J. Build. Mater. Struct. (2018) 5: 185-196 Original Article  
DOI : 10.34118/jbms.v5i2.57  

 

ISSN  2353-0057, EISSN : 2600-6936 

Reaction kinetics of cassava starch graft anionic/nonionic-type 
polymer internal curing agents 

Liu R J1,2,3*, Sun ZH 2, Xiang WH1, Chen P 1,3, Zhou RZ1 

 
1 College of Materials Science and Engineering, Guilin University of Technology, Guilin 541004, P.R.C. 
2 Civil and Environmental Engineering Department, University of Louisville, Louisville, KY 40292, U.S.A. 
3 
 

Ministry-province Jointly-constructed Cultivation Base for State Key Laboratory of Processing for Non-
ferrous Metal and Featured Materials, Guilin 541004, P.R.C. 

* Corresponding Author: liujin@glut.edu.cn 

 
Received: 07-05-2018 

 
  

 
Accepted: 29-08-2018 

Abstract: Internal curing can help to improve the durability of concrete by preventing and 
minimizing initial cracks due to autogenous shrinkage and plastic shrinkage. Using a reliable 
internal curing agent is essential to the effectiveness of the internal curing process. This 
paper investigates the reaction kinetics of a starch graft anionic/nonionic-type polymer. The 
results demonstrate that initiator monomer concentration, and starch concentration are 
positively correlated with graft reaction rate Rp. Based on the research, the kinetics equation 
of this cassava starch graft anionic/nonionic-type polymer has also been developed, which 
coincides well with the law of free radical polymerization. The obtained Rp equation is a first-
order dependence of the monomer concentration and the square root of the initiator 
concentration. And Rp is further correlated to the reaction temperature based on a sigmoid 
function instead of a linear function. It is also found that the polymerization reaction is 
characterized by the coexisted disproportion termination and coupling termination. 

Key words: free radical polymerization; graft reaction rate; kinetics; growth sigmoid curve; internal 
curing agent. 

1. Introduction 

Concrete, as the most commonly used material, creeps and shrinks during its service life. 
Concrete shrinkage, which causes volume change of the material, happens due to the loss of 
moisture (either internally or externally). It was found that the plastic shrinkage was the biggest 
reason for surface cracking of concrete pavements during the early age (Mindess et al., 2003). 
Early-age cracking is a predominant problem especially for high strength concrete/high 
performance concrete (HSC/HPC) due to the high autogenous shrinkage (self-desiccation) 
caused by its low water-to-cement ratio (w/c) and the usage of fine or ultra-fine mineral 
admixtures. These cracks would affect the durability and service life of concrete. Therefore, 
concrete curing plays a vital role in guaranteeing the development of the mechanical properties 
and service life performance of concrete. 

In recent years, ideas of internal curing were proposed (Philleo, 1991; Weber & Reinhardt, 1997; 
Bentz & Snyder, 1999; Lura et al, 2014 ; Jensen & Hansen, 2001; Jensen & Hansen, 2002; Igarashi 
& Watanabe, 2006). Internal curing is a process of providing concrete with additional water 
internally during the hydration process. This is done by using water absorbed in expanded shale, 
clay or slate (ESCS) lightweight aggregate(LWA)(Weber & Reinhardt, 1997; Bentz & Snyder, 
1999; Lura et al, 2014 ) to partially replace the conventional aggregates in the mixture; or by 
using superabsorbent polymers (SAP) that would release water when needed during the self-
desiccation process (Jensen & Hansen, 2001; Jensen & Hansen, 2002; Igarashi & Watanabe, 
2006). By compensating the moisture loss due to self-desiccation, cracking caused by early-age 
shrinkage can be minimized and the ongoing hydration can also be improved. 



