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 CHEMICAL ENGINEERING TRANSACTIONS  
 

VOL. 50, 2016 

A publication of 

 
The Italian Association 

of Chemical Engineering 
Online at www.aidic.it/cet 

Guest Editors: Katharina Kohse-Höinghaus, Eliseo Ranzi
Copyright © 2016, AIDIC Servizi S.r.l., 
ISBN 978-88-95608-41-9; ISSN 2283-9216 

 Alkylation of Isopropanol with Ethanol over Heterogeneous 
Catalysts 

Polina A. Zharova*a, Andrey V. Chistyakova, Mark V. Tsodikova, Sergey A. 
Nikolaevb, Michele Corbettac, Flavio Manentic 
a
 A.V. Topchuev Institute of Petrochemical Synthesis, Leninskiy prospect, 29, Moscow, 119991, Russian Federation 

b
Lomonosov Moscow State University, GSP-1, 1-3 Leninskiye Gory, Moscow, 119991, , Russian Federation 

c
Politecnico di Milano, Dipartimento di Chimica,Piazza Leonardo da Vinci, 32, 20133 Milano, Italy 

zharova@ips.ac.ru  

The importance of synthesis of carbon-carbon bonds is reflected by the fact that Nobel Prizes in Chemistry 
have been given to this area: The Grignard reaction (1912), the Diels-Alder reaction (1950), the Witting 
reaction (1979), the olefin metathesis Y. Chauvin, R.H. Grubbs and R.R. Schrock (2005), the palladium-
catalyzed cross-coupling reactions to R. F. Heck, A. Suzuki, E. Negishi (2010). For the first time ever 
alkylation of isopropanol with ethanol was carried out over heterogeneous 0.2-1 wt.% Au and/or 0.02-0.3 wt. 
%Ni – containing catalysts without any sacrificial agents and/or presence of acidic/base additives. The catalyst 
containing 0.2 wt.% Au and 0.18 wt.% Ni supported on γ-Al2O3 was found to be the most selective in the 
cross-coupling route. Total selectivity of coupling products reached up to 70 %, conversion of the both initial 
alcohols was 50 %. Structural investigations of the Au, Ni – containing catalysts permitted to determine 
probable active sites peculiarities that provide effective one-pot alkylation of isopropanol with ethanol. 

1.  Introduction  

The development of bio-based alternatives for the production of fuels and chemicals has grown significantly in 
recent years. Ethanol is a well-known renewable resource that annual production is about 110 million tons 
from which 100 million tons used as fuels and chemicals (Kaltschmitt et al., 2014). Another bio product is 
isopropanol.  Its attractive production based on cellulose fermentation using E. coli enzymes are under great 
consideration nowadays (Soma et al., 2012). One of approaches aimed towards the catalytic valorisation of 
readily available ethanol and isopropanol into more advanced products is its cross-coupling directed to the 
pentanol-2 production that is a piperylene precursor. Piperylene is a valuable monomer that is used in 
manufacture of plastics, adhesives and resins.  
Among a known abundance methods of alcohols synthesis, C-C bond formation is a pivotal method to 
construct intricate molecules from some simple substrates. In spite of the great attention is given by scientific 
community to this process, it still has some disadvantages in the economic and environmental points of view.  
Here we report an alternative method one-pot β-alkylation of secondary alcohols with primary alcohols that 
first time ever was carried out over heterogeneous catalysts. 

2. Materials and Methods 

Analytical grade ethanol (96 %) was used without further purification. For catalytic experiments, original Au-
containing catalysts samples were used. Gamma Al2O3 with S=160 m

2/g was used as a support for metal 
nanoparticles. Au/Al2O3 catalysts were produced by deposition-precipitation as described by Nikolaev et al. 
(2013). In typical experiment an aqueous solution of HAuCl4 was adjusted to pH = 7.0 by adding NaOH (0.1 
M), then the support was dispersed in the solution with stirring for 1 h. This precursor was washed to remove 
Cl-, dried in air at 298 K for 24 h and calcined in air at 623 K for 3 h. NiO/Al2O3 catalyst was produced by 
impregnating Al2O3 (calcined at 623 K for 3 h) with an aqueous solution of Ni(NO3)2, followed by calcination at 

                               
 
 

 

 
   

                                                  
DOI: 10.3303/CET1650050

 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 

Please cite this article as: Zharova P., Chistyakov A., Tsodikov M., Nikolaev S., Corbetta M., Manenti F., 2016, Alkylation of isopropanol with 
ethanol over heterogeneous catalysts, Chemical Engineering Transactions, 50, 295-300  DOI: 10.3303/CET1650050 

