CHEMICAL ENGINEERING TRANSACTIONS  
 

VOL. 52, 2016 

A publication of 

 

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

Guest Editors: Petar Sabev Varbanov, Peng-Yen Liew, Jun-Yow Yong, Jiří Jaromír Klemeš, Hon Loong Lam 
Copyright © 2016, AIDIC Servizi S.r.l., 

ISBN 978-88-95608-42-6; ISSN 2283-9216 
 

Study of Hydrogen Sulfide Absorption with Diethanolamine in 

Methanolic Aqueous Solutions 

Fatiha Amararene, Chakib Bouallou* 

MINES ParisTech, PSL-Research University, CES-Centre d'efficacité énergétique des systèmes 

60 Bd Saint Michel, 75006 Paris, France * 

chakib.bouallou@mines-paristech.fr 

The sulphur compounds are removed by various processes, among which that corresponding to the gas 

absorption in specific liquid solutions. This absorption is carried out by physical, chemical solvents and 

currently by mixing both in the so called hybrid solvents. In this work, hydrogen sulphide (H2S) absorption in a 

hybrid solvent containing aqueous Di-Ethanol-Amine (DEA) dissolved in methanol have been studied 

extensively in a modified Lewis cell reactor. Experiments have been achieved in an extended range of 

temperature, 313-353 K and with two mixtures (50 % water, 30 % DEA, 20 % Methanol), (40 % water, 40 % 

DEA, 20 % methanol). Through these experiments, three parameters affecting the absorption of hydrogen 

sulfide (temperature T, loading rate (mol H2S/mol DEA) and mass fraction %) were studied. Absorption is 

accelerated by raising the temperature while it is penalized by the increase in the loading rate. The absorption 

rate increases as the mass fraction of DEA varies from 30 % to 40 % to achieve an optimum loading rate ( = 

0.25 (1) at T = 333 K and  = 0.50 at T = 353 K) for which the absorption rate remains practically unchanged. 

1. Introduction 

The removal of acid gas impurities such as CO2, H2S, COS and CS2 from natural and industrial gases is a 

frequently encountered operation in process industry. Natural gas contains varying amounts of these acid gas 

components. These sulphur species are toxic and corrosive to processing equipment. H2S is the most 

common sulphur species in natural gas but varying amounts of COS and CS2 are often also present.  

Absorption by aqueous solutions of alkanolamines is the dominant industrial process for removing acid gases, 

mainly carbon dioxide (CO2), hydrogen sulphide (H2S), carbonyl sulphide (COS) and carbon di-sulphide (CS2) 
from natural gas. Such washing processes are also used in petroleum refining, coal gasification and hydrogen 

production. Industry would prefer to use less corrosive and more advanced solvent systems which could be 

formulated along with the plant design and operation, according to the feed and exit streams specifications of 

plants. In spite of an abundance of literature, only few works deal with absorption kinetics. The data which 

exist are dedicated to the study of the initial kinetics in gas unloaded solutions (Pani et al., 1997). The 

specifications imposed on the content of sulphur compounds in treated gas are very strict; indeed, the total 

content sulphur should not exceed 4 ppm. To reach this specification it is necessary to reduce the content of 

H2S. 

New developments are being considered in the treatment of acid gases, it is the increasing use of hybrid 

solvents (chemical and physical). The few studies carried out with hybrid solvents confirm the increase in 

solubility of acid gases such as CO2 and H2S as well as impurities such as COS in this solvent. There is a 

discrepancy about the kinetic point of view: is that absorption is physical or chemical between the acid gas 

and the amine according to a reaction mechanism? Santo and Rameshni (2014) discussed the design 

features of the units and reasons why they were selected. They discussed the options that we considered to 

design this unit, including the solvent evaluation and selection, the impact of H2S/CO2 ratio on the SRU 

design, and the selected optimum scheme of the Sulphur Recovery Units to meet the performance guarantees 

for many cases including the operating and the capital costs comparison. The challenge in their work was to 

deal with a wide range of feed gas compositions of H2S and CO2 while also dealing with a lot of impurities 

                                

