusion rates with all organic compounds. Thus, it is the most dangerous member of the reactive oxygen species. In one manifestation of this reactivity, the hydroxyl radical contributes significantly in vivo to oxidative damage to DNA. The hydroxyl radical can cause numerous types of damage to the nucleotide bases of DNA (for example, formation of 8-Oxo-2'-deoxyguanosine), as well as deoxyribose damage, strand breaks and interstrand cross-links. Oxidative damage to DNA has an important role in the origin and progression of several human diseases, most prominently cancer, but also neurodegenerative diseases and atherosclerosis.[7]

Water purification

Hydroxyl radicals play a key role in the oxidative destruction of organic pollutants using a series of methodologies collectively known as advanced oxidation processes (AOPs). The destruction of pollutants in AOPs is based on the non-selective reaction of hydroxyl radicals on organic compounds. It is highly effective against a series of pollutants including pesticides, pharmaceutical compounds, dyes, etc.[8][9]

Atmosphere

Hydroxyl radical is pervasive in the atmosphere and its behavior governs much of atmospheric chemistry.[10] Although its lifetime is about 1 second, the hydroxyl OH radical is reactive toward many components of the atmosphere including methane, sulfur dioxide, carbon monoxide, nitrogen oxides, and any organic compound.[11] Atmospheric hydroxyl is estimated to remove 3.7 gigatons of gases annually. In addition to the previously listed gases, other gases destroyed include HFCs and HCFC's.[12]

Understanding the role of OH in the oxidation process of methane (CH4) present in the atmosphere to first carbon monoxide (CO) and then carbon dioxide (CO2) is important for assessing the residence time of this greenhouse gas, the overall carbon budget of the troposphere, and its influence on the process of global warming. The lifetime of OH radicals in the Earth atmosphere is very short, therefore OH concentrations in the air are very low and very sensitive techniques are required for its direct detection.[13] Global average hydroxyl radical concentrations have been measured indirectly by analyzing methyl chloroform (CH3CCl3) present in the air. The results obtained by Montzka et al. (2011)[14] shows that the interannual variability in OH estimated from CH3CCl3 measurements is small, indicating that global OH is generally well buffered against perturbations. This small variability is consistent with measurements of methane and other trace gases primarily oxidized by OH, as well as global photochemical model calculations.

In 2014, researchers reported their discovery of a "hole" or absence of hydroxyl throughout the entire depth of the troposphere across a large region of the tropical West Pacific. They suggested that this hole is permitting large quantities of ozone-degrading chemicals to reach the stratosphere, and that this may be significantly reinforcing ozone depletion in the polar regions with potential consequences for the climate of the Earth.[15]

Astronomy

It is convenient to distinguish two types of interstellar clouds: diffuse clouds, with T = 30–100 K and n = 10–1000 cm−3, and dense clouds, with T = 10–30 K and density n = 104103 cm−3.[16]

The first experimental evidence for the presence of 18 cm absorption lines of the hydroxyl (OH) radical in the radio absorption spectrum of Cassiopeia A was obtained by Weinreb et al.[17] based on observations made during the period October 15–29, 1963.[18] Reports on interstellar hydroxyl radical continued in earnest in the 1960's and 1970's.[19][20][21][22][23][24][25]

Production pathways in the interstellar medium

The OH radical is linked with the production of H2O in molecular clouds. Studies of OH distribution in Taurus Molecular Cloud-1 (TMC-1)[26] suggest that in dense gas, OH is mainly formed by dissociative recombination of H3O+. Dissociative recombination is the reaction in which a molecular ion recombines with an electron and dissociates into neutral fragments. Important formation mechanisms for OH are:

H3O+ + eOH + H2

 

 

 

 

(Dissociative recombination:           1a)

H3O+ + eOH + H + H

 

 

 

 

(Dissociative recombination:           1b)

HCO+
2 + eOH + CO

 

 

 

 

(Dissociative recombination:           2a)

O + HCO → OH + CO

 

 

 

 

(Neutral–neutral:           3a)

H + H3O+OH + H2 + H

 

 

 

 

(Ion–molecular ion neutralization:          4a)

Destruction pathways in the interstellar medium

Small neutral molecules in the interstellar clouds may be formed by reactions of H and OH.[27] The formation of O2 occurs in the gas phase via the neutral exchange reaction between O and OH, which is also the main sink for OH in dense regions.[26]

Atomic oxygen takes part both in the production and destruction of OH, so the abundance of OH depends mainly on the H3+ abundance. Then, important chemical pathways leading from OH radicals are:

OH + O → O2 + H

 

 

 

 

(Neutral–neutral:           1A)

OH + C+ → CO+ + H

 

 

 

 

(Ion–neutral:           2A)

OH + N → NO + H

 

 

 

 

(Neutral–neutral:           3A)

OH + C → CO + H

 

 

 

 

(Neutral–neutral:           4A)

OH + H → H2O + photon

 

 

 

 

(Neutral–neutral:           5A)

Rate constants and relative rates for important formation and destruction mechanisms

Rate constants can be derived from the dataset published in a website.[28] Rate constants have the form:

k(T) = α(T/300)β × exp(−γ/T) cm3 s−1

The following table has the rate constants calculated for a typical temperature in a dense cloud T = 10 K.

