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Catalytic dehydrogenation of cyclohexane over Ag-M/ACCcatalysts for hydrogen supply

Jayshri V. Pande, Anshu Shukla, Rajesh B. Biniwale*

National Environmental Engineering Research Institute (NEERI), Council of Scientific and Industrial Research, Nagpur 440020, India

a r t i c l e i n f o

Article history:

Received 5 October 2011

Received in revised form

12 January 2012

Accepted 18 January 2012

Available online 14 February 2012

Keywords:

Dehydrogenation

Bimetallic catalyst

Cyclohexane

Pulse spray reactor

Hydrogen storage

* Corresponding author. Tel.: þ91(712) 224988E-mail address: rb_biniwale@neeri.res.in

0360-3199/$ e see front matter Copyright ªdoi:10.1016/j.ijhydene.2012.01.069

a b s t r a c t

Dehydrogenation of cyclohexane to benzene has been carried out over Ag supported on

activated carbon cloth (Ag/ACC) catalysts using a spray- pulse reactor. Hydrogen evolution

was studied for hydrogen storage and supply system applications. The maximum rate of

hydrogen evolution rate using monometallic Ag/ACC catalysts was 6.9 mmol/gmet/min for

Ag loading of 10 wt%. An enhanced hydrogen evolution was observed by adding a small

amount of noble metal (1 wt% Pt, Pd, Rh) to the Ag based catalysts. A synergistic effect was

observed in the case of the Pt promoted catalysts on the hydrogen production were twice as

compared to 10 wt% Ag catalyst only.

Copyright ª 2012, Hydrogen Energy Publications, LLC. Published by Elsevier Ltd. All rights

reserved.

1. Introduction A wide variety of monometallic and bimetallic catalysts

Hydrogen-based energy systems are being pursued widely

across many countries as cleaner energy options [1]. The

transporation of hydrogen from hydrogen production facility

and delivery to fueling station is one of the important chal-

lenges in case of implementation of hydrogen-based energy

[2]. Liquid organic hydrides such as cycloalkanes are highly

potential candidates for hydrogen storage and supply; it holds

high hydrogen content about 6e8% on weight basis and

60e65 kg/m3 on the volume basis at atmospheric temperature

and pressure. Furthermore, hydrogen can be easily stored and

extracted from the liquid organic hydrides using a catalytic

process [3]. Therefore, it is convenient to use cycloalkanes for

storage and supply of hydrogen. Further, the system does not

produce any by-products such as CO or CO2 [4].

5x410, þ91-9822745768(M(R.B. Biniwale).2012, Hydrogen Energy P

has been reported in literature for high selectivity towards

dehydrogenation of cycloalkane to extract hydrogen [5e9]. Pt

based catalysts have been reported by various researchers for

selective dehydrogenation of cycloalkanes and seasonal

storage of energy as hydrogen. Kobayashi and coworkers have

used an unsteady-state spray pulse mode reactor for dehy-

drogenation of 2-propanol on Pt/-Al2O3 [10]. Literature reports

indicate that bimetallic catalysts have profound role in cata-

lytic reactions and in enhancing activity as compared to

monometallic catalysts in many reactions. Activity of bime-

tallic catalyst is highly dependent on electronic effect, CeH

bond cleavage and hydrogen recombination ability of metal

[11]. Bimetallic catalysts containing a small amount of Pt have

been shown promise as potential cost-effective catalysts. In

such cases, the secondmetal acts as a promoter and enhances

obile); fax: þ91(712) 2249900.

ublications, LLC. Published by Elsevier Ltd. All rights reserved.

i n t e r n a t i o n a l j o u r n a l o f h y d r o g e n en e r g y 3 7 ( 2 0 1 2 ) 6 7 5 6e6 7 6 3 6757

the activity as also selectivity of the catalyst. Promoting effect

of second metal has been reported for Pt-M catalysts wherein

M ¼ W, Re, Rh, and Ir for dehydrogenation of cyclohexane. It

has beenwell reported by Kariya et al., that the increase in the

catalytic activity in terms of increased hydrogen evolution

rate may result due to the electronic effect of adjacent second

metal, which improves the CeH bond breaking ability,

stability of intermediate and desorption of aromatic product

[10]. Ichikawa and coworkers have reported the dehydroge-

nation of cyclic hydrocarbons over Pt and PteM (M ¼ Re, Rh,

Pd) catalysts supported on activated carbon under non steady

spray pulse reaction conditions [10,12].

