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On the role of alkali metals in ammonia synthesis
Applied Elsevier
Catalysis, 18 (1985) 405-408 Science Publishers B.V., Amsterdam
ON THE ROLE OF ALKALI
H. BOSCH,
of Chemical
7500 AE Enschede,
(Received
Bowker
et al. [I] recently
potential
diagram
adsorption
ward the necessity This
rates of ammonia
of nitrogen,
hydrogen
P.O. Box 217,
be raised.
kinetics
based on the
[21. Agreement
that, under
with
known
these conditions,
and, therefore,
the potential
In their concluding
their calculations
draws attention
at industrially
of detailed
and ammonia,
of nitrogen
by assuming
of quantifying
synthesis
They used a compilation
for low coverage
remarks
the
well for
they put for-
for iron catalysts
containing
to the role of K in the mechanism
of the
reaction. communication
measurements
K-contents
from this laboratory,
for the N2+H2 reaction
ranging
Fe catalysts
Altenburg
over doubly
from 0.55 to 3.8 wt%. We showed
from 620 to 720 K and at pressures promoted
of Technology,
1985).
predicted
should
(again)
In a previous
with
University
of N2 is activated
N and H atoms
potassium.
17 June
could only be achieved
dissociative adsorbed
Twente
and pressures.
and desorption
energy
activities
SYNTHESIS
The Netherlands.
temperatures
of adsorption
in The Netherlands
GELLINGS
P.J.
Technology,
8 May 1985, accepted
relevant
synthesis
IN AMMONIA
J.G. VAN OMMEN and
Department
kinetic
METALS
405 -Printed
et al. [3] reported
promoted
commercial
that in a temperature
from 0.5 to 20 MPa the reaction
can be expressed
catalysts
as
(1)
r = k.f
where
range
rate of doubly
k = reaction
rate constant
fi = fugacity w = order
of species
i
in hydrogen
a = constant K = equilibrium
constant
of synthesis
a and W were found to be a function function
of temperature
for all the catalyst For catalysts
only. This rate equation
formulations
0166-9834/85/$03.30
increased
formulation was found
only, whereas
k was a
to give the best fit
examined.
with a very low K-content
0.5 and this order
reaction
of catalyst
with
0 1985 Elsevier
the order
increasing
Science
Publishers
in hydrogen
K-content. B.V.
was found to be
On a catalyst
with
’
406 optimum
formulation
it was found
from the hydrogenation surface,
assuming
determining
the chemisorption
the resulting
equilibrium
order
(NH2)a + 0.5
derivation
formation species. alumina
orders
results,
state,
o = vacancy):
amount
we concluded
the steps
Altenburg
whereas
higher
to form H-bridges,
et al. gave a full
them
N species
in catalysts with
higher
was thought
cristallites.
the presence
catalysts
hand,
Recently,
for the formation
of (N), and (NH), species
ESCA pictures
was hydrogenated
by hydroxyl
species.
from that used of (NH), and
in ammonia
(NH2)a groups
for the mechanism mentioned
experimental to the quite
their different
same molar A singly an aqueous
results
our commercial always
revealed could
Although
by hydroxylic
species
this system
of the ammonia
evidence
in our opinion
formation
and speci-
above. discussed
above
and to discuss
it is now relevant
some recent which
influences
the nature
of OH-groups,
charge/radius
that N chemisorbed
this spectroscopic
hypothesis
influence
in which
synthesis,
speculative
of potassium
of the IA group would
was prepared
to reduce
with
2+ amounts of Fe . Also, the presence of OH-groups
In the light of recent developments
the presence
(N), in
on pure iron
of our samples
spectroscopy
implications
may contribute
(apparent
hydrogenated
of mainly
by electron
for the hypothesis
some additional
potassium
by the alkaline
Ertl [4] was able to detect
et al. [51 showed
surface
different
has important
through
either.
Roberts
on a Zn(0001)
At higher
of predominantly
it was not possible
completely;
of considerable
not be confirmed
of (N), species
of (N), to (NH),
nor the presence
Among others,
the presence
On the other
promoted
(NH), and (N),
that
to be changed
for conversion
the rapid
(order = 0.5).
low K-content,
K-content.
UHV conditions
favour
but only at low K-contents.
less effective
with
would
favpur
by the speculation
we were not able to prove the presence
catalysts
would
role in the hydrogenation
of these OH-groups
of K, making
K-contents
these findings
in H'= 1) or even to (NH2)a
ESCA under
that a low K-content
play an important
the nature
is quite
to 1.5. Analogously
+ 0
to explain
OH-groups
However,
If
on the
of N2 to be the rate
(a = adsorbed
of 1 and 0.5 respectively.
of (NH2)a species, We tried
their ability
fically
species
of the equations.
