CHEMICAL ENGINEERING TRANSACTIONS  
 

VOL. 61, 2017 

A publication of 

 

The Italian Association 
of Chemical Engineering 
Online at www.aidic.it/cet 

Guest Editors: Petar S Varbanov, Rongxin Su, Hon Loong Lam, Xia Liu, Jiří J Klemeš 
Copyright © 2017, AIDIC Servizi S.r.l. 

ISBN 978-88-95608-51-8; ISSN 2283-9216 

Selective Hydrogenation of Alkynols in Ethanol Medium in a 

Batch Mode using Polyamine-Supported Pd Catalysts 

Ekaterina A. Kholkinaa, Linda Z. Nikoshvilia,*, Alexey V. Bykova, Alexey S. 

Morozovb, Ivan V. Bessonovb, Lioubov Kiwi-Minskerc,d, Esther M. Sulmana 

aTver Technical University, A.Nikitina str. 22, 170026, Tver, Russian Federation 
bJSC «Advanced medical technologies», Lukov lane 4, 107045, Moscow, Russian Federation 
cTver State University, Regional Technological Centre, Zhelyabova 33, 170100, Tver, Russian Federation 
dEcole Polytechnique Fédérale de Lausanne, GGRC-ISIC-EPFL, CH-1015, Lausanne, Switzlerand 

 nlinda@science.tver.ru 

Hydrogenation of triple carbon-carbon bond is of high importance and one of the main issues is the 

development of highly active and selective catalytic systems. Polymeric palladium-containing catalysts can 

serve as an alternative to traditional catalysts based on inorganic supports. In this work, the series of Pd 

catalysts based on highly branched polyamines were synthesized at variation of polyamine type and metal 

precursor nature. It was shown that the developed polyamine-based catalysts allowed achieving 99 % 

selectivity (at 98 % of substrate conversion) in hydrogenation of dimethylethynylcarbinol. 

1. Introduction 

Catalytic hydrogenation of triple carbon-carbon bond of alkynols is one of the most widely used reaction in 

production of fragrances, biologically active compounds and fat-soluble vitamins (Bonrath et al., 2007). 

Palladium is well known to be the most selective catalyst for hydrogenation of alkynols. Historically, Lindlar 

catalyst (Pd/CaCO3) was the first commercial catalyst of triple bond hydrogenation (Tschan et al., 2001), 

providing selectivity of about 96 % at nearly 100 % of substrate conversion, e.g. in hydrogenation of alkynol C5 

(Witte et al., 2012). However, the use of environmentally unfriendly modifiers such as lead acetate and 

quinoline, which contaminate target products, is necessary in order to achieve high selectivity. 

Polymeric matrices can be considered as an alternative to inorganic supports while developing palladium-

containing catalysts (Stepacheva et al., 2016). Their application allows avoiding the necessity to use modifiers 

due to the increase of selectivity (Valetsky et al., 2009). It is noteworthy that the nature of polymer is able to 

influence the catalyst reactivity, as it was shown for reactions of different types including triple bond 

hydrogenation (Corain and Kralik, 2000). The use of functionalized polymers contributes to dispersion of 

active metal catalyst, facilitates the diffusion of reactants into the polymer pores and the interaction between 

reagents and metal nanoparticles. The presence of amino groups, which are able to coordinate metals with 

formation of complexes, makes nitrogen-containing polymeric matrices one of the most perspective catalytic 

supports (Nemygina et al., 2016). 

In this work, the series of polyamine-supported Pd-containing catalysts intended for selective hydrogenation of 

triple carbon-carbon bond of alkynol C5 (dimethylethynylcarbinol, DMEC) was synthesized via wet-

impregnation method at variation of polyamine (PA) type and palladium precursor nature. 