Reaction k at T = 10 K (cm3·s−1)
1a 3.29×10−6
1b 1.41×10−7
2a 4.71×10−7
3a 5.0×10−11
4a 1.26×10−6
5a 2.82×10−6
1A 7.7×10−10
2A 3.5×10−11
3A 1.38×10−10
4A 1.0×10−10
5A 3.33×10−14

Formation rates rix can be obtained using the rate constants k(T) and the abundances of the reactants species C and D:

rix = k(T)ix[C][D]

where [Y] represents the abundance of the species Y. In this approach, abundances were taken from The UMIST database for astrochemistry 2006, and the values are relatives to the H2 density. The following table shows the ratio rix/r1a in order to get a view of the most important reactions.

r1a r1b r2a r3a r4a r5a
r1a 1.0 0.043 0.013 0.035 3.6×10−5 0.679

The results suggest that 1a reaction is the most prominent reaction in dense clouds. It is in concordance with Harju et al. 2000.

The next table shows the results by doing the same procedure for the destruction reaction:

r1A r2A r3A r4A r5A
r1A 1.0 6.14×10−3 0.152 3.6×10−5 4.29×10−3

The results show that reaction 1A is the main sink for OH in dense clouds.

Interstellar observations

Discoveries of the microwave spectra of a considerable number of molecules prove the existence of rather complex molecules in the interstellar clouds, and provides the possibility to study dense clouds, which are obscured by the dust they contain.[29] The OH molecule has been observed in the interstellar medium since 1963 through its 18 cm transitions.[30] In the subsequent years OH was observed by its rotational transitions at far infrared wavelengths, mainly in the Orion region. Because each rotational level of OH is split in by lambda doubling, astronomers can observe a wide variety of energy states from the ground state.

Tracer of shock conditions

Very high densities are required to thermalize the rotational transitions of OH,[31] so it is difficult to detect far-infrared emission lines from a quiescent molecular cloud. Even at H2 densities of 106 cm−3, dust must be optically thick at infrared wavelengths. But the passage of a shock wave through a molecular cloud is precisely the process which can bring the molecular gas out of equilibrium with the dust, making observations of far-infrared emission lines possible. A moderately fast shock may produce a transient raise in the OH abundance relative to hydrogen. So, it is possible that far-infrared emission lines of OH can be a good diagnostic of shock conditions.

In diffuse clouds

Diffuse clouds are of astronomical interest because they play a primary role in the evolution and thermodynamics of ISM. Observation of the abundant atomic hydrogen in 21 cm has shown good signal-to-noise ratio in both emission and absorption. Nevertheless, HI observations have a fundamental difficulty when they are directed at low mass regions of the hydrogen nucleus, as the center part of a diffuse cloud: the thermal width of the hydrogen lines are of the same order as the internal velocities of structures of interest, so cloud components of various temperatures and central velocities are indistinguishable in the spectrum. Molecular line observations in principle do not suffer from this problem. Unlike HI, molecules generally have excitation temperature TexTkin, so that emission is very weak even from abundant species. CO and OH are the most easily studied candidate molecules. CO has transitions in a region of the spectrum (wavelength < 3 mm) where there are not strong background continuum sources, but OH has the 18 cm emission, line convenient for absorption observations.[32] Observation studies provide the most sensitive means of detections of molecules with subthermal excitation, and can give the opacity of the spectral line, which is a central issue to model the molecular region.

Studies based in the kinematic comparison of OH and H I absorption lines from diffuse clouds are useful in determining their physical conditions, especially because heavier elements provide higher velocity resolution.

Masers

OH masers, a type of astrophysical maser, were the first masers to be discovered in space and have been observed in more environments than any other type of maser.

In the Milky Way, OH masers are found in stellar masers (evolved stars), interstellar masers (regions of massive star formation), or in the interface between supernova remnants and molecular material. Interstellar OH masers are often observed from molecular material surrounding ultracompact H II regions (UC H II). But there are masers associated with very young stars that have yet to create UC H II regions.[33] This class of OH masers appears to form near the edges of very dense material, place where H2O masers form, and where total densities drop rapidly and UV radiation form young stars can dissociate the H2O molecules. So, observations of OH masers in these regions, can be an important way to probe the distribution of the important H2O molecule in interstellar shocks at high spatial resolutions.

See also

References
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