From the economic point of view, we have a specific

interest to minimize the use of Pt or find the alternate catalyst

compositionwith improved or equal activity and selectivity as

that of Pt catalysts. In an attempt to reduce the amount of Pt,

we have earlier reported Ni/C catalyst and synergistic effect of

addition of Pt for dehydrogenation of cyclohexane [7].

Hodoshima et al. had reported Ni/C, Ru/C and NieRu/C cata-

lysts for dehydrogenation of tetralin for efficient hydrogen

supply [13].

It is evident from the above discussions that use of liquid

cycloalkane is a potential option for storage and supply of

hydrogen. Endothermic reaction of dehydrogenation of

cycloalkanes on solid catalysts is facilitated under unsteady-

state conditions. It has been reported that dehydrogenation

of cyclohexane by feeding liquid reactant in pulse, creating an

alternate wet-dry condition on the heated catalyst surface,

improves hydrogen evolution rates for the highly endo-

thermic dehydrogenation reaction [7]. Hodoshima et al. have

reported the use of a superheated liquid film reactor for

enhancing the hydrogen evolution during dehydrogenation of

decalin [14].

In the present study, we have reported relatively high

selectivity towards hydrogen during dehydrogenation of

cyclohexane over monometallic Ag/ACC (Ag supported on

activated carbon cloth) under spray pulse mode. Effect of

addition of a small amount of noble metal to the Ag based

catalysts was also studied. It has been reported that, presence

of the group Ib (group 11) metals (Ag, Au, Cu) decreases the

extent of hydrogenolysis in alkane isomerisation reaction [15].

This effect of group Ib metals is due to their property of not

promoting CeC bond cleavage. The bimetallic catalysts re-

ported in this study include Ag-M/ACCwhereinM¼ Pt, Pd and

Rh. The catalysts were characterized using XRD, SEM and XPS.

2. Experimental

2.1. Catalyst preparation

Activated Carbon Cloth (ACC) with surface area of 800 m2/g

was used as support for loadingmetal catalysts. Monometallic

Ag catalysts used in the present study were 5, 10 and 15 wt%

Ag/ACC. The Ag loading was achieved by adsorption method

using solution of AgNO3 in acetone. Activated carbon cloth

was stirred with stoichiometric amount of AgNO3 corre-

sponding to Ag content of ca. 5, 10 and 15 wt% and subse-

quently dried in an oven at 100 �C. Bimetallic catalysts, Ag-M/

ACC with second metal were synthesized by wet-

impregnation method for loading of 1 wt% of Pt, Pd and Rh

over Ag/ACC base catalyst with subsequent drying at 100 �C.

2.2. Characterization of catalysts

The catalysts were characterized using XRD, SEM and XPS

after reduction under the hydrogen atmosphere. X-ray

diffraction patterns for various catalysts in this study were

obtained using Rigaku Miniflex II, Dekstop X-ray Diffractom-

eter with Cu Ka radiation (l ¼ 1.5405). The oxidation state of

surface metal was identified by X-ray photoelectron spec-

troscopy technique (XPS). The XPS analysis of all mono-

metallic and bimetallic catalysts were carried out before and

after the reaction. XPS measurements were performed on

a Vacuum Generator Microtech photoelectron spectropho-

tometer (model ESCA 3000) by using monochromatized MgKa

radiation (l ¼ 1253.6). The pressure of the XPS analysis

chamber during the measurement was >1 � 10�9 Pa. All the

spectra were corrected by subtracting a Shirley type back-

ground. Binding energies were corrected with respect to C1s

binding energy of 285 eV.

2.3. Catalytic Reaction

Dehydrogenation reaction was carried out in a stainless steel

reactor with a spray pulse mode injection of the cyclohexane

feed. The average feed rate of cyclohexane was 2.4mmol/min.