295



623 K for 3 h. NiO/Au catalysts were produced by impregnating Au/Al2O3 catalysts with an aqueous solution of 
Ni(NO3)2, followed by calcination at 623 K for 3 h.  
The metal content of the catalysts was determined by atomic absorption on a Thermo iCE 3000 AA 
spectrometer. The relative error of this method was within ±1 %. Transmission electron microscopy 
(TEM) and energy-dispersive X-ray (EDX) analysis of catalysts were carried out on a JEOL JEM 
2100F/UHR microscope with 0.1-nm resolution and a JED-2300 X-ray spectrometer, respectively. The 
size of spherical (SPH) and distorted (DIS) particles was calculated as diameter and maximum linear 
size, respectively. For each catalyst, 300-380 particles were processed to determine the particle size 
distribution. The mean particle size was determined as the average size of the most frequent particles. 
The concentration of SPH particles in the catalyst was calculated as C(SPH) = n (SPH) × N × 100 %, 
where n(SPH) is the number of SPH particles, N (300-380) is the number of processed particles. The 
concentration of DIS particles was calculated in the same manner. X-ray diffraction (XRD) analysis was 
carried out on a Rigaku D/MAX 2500 instrument using Cu Kα radiation with a step size of 0.02 ° two-theta (2θ) 
ranging from 35–70 °. The average size of the gold particles was determined from XRD patterns using the 
Debye–Scherer formula. The strongest reflection observed with d = 0.235 nm was chosen as an analytical 
reflection for Au(111). 

The alkylation of alcohols was performed in a 45 mL high pressure Parr autoclave equipped with magnetic 
stirring under argon. The reactor was heated up to 275°C with a heating rate of 20 °C/min. Qualitative and 
quantitative analyses of the C1–C5 hydrocarbon gases were performed by gas chromatography (GC) with a 
Kristall-4000M chromatograph (detector: FID, carrier gas: He, column: HP-PLOT/Al2O3, 50 m × 0.32 mm). GC 
analyses of CO, CO2 and H2 were performed with a Kristall-4000 chromatograph (detector: TCD, carrier gas: 
Ar, column: SKT, 1.5 m × 4 mm). The qualitative composition of the liquid products were identified by gas-
liquid chromatography coupled to a mass spectrometry (GLC-MS) using a MSD 6973 - and an Autowt.-150 
spectrometer - (EI = 70 eV, catalyst volume = 1 µl, columns: HP-5MS, 50 m × 0.32 mm and CPSil-5, 25 m × 
0.15 mm). The quantitative content of the organic compounds was determined by GLC using a Varian 3600 
chromatograph (detector: FID, carrier gas: He, column: Chromtec SE-30, 25 m × 0.25 mm). Calibration of the 
GLC was carried out with commercial standards using method Haruta et al. (1987). 

3. Results and Discussion  

Found that over monometallic Au/Al2O3 and bimetallic Au-Ni/Al2O3 catalysts ethanol and isopropanol converts 
mainly into pentanol-2 and heptanol-4 (Table 1). Monometallic Ni/Al2O3 catalyst is not active in the process at 
all. Detailed analysis of the reaction products (Table 1) permits to consider that cross-coupling process 
proceeds according to Scheme 1. On the first step substrates molecules undergo dehydrogenation with acetic 
aldehyde and acetone formation. Should be noticed that among products we observed a small amount of 
acetic aldehyde that means aldehyde is more active molecule than acetone is under process conditions. The 
main by-reaction of aldehyde is self-aldonization resulting in butanol-1, hexanol-1 and octanol-1 formation.  
The catalyst containing 0.2 wt.% Au and 0.18 wt.% Ni was found to be the most active one in cross-coupling 
process. Over this catalyst total selectivity of cross-coupling products reached up to 70.2 % with ethanol and 
isopropanol conversions about 50 %. The decrease of Ni content leads to substrates conversion decreasing 
down to 29.3 % for ethanol and 27.7 % for isopropanol and selectivity lowering down to 61,8 %. Also Ni 
content decreasing leads to deceleration of intermediates hydrogenation that results in increasing of ketones 
formation selectivity. 
The increasing of both Au and Ni concentration in the catalyst up to 1 wt.% and 0.3 wt.%, consequently, leads 
to initial alcohols conversion increasing but aim products of cross-coupling selectivity lowering.  Also the 
inhibition of hydrogenation of intermediate ketones (pentanone-2, heptanone-4) was observed. Acetone and 
diethyl ether are the main by-products, that selectivity were 14.2 and 16.1 %, consequently.  
Monometallic catalysts containing 0.2-1 wt.% Au have lower selectivity of coupling products formation than 
bimetallic catalysts. Should be noticed that size effect of Au particles were observed during ethanol and 
isopropanol conversion. The decreasing of Au concentration leads to selectivity lowering of alkylation products 
but conversions of ethanol and isopropanol were increasing. So the smallest Au particles have the highest 
activity and lowest selectivity. The main by-products over 0.2 wt.% Au/Al2O3 catalyst are diethyl ether and 
acetone. Also one can see that the ratio between aimed alcohols (pentanol-2, heptanol-4) and ketones 
(pentanone-2 and hepnanone-4) significantly lower than one over the most prospective catalyst 0.2 wt.%Au-
0.18 wt.% Ni/Al2O3. That phenomenon means inhibition of hydrogenation processes.  
The diffraction patterns of Ni, Au and Au-Ni catalysts are shown in Fig.1. The diffraction pattern of 
monometallic Ni/Al2O3 catalysts present reflexes at 2θ = 32.5, 37.6, 39.5, 46.0, 61.1, 66.8 °, that indicates to 
the reflection from the faces (220), (311), (222), (400), (511 ), (440) of alumina (Nikolaev et al., 2013). 