2. Experimental 

2.1 Materials 
Highly branched polyethyleneimine (PEI) with Mw 50-100 kDa (50 % w/w aqueous solution) was purchased 

from MP Biomedicals (USA). (±)-Epichlorohydrin (ECH, ≥99 %), diethylene glycol (DEG, 99 %), 

dichloromethane (≥ 99.8 %), sodium dodecyl sulfate (SDS, 92.5 - 100.5 % based on total alkyl sulfate content 

basis), hexamethylene diisocyanate (HDI, ≥98.0 %), palladium(II) chloride (PdCl2, ≥ 99.9 %), 

                               
 
 

 

 
   

                                                  
DOI: 10.3303/CET1761145

 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 

Please cite this article as: Kholkina E.A., Nikoshvili L.Z., Bykov A.V., Morozov A.S., Bessonov I.V., Kiwi-Minsker L., Sulman E., 2017, Selective 
hydrogenation of alkynols in ethanol medium in a batch mode using polyamine-supported pd catalysts, Chemical Engineering Transactions, 
61, 883-888  DOI:10.3303/CET1761145  

883



bis(acetonitrile)palladium(II)chloride (PdCl2(CH3CN)2, 99 %), palladium(II) acetate (Pd(CH3COO)2, 99.98 %) 

were purchased from Sigma-Aldrich (USA). Sodium hydroxide (purum p.a., ≥97.0 %), sodium bicarbonate 

(purum p.a., ≥ 99.0 %) and dimethylethynylcarbinol (DMEC, 99 %) were purchased from Fluka (Czech 

Republic). Ethanol (95 vol.%) was purchased from JSC “Medkhimprom” (Russian Federation). Acetonitrile 

(HPLC grade, ≥99.99 %) was purchased from “Criokhrom” Company (Russian Federation). Hydrochloric acid 

(35 - 38 %) and toluene (99.85 %) were purchased from “Component-Reaktiv” Company (Russian Federation). 

All chemicals were used as received. Distilled water was purified with an Elsi-Aqua water purification system. 

2.2 Synthesis of PAs 
Three PAs (M33C, M37A and M50C) were synthesized as described below. The difference between these 

PAs was mainly in molecular weight, cross-linking degree and types of functional groups. 

PA of M33C type was prepared according to the procedure described elsewhere (Chen et al., 2012) with 

minor modifications. In a typical experiment, 60 g of PEI, 100 mg of SDS and 250 mL of toluene were placed 

into two-neck round-bottom flask. Then 10 mL of distilled water and 14.2 mL of HCl were added and the 

mixture was warmed up to 70 °C. After that ECH (7.6 mL in 10 mL of toluene) was added drop-wise to the 

reaction mixture by dropping funnel over 2 h at continuous stirring. The reaction was carried out under reflux 

and water was separated using Dean stark apparatus. The reaction was stopped after ca. 4 h, when all water 

was removed. After cooling to ambient temperature, resin was filtered using a Büchner funnel and washed 

sequentially with ethanol (2 x 200 mL), 10 % sodium hydroxide solution (1 x 100 mL) and distilled water until 

pH reached 8-9. Reaction product M33C was obtained as off-white powder (34.5 g, 99 %) after freeze-drying. 

M37A was prepared according to the following procedure: 27 g of PEI and 1.5 g of SDS were placed into two-

neck round-bottom flask and were dissolved in 125 mL of distilled water. Than solution of HDI (4.2 mL) in 

dichloromethane (12.5 mL) was added drop-wise to the reaction mixture by dropping funnel over 1 h at 

continuous stirring. After 4 h of stirring at ambient temperature, the reaction mixture was filtered using a 

Büchner funnel and washed sequentially with ethanol (1x50 mL), petroleum ether/toluene mixture 1:1 (3 x 

50 mL), ethanol (2 x 50 mL), 0.5 M HCl (1 x 50 mL), 1 M NaOH (1 x 50 mL) and distilled water until pH 

reached 8-9. Reaction product M37A was obtained as off-white powder (2.3 g, 13 %) after freeze-drying. 

M50C was prepared according to the following procedure: 40 mL of aqueous PEI solution (10 % w/w) and 

4.1 mL of DEG were placed into plastic tube (50 mL) with screw cap. The mixture was agitated using shaker 

during 2 min and placed in freezer at -18 °C overnight. After defrosting, resin was filtered on a Büchner funnel 

and washed several times with ethanol. Then it was placed in 100 mL round-bottom flask and 40 mL of 

ethanol was added. The mixture was refluxed for 2-3 h to eliminate the excess of DEG. After cooling to 

ambient temperature, resin was filtered using a Büchner funnel, washed sequentially with ethanol (2 x 30 mL), 

10 % sodium hydroxide solution (1 x 100 mL) and distilled water (5 x 30 mL). Reaction product M50С was 

obtained as off-white powder (5.0 g, 57 %) after freeze-drying. 