The details of experimental setup are reported in an earlier

article [9]. Catalyst was pre-treated in nitrogen flow at 300 �C.The catalyst was activated in flow of nitrogen (100 ml/min)

and hydrogen (50ml/min) following a specific heating cycle up

to 400 �C. Hydrogen evolution rate was studied by monitoring

the concentration of outlet gas. Analysis of hydrocarbons

(benzene and unreacted cyclohexane) in condensed product

was carried out by GC-FID (Shimadzu GC-2014). Hydrogen

concentration in product gas was monitored using GC-TCD

(Shimadzu GC- 2014). The packed column (porapack-Q) was

used in GC-TCD for hydrogen separation from sweep gas N2.

3. Result and discussion

3.1. Catalyst characterization

Fig. 1 depicts XRD patterns for the monometallic and bime-

tallic catalysts. The peaks in XRD pattern can be attributed to

metallic silver particles, which was confirmed by JCPDS card

no. 89-3722. This confirms the crystalline phase of Ag. The size

of the metal particles was derived from the Debye- Scherer’s

formula. The estimated size of Ag was in the range of

8e10 nm. In case of the promoted catalyst, XRD pattern did

not show any additional peak than peaks for Ag. This may be

due to relatively lower concentration of the second metal,

however, shift in the peak position was observed. All the

peaks were attributed to silver.

SEMmicrograph of Ag/ACC given in Fig. 2 revealed that the

Ag particles were well dispersed on the carbon fibres.

However, agglomerates were also observed.

The survey analysis of the catalyst during XPS confirms the

presence of various elements present on carbon cloth. The

Fig. 1 e XRD patterns for monometallic and bimetallic

catalysts (a) Ag/ACC (b) AgePt/ACC (c) AgePd/ACC (d)

AgeRh/ACC.

i n t e rn a t i o n a l j o u r n a l o f h y d r o g e n en e r g y 3 7 ( 2 0 1 2 ) 6 7 5 6e6 7 6 36758

binding energy values of XPS spectra for all monometallic and

bimetallic catalysts for both reduced and after exposure to

cyclohexane (after reaction) are reported in Table 1. XPS

analysis of reduced sample of Ag/ACC catalyst confirms that

metal present on the support was in zero valent state. Fig. 3

represent XPS spectrum for Ag catalyst before and after

exposure to cyclohexane. In case of fresh catalyst, peak was

observed for the binding energy of Ag 3d5/2 and Ag 3d3/2 was at

about 368 eV and 374 eV, which confirms the presence of Ag in

zero oxidation state [16]. The peaks for 10 wt% Ag/ACC cata-

lysts after exposure to cyclohexane were observed at binding

energy of 370 eV and 376 eV. Shift in the peak position was

attributed to the change in the oxidation state of catalyst over

the support from metallic silver to Agþ1 [17,18]. Monometallic

Pt catalysts exhibit a single peak at 74.5 eV, which shifted to

75.1 eV after the reaction. This indicates that platinum was

Fig. 2 e SEM image of 10 wt% Ag/ACC catalyst.

fully reduced to metallic state after treatment at 400 �C in

hydrogen flow. Wherein, after the reaction shift at higher

binding energy assigned to change in the oxidation state [19].

Similarly, XPS spectrum of all bimetallic catalysts reduced

under hydrogen flow corresponds to zero valent state of

metal. Binding energy values of 10 wt% Ag-1 wt% Pd/ACC

catalysts were observed to be 368.6 eV, 374.5 eV and 335.2 eV

corresponding to Ag 3d5/2, Ag 3d3/2 and Pd 3d respectively. For

10 wt% Ag-1 wt% Rh/ACC catalyst binding energies were

368.4 eV, 374.4 eV and 306.6 eV corresponding to Ag 3d5/2, Ag

3d3/2 and Rh 3d5/2 respectively. All these values represent zero

valent state of metals [8,20]. XPS spectrum of reduced 10 wt%

Ag -1wt% Pt/ACC catalyst also indicates zero valent state of Ag

& Pt. After reaction, in the case of 10 wt% Ag-1 wt % Pd/AACC

catalyst the binding energy of Ag was almost same as reduced

catalysts but the binding energy of Pd was shifted towards

higher value reveals change in oxidation state of Pd. This

result is in good agreement with the experimental data.