 
 

 

 
   

                                                  
DOI: 10.3303/CET1652044 

 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 

Please cite this article as: Amararene F., Bouallou C., 2016, Study of hydrogen sulfide absorption with diethanolamine in methanolic aqueous 
solutions, Chemical Engineering Transactions, 52, 259-264  DOI:10.3303/CET1652044   

259



such as carbonyl sulphide (COS), heavy hydrocarbons, mercaptans, and benzene, toluene, xylene where the 

operation of the SRU’s with the lean gas and impurities are difficult. Tamajon et al. (2016) studied the CO2 

absorption into N-methyldiethanolamine hybrid (chemical and physical) solutions, using pure water, pure 

methanol and water + methanol mixtures as solvents. The CO2 absorption experiments were significantly 

influenced by the effect of temperature, amine concentration and water/methanol ratio. The performance of 

CO2 absorption into aqueous MDEA solutions was compared to that into hybrid MDEA solutions. It was 

concluded that MDEA aqueous solutions demonstrated lower performance than amine solutions using pure 

methanol or water–methanol mixtures as solvents, even at high temperatures and amine concentrations. 

Results showed that at high temperatures, amine concentration and chemical absorption had no relevant 

influence on the process. The methanol effect was noticed to improve the diffusivity and solubility in the 

process, by means of physical absorption. 

In our work, hydrogen sulphide (H2S) absorption in a hybrid solvent containing aqueous Di-Ethanol-Amine 

(DEA) dissolved in methanol have been studied extensively in a modified Lewis cell reactor. We used the 

same type of apparatus as described by Molina and Bouallou (2013). Experiments have been achieved in an 

extended range of temperature, 313-353 K and with two mixtures (50 % water, 30 % DEA, 20 % Methanol), 

(40 % water, 40 % DEA, 20 % methanol). 

 

Figure 1: Experimental apparatus 

2. Experimental section 

The Distilled water grade is used. DEA is from Aldrich, with a certified minimum purity of 99 % (mass). MDEA 

is from Fluka, with a certified minimum purity of 98 % (mass). The experimental apparatus (Figure 1) is a 

thermostated Lewis type reactor with flat horizontal gas-liquid interface (15.340.05) 10-4 m2. The total volume 

available for gas and liquid is (0.36530.0003) 10-3 m3. The temperature is controlled by circulating a 

thermostatic fluid through the glass double jacket. Experimental set up and procedure have been described in 

more detail by Amararene and Bouallou (2004). The originality here is the use of non-rotating stem valve; the 

loading time is thus considerably reduced. Kinetics of gas absorption are measured by recording the absolute 

pressure drop through a DRUCK pressure transducer, working in the range (0 to 250) kPa. This transducer is 

thermostated at a temperature higher than the experiment temperature to avoid liquid condensation in its 

measuring chamber. For each temperature investigated, it is calibrated within 80 Pa against a pressure 

calibration device. A microcomputer fitted with a data acquisition card is used to convert the pressure 

transducer signal directly into pressure units (Pa), using calibration constants previously determined, and 

record it as a function of time. Water and amine are degassed independently and aqueous solutions are 

prepared under a vacuum. The mass of water and amine are known by differential weightings. The flask 

containing the solution is connected to the reactor to allow the solution to transfer by gravity under vacuum. 

Accurate weightings of the flask before and after transfer yield the mass of solution actually present in the cell, 

260



and the liquid phase volume was calculated using the density. At a given temperature, and under solution 

vapour pressure PI, pure H2S is introduced during a very short time in the upper part of the cell, the volume of 

which is noted as Vg. Then stirring is started, and the pressure drop resulting from absorption is recorded. The 

estimated maximum experimental error in the H2S absorption rate is 8 %.  

