Nitric oxide introduction

Introduction to Iron
Nitrosyl Compounds
Dr. G.R. Navale,
IIT-Roorkee

Nitric Oxide I
 Nitric oxide (NO) is a colorless gas that is
thermodynamically unstable (DHf= 90.2 kJ/mol).
 Due its odd number of electrons, the compound is
paramagnetic. The unpaired electron is located in
a p*-orbital (HOMO orbital shown on the right)
 The molecule possesses a small dipole moment
(m=0.158 D) in which the nitrogen atom possesses
a partial negative charge (60 % spin density is
located on nitrogen based on EPR).
 The N-O bond length (115 pm) corresponds with a
bond order of about 2.5 (double bond: 118 pm, triple
bond: 106 pm).

Nitric Oxide II
 Nitric oxide is a by-product of combustion of substances in the air (i.e., car engines,
fossil fuel power plants). In both cases, it is quickly oxidized to form nitrogen
dioxide, which is removed using a catalytic converter.
 Nitric oxide is also produced naturally during the electrical discharge of lightning.
However, the direct reaction of nitrogen with oxygen requires temperatures in
excess of 2000 oC, which is not practical for a large-scale synthesis.
 Industrially, the oxidation of ammonia at 850 oC with platinum as catalyst leads
to the formation of nitric oxide.
 4 NH3 + 5 O2 4 NO + 6 H2O
 Nitric oxide can be oxidized to form the nitrosonium ion (NO+) or be reduced to
form a nitroside ion (NO-). The nitrosonium ion appears as the cation in nitrosyl
salts NO+X- (X=BF4
-, ClO4
-, AsF6
-, SbCl6
-, OsF6
-, HSO4
-, PtCl6
2-).
 Nitrosyl chloride is formed in a mixture of hydrochloric acid and nitric acid also
known as aqua regia.
 HNO3 + 3 HCl ClNO + Cl2 + 2 H2O

Metal Nitrosyl Complexes I
 Metal nitrosyl complexes, have gained significant interest in the
past twenty years because of the important role nitric oxide
displays as signaling molecule in biological systems.
 Louis Ignarro, a professor in the pharmacology department at
UCLA, received the Noble Prize in Physiology and Medicine in
1998 for his discovery about the signaling properties of nitric
oxide.
 Iron dithiocarbamates are used as model compounds for NO spin
trapping
 The first nitrosyl complex was discovered in 1790 by J. Priestley
([Fe(H2O)5(NO)]2+). This complex is also formed in the qualitative
test for nitrate with ferrous sulfate and sulfuric acid (“brown ring
test”).

Metal Nitrosyl Complexes II
 The second compound, an iron cyano complex ([Fe(CN)5(NO)]2-),
was described about 60 years later by K. L. Playfair.
• The dark-red sodium nitroprusside Na2[Fe(CN)5(NO)]*2 H2O)
is obtained from potassium ferrocyanide and concentrated nitric
acid
• It is a potent vasodilator (SNP, Nitropress).
• This compound is also used in Simon’s test in the detection of
methamphetamine (blue) and as reagent to detect sulfide ions
as [Fe(CN)5(NOS)]4-, which is purple.
 Roussin’s salts (red: K2[Fe2S2(NO)4], black: Na[Fe4S3(NO)7]) are
both iron sulfur nitrosyl complexes that were discovered in 1858.
 The esters of the Roussin’s Red salt are being investigated as nitric
oxide donors because photolysis of the compounds causes the
release of NO.

Metal Nitrosyl Complexes III
The nitric oxide donated by Roussin’s Black salt has
proven to be toxic to some melanoma cancer cells.
The same salt demonstrates antibacterial activity in
some food processing applications as well.
The structure of the red salt displays an edge-shared
bitetrahedron: four nitrosyl ligands are terminal and
two sulfide ligands are located in the bridge.
The black salt forms an incomplete cubane structure,
which is missing one corner (4 Fe and 3 S).

Metal Nitrosyl Complexes IV
 The nitrosyl ligand can act as a one-electron or a three-electron
donor.
 The nitrosyl cation (:N≡O:+) can use its lone pair on the nitrogen
atom to form a bond to the metal atom like its isoelectronic
counterparts the carbonyl (:C≡O:) and the cyanide (:C≡N:-).
 As carbonyl ligands, various degrees of p-back bonding are
observed (NO+ is a stronger p-acceptor than CO):

Metal Nitrosyl Complexes V
 Increasing strength of the p-back bond strengthens the M-N bond and weakens the
N-O bond.
 In extreme cases, both bonds can be characterized as double bonds (II). In cases in
which the M-N-O angle is close to 180o, the
M-N bond is usually relatively short.
 If the backbonding effect is weak, the angle decreases significantly (< (M-N-O)=
~120 o) and the ligand can be described as “NO-“ as
it is observed in the cobalt complexes below
 The Enemark-Feltham notation is used to describe the number of
d-type electrons present in a given metal nitrosyl complex. Complexes with "d+p*-
electrons" in excess of six often
tend to have bent NO ligands i.e., Co(NO)dtc2 (7 e,127o).