2.3 Catalyst synthesis 
PA-based catalysts were synthesized via conventional wet-impregnation method at variation of PA type and 

Pd precursor (PdCl2, PdCl2(CH3CN)2 or Pd(CH3COO)2). 

In a typical experiment, 0.3 g of PA was impregnated with 3 mL of solution of palladium precursor. Depending 

on the Pd compound different solvents were used: ethanol with the addition of HCl (0.1 mL) in the case of 

palladium chloride, and mixture of ethanol and acetonitrile (1:1) for both PdCl2(CH3CN)2 and Pd(CH3COO)2. 

After vigorous stirring during 10 min, all the Pd-containing PAs were dried at 75 °C for 1 h until the constant 

weight was achieved.  

The following catalysts were synthesized: PdCl2/M33С (designated as Pd/M33С-1), PdCl2(CH3CN)2/M33С 

(designated as Pd/M33С-2), Pd(CH3COO)2/M33С (designated as Pd/M33С-3), Pd(CH3COO)2/M37A 

(designated as Pd/M37A) and Pd(CH3COO)2/M50С (designated as Pd/M50С). 

2.4 Testing procedure 
Synthesized catalysts were tested in hydrogenation of DMEC to dimethylvinylcarbinol (DMVC) (see Figure 1). 

The reaction was carried out in a 60 mL isothermal glass batch reactor installed in a shaker and connected to 

a gasometrical burette (for hydrogen consumption control) at a temperature of 65 °C at vigorous stirring. The 

total volume of liquid phase was 30 mL. Ethanol was used as a solvent. Before the DMEC addition (1.5 g), in 

each experiment the catalysts were preliminarily reduced with hydrogen in situ during 60 min.  

Samples of reaction mixture were periodically taken and analyzed via GC-MS (Shimadzu GCMS-QP2010S) 

equipped with a capillary column HP-1MS (30 m × 0.25 mm i.d., 0.25 μm film thickness). Helium was used as 

a carrier gas at flow rate 1 mL/min. Analysis conditions: oven temperature 60 C (isothermal), injector and 

interface temperature 280 C, ion source temperature 260 C, range from 10 up to 200 m/z. 

Catalytic activity (designated as “R”) was calculated at 50 % of DMEC conversion: R50 = q × t−1 × 0.50, where 

q is DMEC-to-Pd molar ratio, and t is the reaction time for achieving of 50 % of DMEC conversion. 

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Figure 1: Scheme of DMEC transformation to DMVC 

2.5 Methods 
Synthesized PAs and PA-based catalysts were characterized by thermogravimetric analysis (TGA), liquid 

nitrogen physisorption, Fourier transform infrared (FTIR) spectroscopy, X-ray photoelectron spectroscopy 

(XPS), X-ray fluorescence analysis (XFA) and scanning electron microscopy (SEM). 

TGA was carried out using thermoscales TG 209 F1 (NETZSCH, Germany) with increasing temperature from 

30 С up to 200 С (10 С/min) and following delay at 200 С.  

Liquid nitrogen physisorption was carried out using Beckman Coulter SA 3100 (Coulter Corporation, USA). 

Prior to the analysis, samples were degassed in Beckman Coulter SA-PREP at 120 C in vacuum for 1 h. 

Weight of each sample was above 0.1 g. The following models were used for calculation of specific surface 

area (SSA) and pore size distribution: Langmuir, Brunauer-Emmett-Teller (BET), t-plot, Barrett-Joyner-

Halenda (BJH). Pore size distribution was measured in the range from 3 nm up to 200 nm. 

XPS data were obtained using Mg Kα (h = 1,253.6 eV) radiation with ES-2403 spectrometer (Institute for 

Analytic Instrumentation of RAS, St. Petersburg, Russia) equipped with energy analyzer PHOIBOS 100-MCD5 

(SPECS, Germany) and X-Ray source XR-50 (SPECS, Germany). All the data were acquired at X-ray power 

of 250 W. Survey spectra were recorded at an energy step of 0.5 eV with an analyzer pass energy 40 eV, and 

high-resolution spectra were recorded at an energy step of 0.05 eV with an analyzer pass energy 7 eV. 

Samples were allowed to outgas for 180 min before analysis and were stable during the examination. The 

data analysis was performed by CasaXPS. 