186 Rongjin et al., J. Build. Mater. Struct. (2018) 5: 185-196  

 

 

The effectiveness of internal curing is governed by the internal curing agents (ICA) or internal 
curing materials (ICM), such as LWA or SAP that used. SAP has been paid close attention to due 
to its high absorbency and its merit of swelling without dissolving in water. The present SAPs 
used in concrete are graft polymers made by starch, cellulose or the functional monomer such as 
acrylic acid, acrylonitrile, acrylamide (Jensen & Hansen, 2001 ; Schröfl et al, 2012 ; Assmann & 
Reinhardt, 2014). Controlling synthesis reaction is critical to acquire reliable ICAs. Especially for 
starch graft type polymer ICA, reaction kinetics strongly affects the stability of the reacting 
systems and the quality of the final ICAs. However, limited work has been done to report how to 
prepare stable and qualified starch graft type polymer ICA through reaction controlling. Lutfor et 
al. (2001) proposed several kinetics parameters and utilized ceric ammonium nitrate to 
investigate reaction kinetics of graft copolymerization of acrylonitrile and starch (Rahman et al, 
2000). They also deduced the graft copolymerization reaction rate and derived the relation 
formula for monomer concentration and graft rate. Yu et al. (1999) studied the copolymerization 
kinetics of graft acrylonitrile onto starch by using benzoin ethyl ether as initiator, and derived 
the reaction rate equation and calculated the activation energy. They also deducted relative 
differential selective expression in the process of grafting under the experimental conditions. 
Wang (2003), explored the relationship among the concentration of initiator, monomer, starch 
graft, and the reaction rate by utilizing butyl acrylate, starch, ammonium per sulfate and 
emulsifier sodium dodecylsulfate. He proposed a graft reaction rate equation at the beginning of 
the reaction when the concentration of initiator was low. Similar research has been done by 
Yang et al. (2006) who obtained a simplified kinetics equation for two parameter-type universal 
graft polymerization reaction with experimental data. These previous works on reaction kinetics 
mainly confine to binary starch graft copolymerization reaction system without considering the 
effect of temperature. Recent research found that ternary starch graft system satisfies very well 
with the requirements of water absorbency, water retaining, and water releasing of ICAs 
because of its multiple functional groups (Liu, 2003).Therefore, knowing the reaction kinetics of 
the ternary graft system is useful to understand the relationship between the reaction systems 
and the quality of ICAs and is also helpful to control synthesis reaction. On the other side, 
temperature was also found to be a critical factor that closely related to molecular weight 
distribution, chain length, conversion of monomer, etc. (Lipsa et al, 2013). Therefore, 
temperature should also be included when modeling the reaction kinetics of a ternary starch 
graft system. 

In this study, a kind of ICA called starch graft copolymer AM-AMPS (STAGAA) was developed. 
This ICA uses cassava starch, acrylamide (AM), and 2-acrylamide-2-methyl propyl sulfonic acid 
(AMPS) as the raw materials for the ternary system. Based on the preparation of the STAGAA, 
this paper attempts to further discuss how the related factors, such as concentration and 
temperature, affect the synthesis reaction. And the reaction rate equation for STAGAA ternary 
graft copolymer was also developed in this study. This would serve the purpose to predict 
synthesis reaction with eligible explanation. 

2. Experimental details 

2.1. Raw Materials 

There are four kinds of reagents used in synthesis process, which are starch, monomer, initiator 
agent, and crosslinking agent. The moisture content of the cassava starch, the skeleton of 
STAGAA copolymer, was 11.2% and its side chain content was 83%. The molecular structure of 
the cassava starch is illustrated in Figure 1. The amount of side chains plotted in Figure 1a 
represents the amount of active graft sites. The higher content of the side chain would lead to 
more active chemical reaction with the monomer (Moad & Solomon, 2006).The C-C bond 
between C2 and C3 sites in the glucose ring is easy to break and then the hydroxide on C2 and C3 
is easy to react (Tong & Zhang, 2005; Zhang, 2001), as showed in Figure 1b. 



 Rongjin et al., J. Build. Mater. Struct. (2018) 5: 185-196 187 

 

 

O

O

OH

OH

CH2

O

OH

OH

CH2OH

O
O

O

OH

OH

CH2OH

O

OH
OH

CH2OH

O

O
O

O

OH

OH

CH2OH

O

 

(a) Structure unit 

 

O
H H

O O

CH2OH

OH OH

H H

1234

5

6

 

(b) Glucose ring  

Fig 1. Molecular structure of amylopectin cassava starch 

The used reagent monomers in STAGAA synthesis process were of two kinds: acrylamide (AM) 
that provides with nonionic amide group and 2-acrylamido-2-methylpropane sulfonic acid 
(AMPS) that provides with anionic sulfonic group. Ammonium persulfate (APS) and N,N`-
methylenebisacrylamide (NMBA) were used as an initiator agent and a crosslinking agent, 
respectively. 