Hydrogen abstraction was carried out on Ag sites, addition of

palladium improved the stability of the catalysts and had no

considerable effect on dehydrogenation activity. Peaks ob-

tained fromXPS analysis of 10wt%Ag-1wt%Rh/ACC catalysts

showed the shift towards higher binding energy than the

reduced catalyst indicating the change in the oxidation state.

Binding energy values of 10 wt% Ag-1 wt% Pt/ACC catalyst

remained unchanged even after exposure to cyclohexane.

This indicates that the addition of platinum facilitates the

stabilization of Ag-Pt catalyst.

3.2. Influence of catalyst metal content on hydrogenevolution rate

The hydrogen evolution rate during dehydrogenation of

cyclohexane over monometallic Ag catalysts at 300 �C and

with cyclohexane feed rate of 2.4 mmol/min (pulse injection

frequency of 0.33 Hz and pulse width of 10 ms), are shown in

Fig. 4. The loading of Ag was varied as 5, 10 and 15 wt% on

activated carbon cloth. The reactions were carried out as

described in experimental section. The product gas was

monitored using TCD GC with a run time of about 3 min. The

concentration of hydrogen monitored was not the instanta-

neous value after pulse injection. Rather the prevailing bulk

concentration of hydrogen under the flow of nitrogen (as

sweep gas) and pulse injection of cyclohexane was observed.

The cyclic behaviour of the hydrogen concentration data is

due to the variation in bulk concentration under these

conditions. Therefore, the time interval for cyclic behaviour of

hydrogen concentration observed was different from the

pulse injection interval. With the change in the Ag loading,

there is a considerable change in hydrogen evolution rates.

Hydrogen evolution rate for 5 wt% Ag/ACC was observed to be

3.4mol/gmet/min and for 10wt%Ag/ACC 6.9mmol/gmet/min at

30 min. The maximum conversion and hydrogen evolution

rate was observed for 10 wt% Ag/ACC catalyst at 300 �C. It was

observed that hydrogen evolution rate increases with the

increase in metal loading. On the contrast, further increase in

the metal loading to 15 wt% Ag/ACC catalytic activity

decreases to 2.85 mol/gmet/min. At higher Ag loading catalysts

activity was relatively lower may be because of the lower

dispersion of the catalysts [9]. The optimal loading of Ag for

Table 1 e Binding energy values of fresh and used samples characterized by XPS.

Element Reported values Observed values Reference

Zero valentmetal

Higher oxidationstate

Before reaction(reduced)

After reaction(used)

Ag 368.3 370 368.0 370 [15e17]

374.5 376 374.0 376

Pt 70.6 73.1 70.7 71.6 [18]

73.9 76.4 74.5 75.1

AgePt

Ag 368.3 370 368.5 368.5 [15e17]

374.5 376 374.6 374.6

Pt 70.6 73.1 71.4 71.3 [18]

73.9 76.4 74.5 73.7

AgePd

Ag 368.3 370 368.6 368.5 [15e17]

374.5 376 374.5 374.4

Pd 335.2 337 335.3 345.4 [7]

AgeRh

Ag 368.3 370 368.7 367.4 [15e17]

374.5 376 374.5 373.4

Rh 306.6 309 306.8 307.3 [19]

i n t e r n a t i o n a l j o u r n a l o f h y d r o g e n en e r g y 3 7 ( 2 0 1 2 ) 6 7 5 6e6 7 6 3 6759

dehydrogenation of cyclohexane was therefore considered as

10 wt%. This was also confirmed by calculating average crys-

talline size (estimated from XRD data) of Ag as 3.01 and 3.8 nm

for 10 wt% Ag/ACC and 15 wt% Ag/ACC respectively.

In case of monometallic Ag/ACC catalyst, the reaction

products contained benzene and hydrogen. There were no

partial dehydrogenation (cyclohexene) or hydrogenolysis

products (such as CH4) observed. Therefore, the selectivity

towards the hydrogen formation was nearly 100%.

The temperaturesmentioned in thismanuscript are the set

temperatures for the heater. Whereas, the catalyst surface

temperature may vary under the spray pulse feed conditions.

The variations in the surface temperature have been reported

in our previous article regarding thermal profile of the catalyst

surface [6]. Actual surface temperature of the catalyst may be

lower by 50e75 �C approximately under the wet condition

during spray injection of cyclohexane.