XFA was carried out to determine the Pd content. It was performed with a Zeiss Jena VRA-30 spectrometer 

(Mo anode, LiF crystal analyzer and SZ detector). Analyses were based on the Co Kα line and a series of 

standards prepared by mixing 1 g of polystyrene with 10 -20 mg of standard compounds. The time of data 

acquisition was constant at 10 s. 

The morphology of PA-based Pd catalysts was evaluated by SEM/EDX analysis using a Phenom ProX 

instrument at electron accelerating voltage of 17 kV. 

3. Results and Discussion 

3.1 Catalyst characterization 
According to the data of liquid nitrogen physisorption, all the synthesized PAs were found to have very low 

SSA (23 m2/g, 19 m2/g and 38 m2/g for M33C, M37A and M50C) with predominant meso- and macro-porosity. 

However, PAs were found to swell very strongly in polar medium, hence the Pd deposition was easily carried 

out and the access of DMEC to catalytically active sites can be successfully provided. 

To find thermal stability of PAs, TGA was carried out. Figure 2 presents the data of TGA for M33C, as an 

example. It is obvious that M33C is stable in the investigated temperature range. The observed weight loss of 

about 22 % can be explained by the moisture loss because of high moisture capacity of this kind of polymer 

and is not due to the thermal destruction of PA structure. This trend is typical for all synthesized PAs. Thus, 

the reaction of DMEC hydrogenation using PA-based palladium catalysts can proceed at a temperature of 

65С without risk of destruction of polymers. 

Figure 3 shows SEM images of (a) Pd/M33С-3, (b) Pd/M37A and (c) Pd/M50С as examples of catalysts 

based on different PAs and containing the same Pd precursor (Pd(CH3COO)2). It is noteworthy that Figure 3 

shows SEM images for freshly prepared (unreduced) catalysts. The presented SEM images demonstrate the 

presence of palladium-containing particles and their aggregates (as was also confirmed by data of elemental 

mapping) on the surface of the polymeric supports. It was revealed that PA of М33С type has clearly defined 

macroporous structure, which is absent in the case of М37А and M50C. It should be also mentioned that 

morphology of all the synthesized catalysts was revealed to be the same as in the case of initial PA samples. 

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Figure 2: TG curve of PA of M33C type 

 

Figure 3: SEM images of (a) Pd/M33С-3, scale 10 μm, (b) Pd/M37A, scale 80 μm, and (c) Pd/M50С, scale 

80 μm 

XPS analysis was performed in order to determine Pd content as well as its oxidation state on the catalyst 

surface. Surface of all the Pd/PA catalysts was found to contain mainly carbon, oxygen, nitrogen, silicon and 

palladium (see Figure 4 (a) as an example). Besides, in some cases, other elements such as magnesium, 

calcium, aluminium, sodium, sulfur and chlorine were found. 

  

Figure 4: (a) Survey spectrum of Pd/M33С-3 and (b) high-resolution spectrum of Pd 3d of Pd/M33С-3 

According to the high resolution spectrum of Pd 3d as shown in Figure 4 (b), the values of the binding energy 

of Pd 3d5/2 in the case of catalysts synthesized while using Pd acetate as a precursor were found to be ca. 

335 eV and 337 eV, which correspond to Pd(0) and PdO (Wagner et al., 1979). The existence of Pd(0) and 

PdO on the catalyst surface can be ascribed to the transformation of initial precursor during the catalyst 

886



synthesis. Thus, the partial reduction of Pd occurs. This fact can be also confirmed by the absence of 

induction period on kinetic curves (see Figure 5). It should be emphasized that PdO is easily reducible Pd 

specie, so it can be completely reduced during the treatment of catalysts with hydrogen in situ before the 

reaction. 

While using PdCl2(CH3CN)2 as a precursor for impregnation of PA of M33C type, binding energy of Pd 3d5/2 

was found to be equal to 334.5 eV (corresponds to Pd(0)) and 336.8 eV (presumably corresponds to mixture 

PdOx/Pd). In the case of M33C impregnated with PdCl2, the following values of binding energy of Pd 3d5/2 

were found: 337.4 eV (corresponds to PdO) and 335.6 eV (corresponds to Pd(0)). 