296



Absence of reflections from Ni-containing phase indicates a high dispersion of active component on the 
support surface. In the diffraction pattern of Au/Al2O3 addition of Al2O3 present reflexes at 2θ = 38.1, 44.4 and 
64.6 °, which are the reflection of the faces (111), (200) and (222) of gold (Nikolaev et al., 2012). 
In comparison with Au/Al2O3 diffraction peaks of gold in Au-Ni/Al2O3 samples broadened, indicating a high 
dispersion of Au-containing phase. The lack of new reflexes or reflexes shifts in the diffraction patterns from 
gold in Au-Ni samples, allowing with high probability to eliminate the formation of alloys with unlimited 
solubility or intermetallic compounds with a regular structure. 

Scheme 1.  

OHCH3 OCH3-H2
OHCH2

 
 

OH

CH3CH3

-H2
O

CH3CH3

OH

CH3CH2

 
 

OCH3

O

CH3CH3

+

O

CH3

OH

CH3

O

CH3CH3

O

CH3CH3

+H2

-H2O

+CH3CHO

+H2

OH

CH3CH3

-H2O
O

CH3
CH3

OHO

CH3
CH3

+H2

O

CH3
CH3

CH3
CH3

+H2

+H2

O

CH3
CH3

-H2O

+CH3CHO

OHO

CH3CH3

OH

CH3CH3+H2

-H2O

 
 
Electronic state of metal in the Au-Ni, Au and Ni catalysts was studied previously by X-ray photoelectron 
spectroscopy, and the results are shown by Tkachenko et al. (2008). Found that Ni is presented in the oxide 
form on the surface of Ni/Al2O3. Gold is presented as metal in the Au/Al2O3 sample. Compared with the 
catalyst Au/Al2O3 binding energy of Au 4f7/2 electrons according to XPS spectrum of Au-Ni/Al2O3 catalyst 
shifted by + 0.3 eV. This result points to the fact that in addition to the zero-valent gold in the Au-Ni/Al2O3 
formed cations Au (+ n), 0 <n <1. The content of Au (+ n) is low and of the order of 10-20 at.%. Apparently, in 
the Au-Ni catalyst phase contacts Au (0) and NiO leads to electron transfer from gold to nickel oxide. As a 
result, the oxygen of the nickel oxide lattice interact with gold forming AuOy oxide.  
On the Au/Al2O3 catalyst surface areas exist ordering of the atoms belonging to gold particles with an average 
size of 10 ± 2 nm (Fig. 2) according to TEM and EDX analysis data. Formation in Au/Al2O3 of relatively large 
gold particles caused by weak metal-support interaction, which leads to sintering of noble metal particles at 
the stage of calcination the catalyst with impregnated precursor. In comparison with Au/Al2O3 average particle 
size in the Au-Ni/Al2O3 is shifted towards smaller particles possesses  average size about 5 nm (Fig. 3). The 
shift of the average particle size in the Au-Ni/Al2O3 indicates that nickel oxides stabilize small particles of gold 