3.3. Influence of reaction temperature under the spraypulsed condition on the hydrogen evolution rate

Reaction has been carried out over three different tempera-

tures viz. 250, 300 and 350 �C. The hydrogen evolution rates

with respect to temperature for dehydrogenation of cyclo-

hexane over 10 wt% Ag/ACC catalyst have been observed as

depicted in Fig. 5. The reactant feed has been kept constant,

with injection frequency of 0.33 Hz and pulse width of 10 ms.

The average rate of hydrogen evolution at 250 �Cwas found

to be 2.3 mmol/gmet/min. With increase in the temperature to

300 �C the average rate of hydrogen evolution was 6.8 mmol/

gmet/min. It was about three times higher than rate of

hydrogen production at 250 �C. With further increase in the

temperature to 350 �C, the average hydrogen evolution rate

decreased to 4.4 mol/gmet/min. At the set temperature of

250 �C rate of hydrogen evolution was relatively lower due to

decrease in the catalyst surface temperature. This resulted in

decreasing the dehydrogenation rate. The dehydrogenation of

cyclohexane is a highly endothermic reaction and is therefore

favoured at higher temperatures [21]. The temperature of the

catalyst surface plays an important role in order to maintain

close contact of reactant and catalysts surface. However, as

the temperature increases residence time of the reactant on

the catalyst surface decreases, which is unfavourable in the

dehydrogenation reaction [4].

The optimum temperature of 300 �C facilitates the proper

reactant-catalyst contact and provides the required energy for

endothermic dehydrogenation reaction. At this temperature

hydrogen and aromatics are removed rapidly from the cata-

lyst surface during the dry conditions (interval between pulse

injections). Clean and regenerated catalyst surface is there-

fore available for further reaction, which suppress the reverse

reaction and results in the high hydrogen evolution rate [21].

The reactant after injection as an atomized spray for

a controlled period (pulse width) reaches the catalyst surface

and evaporates on the heated catalyst surface. This forms the

dense vapor phase in the vicinity to the catalysts surface

facilitating better contact between reactant and catalysts.

3.4. Effect of addition of second metal

We have studied the interaction of AgePt, AgePd and AgeRh

on dehydrogenation of cyclohexane for hydrogen evolution

rates. Bimetallic catalysts exhibited higher activity in terms of

increased hydrogen evolution rates. Furthermore, bimetallic

catalysts exhibited higher stability and yield in comparison to

the monometallic catalysts. The improved catalytic activity

was observed for Ag catalysts promoted by addition of 1 wt%

Pt, Pd and Rh as shown in Fig. 6. Addition of a second metal to

Ag, improved the hydrogen evolution due to synergistic effect

of second metal for CeH bond cleavage, high hydrogen-

reverse-spill over or the hydrogen-recombination [22e24]

abilities of the catalysts.

The reactions were carried out under a spray- pulsed

injection of feed. The fluctuating hydrogen evolution rate was

0

2000

4000

6000

8000

10000

12000

0 400 800 1200

B.E. (eV)

Inte

nsity

(a.u

.)

8000

12000

16000

20000

364 366 368 370 372 374 376 378 380

i

ii

B.E. (eV)

Inte

nsity

(a.u

.)

a

b

Fig. 3 e XPS spectrum of (a) 10 wt % Ag/ACC fresh catalyst

for survey analysis, (b) Comparison of 10 wt % Ag/ACC (i)

fresh (ii) used catalysts.

0

1

2

3

4

5

6

7

8

0 20 40 60 80 100 120

H2 e

vo

lu

tio

n r

ate (m

mo

l/g

met/m

in

)

Time (min)

(a)

(b)

(c)

Fig. 4 e Effect of metal content on hydrogen evolution rate

at 300 �C over (a) 5 wt % Ag/ACC (b) 10 wt % Ag/ACC and (c)

15 wt % Ag/ACC catalysts.