3.  Results 

We conducted two types of measures: absorption measurements from fresh solutions and from H2S loaded 

solutions. In the first case, the cell Lewis is directly connected to the gas reserve, the amount of absorbed gas 

(assuming an ideal gas) is given by: 

 
RT

VPP
n

geqgg

ag




,0,

,  (1) 

where R is the gas constant (8.3143 J.K-1.mol-1), T is the absolute temperature (K). Vg is the volume of gas 

(m3). In the second type of tests, the gas contained in a press at constant volume, provided with a sensor and 

a probe for measurement of its temperature, is introduced into the cell through the liquid phase. The gas 

number of moles introduced is known thanks to the pressure difference in the press loading, which allows the 

determination of the density of the gas. This is calculated by ALLPROPS software. The circuit volume 

(reserve + tube) connecting the press load to the cell is estimated at (149.31  0.18) cm3. 

The calculation method of the H2S absorption flux in unloaded hybrid solvent solutions is similar to that used in 

the work of Bouallou Rivera-Tinoco (2007). In the case of H2S loaded solvents, the mass balance is 

determined by: 

dt

dP

RT

V
CCEak

SHg

eqSHSHil

2

,2int,2
)(


    (2) 

where kL is the liquid-side mass transfer coefficient (m s-1), E the enhancement factor, ai the interface area 

(m2), t the time (s) and CH2S,eq represents the gas concentration at equilibrium: 

SH

eqSH

eqSH
H

P
C

2

,2

,2
  (3) 

Integration of equation (2) yields: 

 
0

,0,

,
ln tt

PP

PP

eqTT

eqTT



















  (4) 

PT,eq represents the total pressure in equilibrium with the loaded solution. The experimental absorption flux is 

calculated by the following equation: 

 
eqTT

i

g
PP

RTa

V
,0,




  (5) 

For each experiment, the enhancement factor E is obtained from  using Eq 5 and estimates of data for the 

Henry's law constant HH2S and the liquid-side mass-transfer coefficient kL. Given the absence of data on the 

solubility, we considered the following equation to calculate the constant of Henry's Law of H2S in the hybrid 

solvent: 

methanolSHmethanolwaterSHwaterhybSH
HHH

,2,2,2
lnlnln    (6) 

This equation is similar to that given in the model of Wang et al. (1992), we have neglected in this case the 

excess term and the participation of the amine. The actual composition of water and methanol in the hybrid 

solvent is considered in the term corresponding to the volume fraction (water, methanol). 

We used the Kuranov et al. (1996) correlation to estimate the constant of H2S Henry's Law in water, this 

correlation covers a wide temperature range from 273.15 to 473.15 K, it is given by the following equation: 



)ln0551.550595651.0
8.13236

305.340exp(10

)(

6

13

2

TT
TmolmPaH

SH







  (7) 

The H2S Henry's Law constants in methanol HH2S,methanol (bar) at 313, 333 and 353 K are respectively 53.65; 

73.92 and 96.64. They were obtained using the model PSRK (DDB database). 

Knowing the density of the hybrid solvent is necessary to calculate the volume of liquid phase that permits to 

derive therefrom the gas phase during the operation data from the absorption tests. Indeed, the latter in the 

261



computation of the absorption rate or in the calculation of flow rates imposed for the designing of a column. 

Measuring the density of the mixtures is carried out by a vibrating tube densimeter (Anton Paar, DMA5000 

model). The measuring cell is a U-shaped glass tube, located inside the apparatus. This cell can be observed 

from the outside through a transparent window. The densimeter is first calibrated at 293 K by measuring the 

density of air and the degassed water. The temperature range covered is from 278 K to 353 K. All blends were 

prepared at room temperature in volumetric flasks of 20 mL previously evacuated; the amine is then 

introduced and then degassed. We introduce later water and finally methanol. The composition of the solvent 

is determined by weighing. The solvent of a known composition is transferred into a syringe and then 

introduced into the densimeter (Amararene et al., 2003). Note that at high temperature, the density 

measurement is difficult because for this temperature range, the methanol begins to evaporate and lowering 

the density, this phenomenon is more pronounced for solvents with high concentration of methanol. The 

density of the studied hybrid mixtures is a function of temperature and composition of the mixture. For a given 

composition, the density decreases with increasing temperature. The mixture density for the high MeOH mass 

fraction is lowest. Methanol is the lightest compound and its presence in large quantity required to the mixture 

a low density (the density of pure MeOH at 298.15 K is 0.78958 g cm-3). 