2.2. Preparation of STAGAA 

The STAGAA copolymer was synthesized by aqueous solution method shown in Figure 2.  

 

Fig 2. Flowchart of STAGAA synthesis. 

First, the cassava starch was mixed and dissolved with distilled water, and then heated to 70~80 
°C to gelatinize in a four-necked flask for about 30 minutes until the color turns colorless from 
white. Then, the action temperature was lowered to 60~70 °C and APS was added for initiating 
for 30 minutes. Next, AM, AMPS and NMBA were all dissolved in distilled water, and then 
dropped very slowly, and grafted and copolymerized for about 2 hours until a transparent or 
translucent gel-like substance was achieved. Finally, the gel-like product was precipitated in 
alcohol, then filtered and washed with distilled water repeatedly, and dried at 105 ℃in a vacuum 



188 Rongjin et al., J. Build. Mater. Struct. (2018) 5: 185-196  

 

 

oven to constant weight, then crushed and ground to the required fineness to obtain the STAGAA 
powder. For the characterization purpose, part of the gel-like crude product was also put in a 
Soxhlet extractor with isopropanoltoreflux and extract for 24 hours. The purified sample was 
subsequently dried to a constant weight to remove unreacted monomers. 

2.3. Determination of Graft Reaction Rate 

In this study, the weight method was used to determinate the graft reaction rate, Rp. Firstly, a 
certain amount of the purified STAGAA copolymer was put into concentrated hydrochloric acid 
by refluxing to fully eliminate the starch backbone. Then, 1 mol/L sodium hydroxide solution 
was used to neutralize the residual hydrochloric acid and AgNO3 solution was used to be 
hydrochloric acid until the Cl- is completely reacted. After that, the insoluble product was dried 
in a vacuum and its weight equaled the weight of monomer on the grafted side chain. The graft 
reaction rate, Rp, can be calculated according to the following equation based on the side chain 
weight. 

 
(1) 

During the grafting reaction, several factors such as initiator concentration, monomer 
concentration, and starch concentration should be considered comprehensively, and Rp can also 
be written as Eq (2): 

[ ] [ ] [ ]
a b c

p
R K A B C   (2) 

where K represents the rate coefficient; [A] is the initiator concentration (in mol/L); [B] is the 
monomer concentration (in mol/L); [C] is the starch concentration (in mol/L); a, b, and c are 
reaction orders, respectively.  

The logarithmic expression of the above mentioned Eq (2) can be shown in the following 
equation: 

ln ln ln[ ] ln[ ] ln[ ]
p

R K a A b B c C     (3) 

According to the experimental data, there is a liner correlation between lnRpand ln[A], and the 
slope equals the coefficient a. Similarly, when plotting the curve of lnRpversus ln[B] and ln[C] 
respectively, coefficient b and c can be obtained. Given a certain temperature, reaction rate Rp, 
reactants concentration [A], [B] and [C], reaction stages a, b, c, and the rate constant K can be 
obtained from Eq (3). 

3. Results and discussion 

3.1. IR analysis of STAGAA 

In Figure 3a, the absorption peak 3394.1 cm-1 presents the stretching vibration of alcohol - OH 
group in cassava starch, while 2931.3 cm-1 marks saturated C - H stretching vibration. Peaks of 
1421.3 cm-1, 1016 cm-1, and 1157 cm-1 represent asymmetric stretching vibration of C - O - C key 
symmetric in the glucose unit. In Figure 3b, 3411.5 cm-1 shows that product retains the alcoholic 
alcohol - OH group absorption peak but blueshifts; New "shoulder peak" 3208.8 cm-1 addresses 
the stretching vibration of imino group (= NH)  in AMPS; For 1670.1 cm-1 and 1043.3 cm-1 , they 
are stretching vibration peak of carbonyl group C = O and S = O sulfonic group respectively. The 
above three characteristics are a clear indication that the monomer AM and monomer AMPS 
were grafted onto the cassava starch and formed the anionic and nonionic polymer STAGAA. 

grafted monomer weight onto side chain

monomer molar mass reaction time
( / )

reaction volume
p

R mol L min
 

 