Metal Nitrosyl Complexes VI
 Examples
 Infrared spectroscopy and EPR spectroscopy can be used to distinguish between
different bond modes.
 Linear M-N-O groups (N-O triple bond) absorb in the range 1650–1900 cm−1 (i.e.,
[Fe(CN)5(NO)]2-: 1939 cm-1, [Mn(CN)5(NO)]3-:
1700 cm-1)
 Bent nitrosyl groups (N-O double bond) absorb in the range 1525–1690 cm−1 (i.e.,
[Co(NH3)5(NO)]2+: 1620 cm-1).
Compound (M-N-O) d(M-N) d(N-O)
[Fe(CN)5(NO)]2- 173.9o 164.3 pm 114.5 pm
[Mn(CN)5(NO)]3- 177.0o 165.1 pm 117.4 pm
[Co(NH3)5(NO)]2+ 119.0o 187.1 pm 115.4 pm
trans-[Co(en)2(NO)Cl]+ 124.4o 182.0 pm 104.3 pm
[Cr(CN)5(NO)]3- 176.0o 171.0 pm 121.1 pm
Ir(NO)(P(C6H5)3)3 180.0o 166.6 pm 124.4 pm

Experiment (Theory)
 In the lab, an iron nitrosyl complex will be synthesized by the
reaction of ferrous sulfate with nitrous acid in the presence of a
dithiocarbamate ligand.
 The reaction of the nitrite with sulfuric acid generates the nitrous acid
(HNO2) in-situ, which is reduced by Fe2+ to yield nitric oxide, which
reacts with the iron aquo complex to form [Fe(H2O)5(NO)]2+.
 The addition of the dithiocarbamate ion leads to the formation of the
dark-green Fe(NO)dtc2.
 In the second part, the product of the first reaction is reacted with
iodine to yield the brown FeI(NO)dtc2.
 The structures of both compounds are investigated using infrared
spectroscopy, EPR and NMR spectroscopy.

Experiment I
 Safety
• The first experiment has to be performed under
a well-ventilated hood because nitrogen dioxide (NO2) is
formed as a byproduct in this reaction.
• Chloroform is classified as selected carcinogen and should
only be handled in the hood.
• Petroleum ether is flammable. Keep away from any
ignition sources.

Experiment II
 Bis(diethyldithiocarbamato)nitrosyl iron (Fe(NO)dtc2)
• Ferrous sulfate (FeSO4* 7 H2O) and sodium nitrite (NaNO2) are dissolved
in 0.5 M sulfuric acid (student most likely has to prepare this solution).
• A aqueous solution of of sodium (N,N-diethyldithiocarbamate) (Na(S2CNEt2)*3 H2O) is
added immediately.
• The dark reaction mixture is stirred vigorously for 5 minutes before being transferred
into a separatory funnel (without the spin bar).
• The reaction mixture is extracted several times with chloroform (it could
be a difficult to see the phase separation here).
• The combined organic layers are dried over anhydrous magnesium sulfate before the
volume of the solution is reduced using the rotary evaporator.
• Petroleum ether is added to the solution to precipitate the dark green solid.
• If the solid does not crystallize at 0 oC, some of the chloroform is removed by careful
evaporation using the rotary evaporator (do not use heat here!).
• The crystals are isolated by filtration, are washed with petroleum ether and are dried in
vacuum.

Experiment III
 Bis(diethyldithiocarbamato)(iodo)nitrosyl iron
• Bis(diethyldithiocarbamato)nitrosyl iron is suspended in absolute
ethanol.
• A solution of iodine in absolute ethanol is added drop wise over a
period of 15 minutes.
• The resulting mixture is stirred for one hour at room temperature
during which a brown precipitate forms.
• The precipitate is removed by filtration, washed with
95 % ethanol and dried in vacuum.

Characterization I
Infrared spectroscopy
• Fe(NO)dtc2
 n(NO)=1685 cm-1
• FeI(NO)dtc2
 n(NO)=1805 cm-1
 Increased stretching frequency due to reduced p-backbonding due to the higher oxidation state
NMR spectroscopy
 FeI(NO)dtc2
• Complex multiplet at d=3.63 ppm (8 lines) and d=1.24 ppm (8 lines)

Characterization II
 Fe(NO)dtc2
• The nitrosyl group has an unpaired electron (<(Fe-
N-O)= 174o)
• The electron is located at the nitrogen atom and
therefore couples with the nucleus
(14N: 99.638% abundance, I=1)
• A three line spectrum is observed for this
compound (=2*1+1)
[G]
3390 3400 3410 3420 3430 3440 3450 3460
-3.5
-3.0
-2.5
-2.0
-1.5
-1.0
-0.5
0.0
0.5
1.0
1.5
2.0
2.5
3.0
3.5
[*10^ 3]

Nitric oxide introduction

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