3.2 Catalytic testing 

3.2.1. Influence of Pd precursor nature 

PA of M33C type, which is characterized by strongly hydrophilic properties and the presence of free amino 

groups, was chosen as a support for investigation of the influence of Pd precursor nature. Obtained results are 

presented in Table 1 and in Figure 5. 

Table 1: Influence of Pd precursor nature on DMEC hydrogenation using catalysts based on M33C 

Catalyst Functional 

groups of 

support 

Pd content Conversion 

of DMEC, % 

Selectivity  

to DMVC, % 

Yield of 

DMVC, % 

R50,  

s-1 
XFA,  

wt. % 

XPS,  

at. % 

SEM/EDX, 

wt. % 

Pd/М33С-1 

-NH2 

1.99 0.08 8.33 88 97 85 0.2 

Pd/М33С-2 1.89 0.46 3.29 98 98 96 0.6 

Pd/М33С-3 1.88 0.47 10.84 98 99 97 0.9 

 

 

Figure 5: Kinetic curves of DMVC accumulation at variation of Pd precursor nature for the catalysts of 

Pd/M33C series 

It was found that the nature of Pd precursor noticeably influences the catalyst behaviour. Best results (99 % 

selectivity at 98 % of substrate conversion) were obtained while using palladium acetate as a precursor. This 

observation is in good agreement with the data of XPS analysis and SEM/EDX measurements, according to 

which M33C impregnated with Pd(CH3COO)2 has highest Pd content on the surface. The use of 

PdCl2(CH3CN)2 as a precursor allowed also achieving high selectivity (99 % at 98 % of substrate conversion), 

but this catalyst revealed slightly lower activity in comparison with Pd/М33С-3. In case of Pd/М33С-1 (PdCl2), 

the lowest initial substrate conversion (88 %) was achieved. Figure 5 shows the differences in behaviour of 

Pd-containing catalysts based on M33C at variation of Pd precursor nature. 

Pd(CH3COO)2 was chosen as optimal metal precursor for further investigation of Pd-containing catalytic 

systems at variation of PA type. 

From the data presented in Figure 5, it is obvious that the induction period is absent, which indicates the 

presence of reduced form of palladium in all the catalysts of Pd/M33C series. 

3.2.2. Influence of PA type 

As a second part of this work the investigation of the influence of PA type was carried out using Pd acetate as 

a precursor. Obtained results are presented in Table 2. 

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Table 2: Influence of PA type on DMEC hydrogenation over Pd/PA (Pd(CH3COO)2) catalysts 

Catalyst Functional 

groups of  

support 

Pd content, % Conversion 

of DMEC, % 

Selectivity 

to DMVC, % 

Yield of 

DMVC, % 

R50,  

s-1 
XFA,  

wt. % 

XPS,  

at. % 

SEM/EDX, 

wt. % 

Pd/М33С-3 -NH2 1.88 0.47 10.84 98 99 97 0.9 

Pd/M37А -NH2, -C(O)NH- 2.10 0.32 9.56 98 98 96 1.0 

Pd/M50С -NH2 1.78 0.64 21.76 98 95 93 0.5 

Lindlar catalyst (2 %-Pd/CaCO3) 2.03 2.58 - 99 95 94 1.2 

Based on the data presented in Table 2 it can be concluded that both M33C and M37A allowed synthesizing 

active and selective catalysts: activity was close to that of commercial Lindlar catalyst, while the selectivity 

was noticeably higher (98 - 99 % vs. 95 %). The catalyst based on PA of M50C type showed lower of activity 

and selectivity in spite of the highest Pd content on the surface that is likely due to the relatively poor Pd 

dispersion in comparison with other two samples and formation of large Pd aggregates (see Figure 3).  

4. Conclusions 

In the framework of this study the series of PA-based palladium catalysts were synthesized at variation of PA 

type and metal precursor nature. Developed polymeric Pd-containing catalysts were tested in the reaction of 

selective hydrogenation of alkynol C5 – DMEC. The highest value of selectivity with respect to DMVC (99 % at 

98 % of DMEC conversion) was achieved while using palladium acetate as a precursor. It was shown that 

behaviour of the catalysts strongly depends on the PA type. The structure of polymeric support plays an 

important role: PA of M33C type with highest degree of cross-linking was shown to have best morphology, 

which allowed formation of highly active Pd aggregates on the catalyst surface. 

Acknowledgments 

This work was funded by the Russian Science Foundation (project 15-19-20023). 

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