From these
triply
dissociation
established
in H2 would
H2 = NH3
lead to apparent
nature
can be derived
t 1 H2 = NH3 + o
(NH),
order
and/or
orders
N-containing
+ 1.5 He = NH3 + o,
(N),
loads,
of the predominant
step.
Were the following
and
to be 1.5. These apparent
equilibria
those OH-groups
ratio z/r. To test this
the K was replaced
we previously
in a different
by other
the other
1A elements
which
put forward.
way because
idea, a series
group
to add
observations
elements of
of catalysts but with
the
percentages. promoted solution
catalyst of 2 molar
(3 wt% A1203) Fe(N03)3
was prepared
and 0.1 molar
by coprecipitation
Al(N03)3
with ammonia.
from This
407
FIGURE
1
The activity
function culated
from equation
constant reference
singly
solution,
and the fraction
The activity commercial
Thus, the catalyst
activity
method,
k_ = reaction
rate constant
3 wt% A1203.0impregnated
of alkali
0.3-0.6
carbonate,
were calrate
of the
from a
was pressed,
mm was used for activity are described
precipitation
one reported
is governed
mainly
in which
the potassium
by its chemical
with the findings
with the
stage of the
was added
composition,
of Dmitrenko
cata-
[3].
was comparable
no matter
this work)
crushed
measurements,
previously
catalysts
previously,
(KOH, K2C03,
in agreement
and in the case of potassium
at 110°C the product
measurements
form
at IO MPa and 673 K as a rate constants
from a KOH solution.
of the K-containing
or in which
the preparation
with
in a solution
promoted
Reaction
a = 0.5 and w = 1.5. kAM = reaction
of KOH. After drying
with diameter
doubly
preparation,
catalyst
and activity
iron catalysts
metal.
catalysts,
@impregnated
was suspended
lyst reduction
promoted
promoted
also in a solution
promoted
of the alkali
1 with the values
of the doubly
carbonate
product
of alkali
of charge/radius
[31.
not by
[63 for molten
iron catalysts. The activity
of the promoted
one, the results the influence
of the alkali
is in agreement
catalysts
of these measurements additives
with the mechanism
motor may influence
the surface
formation
of NH and/or
H-bridges
between
of the alkali
hydroxide.
on the oxygen
atom
decreases
proposed
already
that of the unpromoted 1. It can be seen that
z/r of the alkali
OH group
metal.
This
, which is based on how the pro-
prevented, present
At high z/r ratios,
in the surface
with
earlier
with
in Figure
If z/r of the alkali metal
OH-groups.
NH2 is apparently
the OH-groups
was compared
being given
possibly
is small the
by the formation
on the surface
as for Li and Na, the electron
is lower,
of
and hydroxyl-groups
so that H-bridge
density
formation
will
408 be less favourable. thus decreasing constants doubly
This means
the promotor
in Figure
promoted
1 are calculated
catalysts.
is best described
that N-H (and/or
effect.
For reasons with
formation
of comparison
behaviour
can take place,
the reaction
the value of w = 1.5 which
In fact, the kinetic
by equation
NH2) group
of Li-containing
1 with the value w = 0.5, typical
rate
applies
of singly
to
catalysts promoted
catalysts. We agree with behaviour surface function
the idea of Bowker
of commercial
techniques
catalysts,
in order
of catalyst
et al. [I] of paying but we also suggest
to study the degree
more attention
the application
of hydrogenation
to the of modern
of N-species
as a
formulation.
REFERENCES M. Bowker, I.B. Parker and K.C. Waugh, Applied Catalysis, 14 (1985) 101. Vol. 4, J.R. Anderson and M. G. Ertl, "Catalysis, Science and Technology", Boudart (Editors), Springer Verlag, Berlin, 1983, p.273. K. Altenburg, H. Bosch, J.G. van Ommen and P.J. Gellings, J. Catal., 66 (1980) 326. G. Ertl and N. Thiele, Appl. Surface Sci., 3 (1979) 99. C.T. Au, M.W. Roberts and A.R. Zhu, Chem. Comm., (1984) 737. L.M. Dmitrenko, L.D. Kuznetsov, P.D. Rabina, T.Ja.Malisheva, M.M. Ivanov, Sh. Sh. Mischenko and V.S. Sobolevski, Proc. 4th Int. Cong. on Catal., Moscow, 1968, vol.1 (1968) 404.
