Nitrosyl bromide
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Chemical formula | NOBr | ||
| Molar mass | 109.910 g/mol | ||
| Appearance | Red gas | ||
| Boiling point | 14.5 °C (58.1 °F; 287.6 K) | ||
Refractive index (nD) | 1.524 | ||
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Except where otherwise noted, data are given for materials in their standard state (at 25 °C [77 °F], 100 kPa). Infobox references | |||
Chemical compound
Nitrosyl bromide is the chemical compound with the chemical formula NOBr. It is a red gas with a condensing point just below room temperature.[1] It reacts with water.[1]
Nitrosyl bromide can be formed by the reversible reaction of nitric oxide with bromine.[2] This reaction is of interest as it is one of very few third-order homogeneous gas reactions. NOBr is prone to photodissociation at standard pressure and temperature.
- 2 NO + Br2 ⇌ 2 NOBr
Another way to make it is by way of nitric oxide reacting with potassium bromide.[1]
- 2NO2 + KBr → BrNO + KNO3
Dissociation kinetics
The bond breaking of the chemical can be done with photolysis using a light to separate the molecules that are present. Another to separate nitrosyl bromide into NO and Br or Br2 is by having excess of NO which then the experiment will follow first order kinetics. This reverse rate constant was calculated to be kr = 2.29 ± 0.33 x 10-21 cm3 /molecules
With excess Br2 plus NO the reaction follows third order kinetics.
Br2 + 2NO ↔ 2BrNO
Some of the previous experiments that determined reaction rates were also done by Histatsune and Zafonte, Hippler, and Godfrey. Histatsune and Zafonte determined the forward and reverse reaction rate constants. Hippler studied the recombination of Br atoms after photoylsis of less than 0.3 torr of Br2 at room temperate in the range of 1 - 100 atm. He also studied the 2 recombination of Br and NO in the presence of helium. Godfrey examined the kinetics of BrNO formation and destruction using time resolved photolysis techniques. He also included the effects of the loss of Br2 to internal surfaces of the cell in calculations of the reaction rate constants. The reaction rates were determined to be between the range of 1.32 ± 0.14 to 1.68 ± 0.11 x 10-38 cm6 /molecule2 -s for kf and from 2.09 ± 0.55 to 3.71 x 10-21 cm3 /molecule-s for kr.
There was a rate constant found of kf = 1.56 ± 0.20 x 10-38 cm6 /molecule2 - s at 293 ± 1 K[3]
The third order reaction is the best reaction to show the formation of nitrosyl bromide. The third order reaction is rare to see with bond breaking reactions between stable molecules but there have been no experiments to prove that this experiment does not have any intermediate steps, but it is suspected that there is two steps. [3]
Safety Precautions
Nitrosyl bromide photodissociates to toxic chemicals (bromine and nitric oxide). The chemical or its decomposition products should not get into contact with skin or eyes. Breathing or wafting any of these chemicals towards oneself can endanger health.
Physical characteristics
Nitrosyl bromide is a red gas at room temperate.
References
Footnotes
- ^ a b c Ratcliffe, Charles T.; Shreeve, Jean'ne M.; Wynne, Kenneth J. (January 1968). "Nitrosyl Halides". Inorganic Syntheses. Vol. 11. pp. 194–200. doi:10.1002/9780470132425.ch39. ISBN 9780470131701.
- ^ Esposti, C.D.; Tamassia, F.; Cazzoli, G.; Kisiel, Z. (April 1995). "Millimeter-Wave Spectrum of Nitrosyl Bromide in the Low-Lying Excited States: Equilibrium Structure and Cubic Force Field". Journal of Molecular Spectroscopy. 170 (2): 582–600. Bibcode:1995JMoSp.170..582E. doi:10.1006/jmsp.1995.1093.
- ^ a b Y. Lian et al., Theoretical study on the structure and dissociation mechanism of electronic excited states of nitrosyl bromide molecules. The Journal of Physical Chemistry A. 126, 2936–2941 (2022).
General sources
- Mahoney, Lori A., "The Kinetics Following Photolysis of Nitrosyl Bromide" (2004). Theses and Dissertations. 3719. https://scholar.afit.edu/etd/3719
- C. M. Blair, P. D. Brass, D. M. Yost, The equilibrium between nitric oxide, bromine and nitrosyl bromide. Journal of the American Chemical Society. 56, 1916–1918 (1934)
External links
Media related to Nitrosyl bromide at Wikimedia Commons
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Salts and covalent derivatives of the bromide ion
| HBr | He | ||||||||||||||||||||
| LiBr | BeBr2 | BBr3 +BO3 | CBr4 +C | NBr3 BrN3 NH4Br NOBr +N | Br2O BrO2 Br2O3 Br2O5 | BrF BrF3 BrF5 | Ne | ||||||||||||||
| NaBr | MgBr2 | AlBr AlBr3 | SiBr4 | PBr3 PBr5 PBr7 +P | S2Br2 SBr2 | BrCl | Ar | ||||||||||||||
| KBr | CaBr2 | ScBr3 | TiBr2 TiBr3 TiBr4 | VBr2 VBr3 | CrBr2 CrBr3 | MnBr2 | FeBr2 FeBr3 | CoBr2 | NiBr2 NiBr42− | CuBr CuBr2 | ZnBr2 | GaBr3 | GeBr2 GeBr4 | AsBr3 +As +AsO3 | SeBr2 SeBr4 | Br2 | Kr | ||||
| RbBr | SrBr2 | YBr3 | ZrBr3 ZrBr4 | NbBr5 | MoBr2 MoBr3 MoBr4 | TcBr4 | RuBr3 | RhBr3 | PdBr2 | AgBr | CdBr2 | InBr InBr3 | SnBr2 SnBr4 | SbBr3 +Sb -Sb | Te2Br TeBr4 +Te | IBr IBr3 | XeBr2 | ||||
| CsBr | BaBr2 | * | LuBr3 | HfBr4 | TaBr5 | WBr5 WBr6 | ReBr3 | OsBr3 OsBr4 | IrBr3 IrBr 4 | PtBr2 PtBr4 | AuBr AuBr3 | Hg2Br2 HgBr2 | TlBr | PbBr2 | BiBr3 | PoBr2 PoBr4 | AtBr | Rn | |||
| FrBr | RaBr2 | ** | Lr | Rf | Db | Sg | Bh | Hs | Mt | Ds | Rg | Cn | Nh | Fl | Mc | Lv | Ts | Og | |||
| * | LaBr3 | CeBr3 | PrBr3 | NdBr2 NdBr3 | PmBr3 | SmBr2 SmBr3 | EuBr2 EuBr3 | GdBr3 | TbBr3 | DyBr3 | HoBr3 | ErBr3 | TmBr2 TmBr3 | YbBr2 YbBr3 | |||||||
| ** | AcBr3 | ThBr4 | PaBr4 PaBr5 | UBr4 UBr5 | NpBr3 NpBr4 | PuBr3 | AmBr2 AmBr3 | CmBr3 | BkBr3 | CfBr3 | EsBr2 EsBr3 | Fm | Md | No | |||||||