297



on the support surface. With the TEM-EDX data found that 20% of the particles in the Au-Ni/Al2O3 comprised 
of non-interacting particles of Au and Ni oxide particles, while the remaining 80% is the composition of the 
bimetallic contact between a nickel oxide particles and small clusters of gold. 
Some contribution to the high activity of bimetallic Au-Ni/Al2O3 catalyst can give the formation of new centers 
of gold cations Au (+n). 0<n<1. Consider this idea in more detail. From Scheme 1 one can see that the growth 
of the alcohols hydrocarbon skeleton (for example pentanol-2) passes through the dehydrogenation-
hydrogenation steps. It is known that these processes are accompanied by changes of catalytic metal 
oxidation ratio from M(n) to M(n+2) (Nikolaev et al.. 2009). For the Au/Al2O3 catalyst changes in oxidation 
state of gold may be presented as next cycle Au (0) → Au (+2) → Au (0). which includes uncharacteristic for 
gold oxidation state (+2). Therefore. the hydrogenation-dehydrogenation of hydrocarbons over zero-valent Au 
clusters in the Au/Al2O3 take place at relatively low speed. In the case where. on the surface of gold clusters 
are formed by individual atoms in oxidation state close to (+1) rapid cycle becomes possible consisting of 
characteristic gold oxidation states Au (+1) → Au (+3) → Au (+1) . Therefore. the processes of hydrocarbons 
dehydrogenation-hydrogenation (and thus the formation of high molecular alcohols of Scheme 1) on cations in 
Au Au-Ni/Al2O3 should proceed at a higher speed. 
Heigh selectivity of alkylation products over Au-Ni/Al2O3 catalyst in comparison with monometallic analogue 
Au/Al2O3 can be explained by changes in the morphology of the active cites of the catalyst. Fig. 3 shows that 
in the case of bimetallic catalysts clusters of Aun-Nin-Aun-Nin are formed. Obviously. such close deposition of 
metals clusters favour multiple molecules coordination of ethanol and isopropanol and facilitated growth of 
advanced hydrocarbon skeleton structures (Scheme 1). 

Table 1. Products formation selectivity and conversions of ethanol and isopropanol (275 °C, 150 atm, 5 h on 
stream). 

catalyst 0,2Au-
0,02Ni 

0,2Au-
0,06Ni 

0,2Au-
0,18Ni 

1Au-
0,3Ni 

1Au 0,5Au 0,2Au 

total selectivity of alkylation product, 
% 61.8 66.9 70.2 53.6 49.2 41.5 33.8 

ethanol conversion. % 29.3 38.2 49.9 58.7 20.8 26.2 46.7 

isopropanol conversion. % 27.7 36.7 50.7 61.8 23.5 33.8 56.4 

product selectivity. % 

propane 3.7 2.3 2.3 1.3 2.6 2.4 4.3 

acetic aldehyde 0.2 0.2 0.1 0.3 3.1 3.6 2.9 

acetone 9.1 10.6 7.4 14.2 12.2 22.7 16.6 

ethyl isopropyl ether 2.4 2.8 1.0 4.7 4.4 4.4 6.9 

diethyl ether 6.2 4.1 3.5 16.1 18.8 11.8 26.2 

ethylacetate 0.3 0.5 0.2 0.6 0.8 2 0.8 

butanol-1 15.0 10.2 13.2 7.7 7.9 8.1 8.0 

pentanone-2 14.2 15.1 13.5 14.2 18.8 14.3 10.4 

pentanol-2 34.7 37.2 40.5 25.6 19.6 19.1 19.1 

hexanol-1 0.4 0.7 0.4 0.6 0.3 1.7 0.2 

butylacetate 0.1 0.9 0.8 0.2 0.2 1.5 0.1 

heptanone-4 3.1 3.4 2.5 5.2 4.8 3.2 1.1 

heptanone-2 1.1 1.9 2.1 1.5 0.3 0.2 0.1 

heptanol-4 7.0 7.2 9.8 6.3 4.8 4.0 2.8 

heptanol-2 0.8 0.9 0.7 0.4 0.2 0.3 0.1 

octanol-1 0.8 0.9 0.9 0.8 0.4 0.2 0.3 

nonanone-4 0.4 0.5 0.6 0.3 0.1 0.1 0.1 

nonanol-4 0.5 0.7 0.6 0.2 0.5 0.3 0.1 
Σ 100 100 100 100 100 100 100 

298



 
Fig. 1. XRD data for Ni/Al2O3. Au-Ni/Al2O3 and Au/Al2O3 catalysts 

Fig. 2 . TEM images of the supported nanoparticles in 

the catalyst Au/Al2O3 

 

Fig.3 TEM images of the supported nanoparticles in 

the catalyst Au-Ni/Al2O3 

 

4. Conclusions 

In conclusion, we report that Au-Ni systems effectively catalyze one-pot alkylation of isopropanol with ethanol 
resulted in pentanol-2 and heptanol-4 formation. The catalyst containing 0.2 wt.% Au and 0.18 wt.% Ni 
supported on γ-Al2O3 was found to be the most selective in the cross-coupling route. Total selectivity of 

299



coupling products reached up to 70 %. conversion of the both initial alcohols was 50 %. Structural 
investigations of the Au. Ni – containing catalysts permitted to determine two main factors effected on catalytic 
activity: structural and charge effects. In the case of bimetallic catalysts clusters of Auδ+n-Ni

+2
n-Au

δ+
n-Ni

+2
n are 

formed that provide effective coordination of substrates with active surface and make catalytic cycle via the 
most suitable charge state of gold. 

Acknowledgments 

This work was financially supported by Russian Scientific Foundation Grant № 15-13-30034 and used the 
equipment of M.V. Lomonosov Moscow State University (Program of MSU Development). 

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