Catalysis, 18 (1985) 405-408 Science Publishers B.V., Amsterdam
ON THE ROLE OF ALKALI
H. BOSCH,
of Chemical
7500 AE Enschede,
(Received
Bowker
et al. [I] recently
potential
diagram
adsorption
ward the necessity This
rates of ammonia
of nitrogen,
hydrogen
P.O. Box 217,
be raised.
kinetics
based on the
[21. Agreement
that, under
with
known
these conditions,
and, therefore,
the potential
In their concluding
their calculations
draws attention
at industrially
of detailed
and ammonia,
of nitrogen
by assuming
of quantifying
synthesis
They used a compilation
for low coverage
remarks
the
well for
they put for-
for iron catalysts
containing
to the role of K in the mechanism
of the
reaction. communication
measurements
K-contents
from this laboratory,
for the N2+H2 reaction
ranging
Fe catalysts
Altenburg
over doubly
from 0.55 to 3.8 wt%. We showed
from 620 to 720 K and at pressures promoted
of Technology,
1985).
predicted
should
(again)
In a previous
with
University
of N2 is activated
N and H atoms
potassium.
17 June
could only be achieved
dissociative adsorbed
Twente
and pressures.
and desorption
energy
activities
SYNTHESIS
The Netherlands.
temperatures
of adsorption
in The Netherlands
GELLINGS
P.J.
Technology,
8 May 1985, accepted
relevant
synthesis
IN AMMONIA
J.G. VAN OMMEN and
Department
kinetic
METALS
405 -Printed
et al. [3] reported
promoted
commercial
that in a temperature
from 0.5 to 20 MPa the reaction
can be expressed
catalysts
as
(1)
r = k.f
where
range
rate of doubly
k = reaction
rate constant
fi = fugacity w = order
of species
i
in hydrogen
a = constant K = equilibrium
constant
of synthesis
a and W were found to be a function function
of temperature
for all the catalyst For catalysts
only. This rate equation
formulations
0166-9834/85/$03.30
increased
formulation was found
only, whereas
k was a
to give the best fit
examined.
with a very low K-content
0.5 and this order
reaction
of catalyst
with
0 1985 Elsevier
the order
increasing
Science
Publishers
in hydrogen
K-content. B.V.
was found to be
On a catalyst
with
’
406 optimum
formulation
it was found
from the hydrogenation surface,
assuming
determining
the chemisorption
the resulting
equilibrium
order
(NH2)a + 0.5
derivation
formation species. alumina
orders
results,
state,
o = vacancy):
amount
we concluded
the steps
Altenburg
whereas
higher
to form H-bridges,
et al. gave a full
them
N species
in catalysts with
higher
was thought
cristallites.
the presence
catalysts
hand,
Recently,
for the formation
of (N), and (NH), species
ESCA pictures
was hydrogenated
by hydroxyl
species.
from that used of (NH), and
in ammonia
(NH2)a groups
for the mechanism mentioned
experimental to the quite
their different
same molar A singly an aqueous
results
our commercial always
revealed could
Although
by hydroxylic
species
this system
of the ammonia
evidence
in our opinion
formation
and speci-
above. discussed
above
and to discuss
it is now relevant
some recent which
influences
the nature
of OH-groups,
charge/radius
that N chemisorbed
this spectroscopic
hypothesis
influence
in which
synthesis,
speculative
of potassium
of the IA group would
was prepared
to reduce
with
2+ amounts of Fe . Also, the presence of OH-groups
In the light of recent developments
the presence
(N), in
on pure iron
of our samples
spectroscopy
implications
may contribute
(apparent
hydrogenated
of mainly
by electron
for the hypothesis
some additional
potassium
by the alkaline
Ertl [4] was able to detect
et al. [51 showed
surface
different
has important
through
either.
Roberts
on a Zn(0001)
At higher
of predominantly
it was not possible
completely;
of considerable
not be confirmed
of (N), species
of (N), to (NH),
nor the presence
Among others,
the presence
On the other
promoted
(NH), and (N),
that
to be changed
for conversion
the rapid
(order = 0.5).
low K-content,
K-content.
UHV conditions
favour
but only at low K-contents.
less effective
with
would
favpur
by the speculation
we were not able to prove the presence
catalysts
would
role in the hydrogenation
of these OH-groups
of K, making
K-contents
these findings
in H'= 1) or even to (NH2)a
ESCA under
that a low K-content
play an important
the nature
is quite
to 1.5. Analogously
+ 0
to explain
OH-groups
However,
If
on the
of N2 to be the rate
(a = adsorbed
of 1 and 0.5 respectively.
of (NH2)a species, We tried
their ability
fically
species
of the equations.