0

1

2

3

4

5

6

7

8

0 20 40 60 80 100 120

H2

evo

lu

tio

n ra

te

(m

mo

ls

/g

me

t/m

in

)

(b)

(c)

(a)

Time (min)

Fig. 5 e Effect of temperature on hydrogen evolution rates

over 10 wt % Ag/ACC catalyst (a) 250 �C (b) 300 �C and (c)

350 �C.

i n t e rn a t i o n a l j o u r n a l o f h y d r o g e n en e r g y 3 7 ( 2 0 1 2 ) 6 7 5 6e6 7 6 36760

observed for monometallic catalysts, wherein the activity was

relatively lower. In case of bimetallic catalysts activity was

relatively higher in terms of hydrogen evolution rates the

product gas has a more homogenous concentration of

hydrogen. The activity of bimetallic catalysts was higher in

terms of the hydrogen evolution rate as compare to mono-

metallic 10 wt% Ag/ACC. The highest catalytic activity was

observed for 10 wt% Ag þ 1 wt% Pt/ACC catalyst with

hydrogen evolution rate of 14.2 mol/gmet/min. In case of 10 wt

% Ag/ACCmonometallic catalyst hydrogen evolution rate was

varying in the range of 6.8 to 2.5 mol/gmet/min. Hydrogen

evolution rate was constant at about 14.2 mmols/gmet/min for

bimetallic catalysts. The improved activity of bimetallic

catalyst may be attributed to the higher hydrogen recombi-

nation ability of Pt. As it is reported by Kariya et al., that the

promotion of activity may be due to the electronic effect of

adjacent second metal, which improves the CeH bond

breaking ability of Pt [12]. Leiske et al., reported that the

electronically modified platinum crystal does not adsorb coke

precursors on its surface [25]. These results signify that 10wt%

Ag-1 wt% Pt/ACC catalyst show higher activity than mono-

metallic Ag/ACC, and among all bimetallic Ag-M/ACC catalyst

selected for dehydrogenation of cyclohexane at 300 �C.The improvement in the catalytic activity of Ag-M/ACC as

compared to Ag/ACC catalysts was observed to be dependent

on the promoter metal selected. The improvement in the

activity by addition of 1 wt% of promoters has been found in

the following order;

Pt > Rh > Pd

While, for improving the stability of Ag based catalysts the

addition of noblemetal promoters has been found in the order

of as;

Pt > Pd > Rh

0

2

4

6

8

10

12

14

16

0 20 40 60 80 100 120

H2

evol

utio

n ra

te (m

mol

/gm

et/m

in)

Time (min)

(b)

(c)

(d)

(a)

Fig. 6 e Hydrogen evolution rate of cyclohexane over

monometallic and bimetallic catalysts at 300 �C (a) 10 wt %

Ag/ACC (b) 10 wt % Ag D 1 wt % Pt/ACC (c) 10 wt %

Ag D 1 wt % Pd/ACC and (d) 10 wt % Ag D 1 wt % Rh/ACC.

0

2

4

6

8

10

12

14

16

0 20 40 60 80 100 120

H2 e

vo

lu

tio

n (m

mo

l/g

me

t/m

in

)

Time (min)

Fig. 7 e Hydrogenevolution rates over (a) 10wt%Ag/ACC, (b)

1 wt % Pt/ACC and (c) 10 wt % AgD 1 wt % Pt/ACC at 300 �C.

0

2

4

6

8

10

12

14

16

0 20 40 60 80 100

evol

utio

n ra

te (m

mol

/gm

et/m

in)

Time (min)

(a)

(b)

Fig. 8 e Hydrogen evolution rates over (a) 10 wt %

Ag D 1 wt % Pt/ACC and (b) 10 wt % Ag D 3 wt % Pt/ACC

catalysts at 300 �C.

i n t e r n a t i o n a l j o u r n a l o f h y d r o g e n en e r g y 3 7 ( 2 0 1 2 ) 6 7 5 6e6 7 6 3 6761

Hydrogen evolution rate for AgePd catalyst was ca.

7.5 mmol/gmet/min and it was stable up to 120 min. Kariya

et al., reported that Pd has a good hydrogen spillover ability

but has no activity for dehydrogenation of cycloalkanes.

Addition of Pd has no significant effect on the activity, but it

improves the stability of the catalyst [12]. The average crys-

talline size for Ag-M/ACC bimetallic catalyst was in the range

of 1.73e1.86 nm.