For mixtures having the same MeOH mass fraction, the denser mixture is that corresponding to the highest 
mass fraction of DEA, which is the highest density of compound (the density of pure DEA at 298.15 K is 
1.09627 g cm-3).  

 

Figure 2: Influence of temperature and the loading rate on the H2S absorption 

 

Figure 3: Influence of temperature and the loading rate on the H2S absorption 

262



Following the experimental procedure described above, we conducted absorption tests at three temperatures 

40 ° C (293 K), 60 ° C (333 K) and 80 ° C (353 K), in two mixtures with 50 % water, 30 % DEA and 20 % 

methanol and 40 % water, 20 % methanol for various loading rate (α) values. The latter is defined as the ratio 

of the gas absorbed moles number on the amine moles number; it depends on the temperature and amine 

mass fraction. To observe the influence of various parameters, we consider the ratio between the 

experimental absorption rate calculated by the Eq.5 and the driving force P=PT,0-PI. Figures 2 and 3 specify 

the influence of the temperature and the loading rate on absorption. 

Figure 2 (50 % Water 30 % DEA, 20 % methanol), show that for fresh solutions, the absorption rate increases 

with increasing temperature. In the case of the loaded solutions, the absorption rate increases as the 

temperature rises from 40 °C to 60 °C, elevating the temperature to 80 °C does not seem to have a significant 

influence on the absorption rate for loaded solutions. For the second composition Figure 3 (40 % water, 40 % 

DEA, 20 % methanol), the absorption rate increases with increasing temperature regardless of the solution 

used (fresh or loaded). The same Figures also show the influence of the loading rate on the H2S absorption. 

For a given composition and temperature, increasing the loading rate leads to the decrease of the absorption 

rate. 

Figures 4 and 5 show the influence of DEA mass fraction on the given temperature absorption kinetics. The 

increase in the DEA mass fraction causes an increase of the absorption rate, upon reaching a loading rate of 

0.25 moles of H2S / mole of DEA at T = 60 °C; absorption rates are then comparable (see Figure 4). At T = 

80 °C, there is also an increase in the rate with the composition, in this case the loading rate at which the rates 

are substantially identical is 0.50 moles H2S / mole of DEA (see Figure 5 ). 

 
Figure 4: Influence of DEA mass fraction on the H2S absorption  

 

Figure 5: Influence of DEA mass fraction on the H2S absorption  

263



4. Conclusions 

The H2S absorption in hybrid mixtures has been studied. We have conducted tests comprising reproducibility 

tests with two blends: 50 % Water 30 % DEA and 20 % Methanol, 50 % Water, 30 % DEA and 20 % 

methanol. Through these experiments, three parameters affecting the absorption of hydrogen sulphide 

(temperature T, loading rate  and mass fraction %) were studied. Absorption is accelerated by raising the 

temperature while it is penalized by the increase in the loading rate. The absorption rate increases as the 

mass fraction of DEA varies from 30 % to 40 % to achieve an optimum loading rate ( = 0.25 at T = 333 K and 

 = 0.50 T = 353 K) for which the absorption rate remains practically unchanged. 

In terms of absorption capacity, two different behaviors of hybrid solvent following operating conditions are 

observed: 

 At low H2S partial pressure and for a loading rate up to 0.78 mol / mol, absorption capacity of aqueous 

amine solution is highest; 

 At high partial pressure and for a loading rate higher than 0.78 mol / mol, the hybrid solvent has the 

highest absorption capacity. The use of a hybrid solvent is more favourable in high pressure conditions 

and high loading rate. 

On the basis of comparisons carried out in this work, it appears that the new hybrid solvent is the better 

solvent for the absorption of H2S compared to a conventional chemical solvent particularly at high loading rate. 

At high partial pressure and for a loading rate higher than 0.78 mol / mol, the hybrid solvent has the highest 

absorption capacity. The use of a hybrid solvent is more favourable in high pressure conditions and high 

loading. 

References 

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Chemical Engineering J., 48, 31-40. 

 

 

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