From these
triply
dissociation
established
in H2 would
H2 = NH3
lead to apparent
nature
can be derived
t 1 H2 = NH3 + o
(NH),
order
and/or
orders
N-containing
+ 1.5 He = NH3 + o,
(N),
loads,
of the predominant
step.
Were the following
and
to be 1.5. These apparent
equilibria
those OH-groups
ratio z/r. To test this
the K was replaced
we previously
in a different
by other
the other
1A elements
which
put forward.
way because
idea, a series
group
to add
observations
elements of
of catalysts but with
the
percentages. promoted solution
catalyst of 2 molar
(3 wt% A1203) Fe(N03)3
was prepared
and 0.1 molar
by coprecipitation
Al(N03)3
with ammonia.
from This
407
FIGURE
1
The activity
function culated
from equation
constant reference
singly
solution,
and the fraction
The activity commercial
Thus, the catalyst
activity
method,
k_ = reaction
rate constant
3 wt% A1203.0impregnated
of alkali
0.3-0.6
carbonate,
were calrate
of the
from a
was pressed,
mm was used for activity are described
precipitation
one reported
is governed
mainly
in which
the potassium
by its chemical
with the findings
with the
stage of the
was added
composition,
of Dmitrenko
cata-
[3].
was comparable
no matter
this work)
crushed
measurements,
previously
catalysts
previously,
(KOH, K2C03,
in agreement
and in the case of potassium
at 110°C the product
measurements
form
at IO MPa and 673 K as a rate constants
from a KOH solution.
of the K-containing
or in which
the preparation
with
in a solution
promoted
Reaction
a = 0.5 and w = 1.5. kAM = reaction
of KOH. After drying
with diameter
doubly
preparation,
catalyst
and activity
iron catalysts
metal.
catalysts,
@impregnated
was suspended
lyst reduction
promoted
promoted
also in a solution
promoted
of the alkali
1 with the values
of the doubly
carbonate
product
of alkali
of charge/radius
[31.
not by
[63 for molten
iron catalysts. The activity
of the promoted
one, the results the influence
of the alkali
is in agreement
catalysts
of these measurements additives
with the mechanism
motor may influence
the surface
formation
of NH and/or
H-bridges
between
of the alkali
hydroxide.
on the oxygen
atom
decreases
proposed
already
that of the unpromoted 1. It can be seen that
z/r of the alkali
OH group
metal.
This
, which is based on how the pro-
prevented, present
At high z/r ratios,
in the surface
with
earlier
with
in Figure
If z/r of the alkali metal
OH-groups.
NH2 is apparently
the OH-groups
was compared
being given
possibly
is small the
by the formation
on the surface
as for Li and Na, the electron
is lower,
of
and hydroxyl-groups
so that H-bridge
density
formation
will
408 be less favourable. thus decreasing constants doubly
This means
the promotor
in Figure
promoted
1 are calculated
catalysts.
is best described
that N-H (and/or
effect.
For reasons with
formation
of comparison
behaviour
can take place,
the reaction
the value of w = 1.5 which
In fact, the kinetic
by equation
NH2) group
of Li-containing
1 with the value w = 0.5, typical
rate
applies
of singly
to
catalysts promoted
catalysts. We agree with behaviour surface function
the idea of Bowker
of commercial
techniques
catalysts,
in order
of catalyst
et al. [I] of paying but we also suggest
to study the degree
more attention
the application
of hydrogenation
to the of modern
of N-species
as a
formulation.
REFERENCES M. Bowker, I.B. Parker and K.C. Waugh, Applied Catalysis, 14 (1985) 101. Vol. 4, J.R. Anderson and M. G. Ertl, "Catalysis, Science and Technology", Boudart (Editors), Springer Verlag, Berlin, 1983, p.273. K. Altenburg, H. Bosch, J.G. van Ommen and P.J. Gellings, J. Catal., 66 (1980) 326. G. Ertl and N. Thiele, Appl. Surface Sci., 3 (1979) 99. C.T. Au, M.W. Roberts and A.R. Zhu, Chem. Comm., (1984) 737. L.M. Dmitrenko, L.D. Kuznetsov, P.D. Rabina, T.Ja.Malisheva, M.M. Ivanov, Sh. Sh. Mischenko and V.S. Sobolevski, Proc. 4th Int. Cong. on Catal., Moscow, 1968, vol.1 (1968) 404.