The yield of hydrogen production was calculated using

following equation (1):

%yield of H2 ¼ moles of H2 formedmoles of CH converted

� 100 (1)

The yield of hydrogen was calculated as 65% for 10 wt% Ag-

1 wt% Pt/ACC catalyst at 120 min. The hydrogen yield for 10

wt% Ag-1wt% Pd/ACC, 10 wt% Ag- 1 wt% Rh/ACC and 10 wt%

Ag/ACC catalyst at 120 min were calculate to be 41, 39 and

17.5% respectively. It is reported that bimetallic catalyst

exhibits a synergistic effect on the hydrogen evolution rate by

addition of a small amount of noble metal. Cyclohexane was

efficiently dehydrogenated over 10 wt% Ag/ACC, 1 wt% Pt/

ACC, 10 wt% Ag- 1 wt % Pt/ACC catalysts shown in Fig. 7.

Enhanced hydrogen evolution rate has been observed by

promoting Ag catalyst with 1 wt% Pt. The average hydrogen

evolution rate for 10 wt % Ag/ACC was about 6.9 mmol/gmet/

min whereas it was almost twice for 10 wt% Ag- 1 wt% Pt/

ACC catalyst at about 14.2 mmol/gmet/min. As compared to

1 wt% Pt catalyst AgePt bimetallic catalyst exhibit four times

higher hydrogen evolution rate. Using AgePt bimetallic

catalyst stability was also improved. When 10 wt% Ag-1wt%

Pt/ACC was tested for 300 min, the hydrogen evolution was

observed to be stable with nearly 14 mmol/gmet/min. The

hydrogen production rate decreased to 2.8 mmol/gmet/min as

the metal loading of Pt was increased from 1 wt% to 3 wt% as

shown in Fig. 8. In case of bimetallic catalyst 10 wt% Ag-1wt%

Pt/ACC the average particle size estimated by XRD was

6e10 nm and 15 nm for 10 wt% Ag-3 wt% Pt/ACC. The

relatively higher activity of 10 wt% Ag-1 wt% Pt/ACC catalysts

can be attributed to the smaller particle size and well

dispersed metal.

The Ag-M/ACC catalysts have been compared with NiePt

catalyst as reported earlier as detailed in Table 2 [6]. Ag-M/ACC

catalysts used in the present study exhibit the similar activity

in terms of hydrogen evolution rate as compared to NiePt

catalyst. However, no CH4 observed indicating only dehydro-

genation reaction was prevailing. The selectivity of the cata-

lyst for dehydrogenation of cyclohexane to hydrogen and

benzene was observed to be as high as 100%.

0

2

4

6

8

10

12

14

16

18

20

0 10 20 30 40 50 60

)nim/te

mg/lom

m( etar noitulove 2

H

Time(min)

(b)

(c)

(a)

Fig. 9 e Hydrogen evolution rate with variation in pulse

frequency over 10 wt% Ag-1 wt% Pt/ACC catalysts at

reaction temperature of 300 �C (a) interval of 1s and pulse

witdh of 10 ms (b) interval of 3s and pulse width of 10 ms

(c) interval of 5s and pulse width of 10 ms.

Table 2 e Hydrogen evolution rates reported for dehydrogenation of cyclohexane over various catalysts (Pt and otherbimetallic) using different reactor systems.

Sr no. Catalysts Temperature (�C) Highest hydrogenevolution (mmol/gmet/min)

Reactor System Ref.

Pt based catalysts

1. 5 wt % Pt/AC 82 0.034 Batch [10]

2. 3.82 wt% Pt/AC 300 1800 Batch [12]

3. 2 wt% Pt/Alumina 300 910 Batch [12]

4. 2 wt% Pt/Alumina 315 29 Flow system [12]

5. 10 wt% Pt/ACC 260 98 Flow system [12]

6. 10 wt% Pt/ACC 330 510 Flow system [12]

7. 11 wt% Pt-Re/ACC 328 550 Flow system [12]

8. 12 wt% Pt-Rh/ACC 331 520 Flow System [12]

9. 5 wt% Pt/AC 235 98 Spray-pulsed

system

[7]

10. 0.5 wt % Pt/ACC* 300 0.22 Spray-pulsed

system

[7]

11. 1 wt% Pt/ACC 300 2.49 e This study

Non Pt monometallic and Bimetallic with lower amount of Pt Catalysts

12. 10 wt% Ni/ACC 300 7.1 Spray-pulsed

system

[7]

13. 20 wt% Ni/ACC 300 8.5 Spray-pulsed

system

[7]

14. 20 wt% Ni �0.5 wt % Pt/ACC 300 13.1 Spray-pulsed

system

[7]

15. 10 wt% Ag/ACC 6.9 10 This study

16. 10 wt% Ag-1 wt% Pd/ACC 7.5 8 This study

17. 10 wt% Ag-1 wt% Rh/ACC 12.34 8 This study

18. 10 wt% Ag-1 wt% Pt/ACC 13.36 6 This study

i n t e rn a t i o n a l j o u r n a l o f h y d r o g e n en e r g y 3 7 ( 2 0 1 2 ) 6 7 5 6e6 7 6 36762

3.5. Influence of pulse frequency and pulse width forreactant feed over 10 wt% Ag-1 wt% Pt/ACC catalyst

As the rate of hydrogen production depends on the rate of

reactant feed, beyond the optimal rate of feeding, reactant

pool forms over the catalyst surface. This results in the

decrease of surface temperature and consequent decrease in

the hydrogen production rate [6]. Before the reaction start, the

catalyst surface is dry. The catalysts experience an alternate

wet-dry condition when the reactant strikes over the catalyst

surface through the nozzle in spray pulse injectionmode. This

alternate wet-dry condition is advantageous for the dehy-

drogenation reaction as it results in higher temperature of the

catalyst surface. Rapid desorption of the hydrogen and

aromatic product prevents the reverse reaction [21].

Fig. 9 depicts the influence of pulse injection frequency of

cyclohexane over the catalyst at 300 �C. The phenomenon of

variation in pulse width and pulse frequency is well explained

by Biniwale et al. [2]. The pulse width remained constant as

10ms and pulse frequency was varied from 0.5 s to 3 s. Shown

in Fig. 9 at 3s pulse frequency and 10 ms pulse width was an

optimal amount of cyclohexane feeding, at this point the

highest hydrogen evolution rate of 14.2 mmol/gmet/min was

observed. The highest hydrogen evolution rate for 5 s and 1 s

was observed to be 7.2 and 7.5 respectively.

The hydrogen production rate significantly depends on

frequency of reactant sprayed over the catalyst surface. At

lower pulse frequency (10 ms pulse frequency and 1 s pulse

width) a liquid rich conditionmay form over the surface of the

catalyst due to continuous spraying of reactant, which

decreases the hydrogen evolution rate. As liquid phase

reduces the surface temperature and inhibits desorption of

product and unreacted reactant. This would result in the

occurrence of reverse reaction and decline of the conversion

[20]. At higher pulse frequency (10 ms pulse frequency and 5 s

pulse width) reactant feeding was relatively small, and the

reactant would evaporate rapidly before reaching to the

catalyst surface. The residence time of the reactant over the

i n t e r n a t i o n a l j o u r n a l o f h y d r o g e n en e r g y 3 7 ( 2 0 1 2 ) 6 7 5 6e6 7 6 3 6763

catalyst surface would be too small to come in contact with

catalyst completely. Hence, hydrogen evolution rate

decreases at increased feed rate. Thus, 10 ms pulse frequency

and 3 s pulse width was observed to be optimum feeding rate

of reactant to strike on the catalyst surface.

4. Conclusions

Dehydrogenation of cyclohexane was successfully carried out

over Ag based catalysts. The addition of a second metal to Ag

catalysts has exhibited a synergistic effect resulting in rela-

tively higher hydrogen evolution rates. Particularly, 10 wt%

Ag-1 wt% Pt and 10 wt% Ag-1 wt% Rh supported on activated

carbon cloth are potential catalysts. The probable reason for

higher activity in bimetallic catalyst can be attributed to role

of noble metal such as platinum to maintain Ag in zero valent

state. Ag based catalystswith addition of 1 wt% of noblemetal

promoters are potential candidate for dehydrogenation of

cyclohexane.

Acknowledgement

This work was financially supported by Ministry of New and

Renewable Energy (MNRE), New Delhi. Senior Research

Fellowships awarded to Ms. Jayshri Pande and Ms. Anshu

Shukla by CSIR, New Delhi are gratefully acknowledged.

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