 Rongjin et al., J. Build. Mater. Struct. (2018) 5: 185-196 189 

 

 

 

 

Fig 3. IR spectrograms of cassavastarch (a) andSTAGAA (b) 

3.2. SEM analysis of STAGAA 

 Seen from Figure 4a, cassava starch particles have spherical or hemispherical in shape and 
smooth surface, and its size varies widely. In Figure 4b, STAGAA obviously characterizes by 
wrinkled surface, and its assemble as a layered structure. Its microstructure is clearly different 
from three-dimensional network of the common crosslinked SAP (Ren et al, 2012). According to 
the synthesis process and the surface morphology, the authors tentatively thought that the 
shape and its assemble state were formed as follows: the water-absorbed STAGAAs firstly lost 
internal water under the interaction with the environment, then the flexible strip or membrane 
STAGAAs gradually stacked, finally assembled as a special appearance of wrinkles. This kind of 
wrinkled surfaces and layered structure provides STAGAAs with a channel to absorb water and a 
lot of space to store water. 



190 Rongjin et al., J. Build. Mater. Struct. (2018) 5: 185-196  

 

 

 

 

Fig 4. Morphology of cassava starch (a) and STAGAA (b). 

3.3. Determination of Early Reaction Time 

The monomer weight change grafted onto starch backbone has been recorded shown in Figure 
5. It shows that the mean monomer mass grafted onto starch backbone increases linearly with 
the increasing reaction time during the early 30minutes, but it increases slowly after that. This 
indicates that the reaction rate is approximately constant in early reaction time (30 minutes) 
and it can be considered as the initial reaction rate. 



 Rongjin et al., J. Build. Mater. Struct. (2018) 5: 185-196 191 

 

 

0 10 20 30 40 50

0.5

1.0

1.5

2.0

2.5

3.0

3.5

  

 

 

W
e
ig

h
t 

o
f 

g
ra

ft
in

g
 s

id
e
 c

h
a
in

 (
g
)

 Reaction time (min)

 

Fig 5. Curve of the grafted monomers weight changes with the reaction time 

3.4. Initiator Concentration 

In the study, starch concentration [C] and monomer concentration [B] were first kept constant at 
0.23 mol/Land 1.5 mol/L. The material was reacted at 70 ℃ for 30minutes. The initiator 
concentration [A] was ranged from 0.01 mol/L to 0.012 mol/L. The fitting curve of lnRp is plotted 
in Figure 6. It shows that the curve lnRp presents a positive linear correlation with ln[A] at early 
stage of the graft reaction. The linear correlation coefficient R2 was 0.998 using the least squares 
linear regression fitting. Therefore, for the initiator, the reaction order (coefficient a in Eq 3) was 
0.509. 

4.40 4.45 4.50 4.55 4.60

4.78

4.80

4.82

4.84

4.86

4.88
y = 2.53 + 0.509x

R
2
=0.998

  

 

 -ln[A]

-l
n

R
p

 

Fig 6. The relationship between -lnRp and -ln[A] 

It should be noted that when the initiator concentration increases, starch free radicals and 
monomer free radicals increase accordingly. Thus, the number of graft reaction active center 



192 Rongjin et al., J. Build. Mater. Struct. (2018) 5: 185-196  

 

 

increases, which accelerates the synthesis reaction. The chain termination process of the alkene 
monomers is controlled by the diffusion process (Gugliemelli et al, 1972).When Rp is 
proportional to the square root of the initiator concentration, it indicates that all the coupling 
reactions are terminated. However, it is difficult to realize the termination of all the coupling 
reactions because some free radicals are encased during the gel reaction process. In general, 
termination by disproportion and coupling coexist, and the graft reaction order of the initiator 
concentration ranges from 0.5 to 1.0 (0.5 for coupling termination, 1.0 for disproportionation 
termination). In this study, when the reaction order of initiator (coefficient a) goes up to 0.509, it 
means that both the disproportion termination and the coupling termination coexist and the 
latter takes a dominant position. 

3.5. Monomer Concentration 

To find out the coefficient b in Eq (3), the starch concentration [C] and the initiator 
concentration [A] were kept constant at 0.23 mol/L and 0.012 mol/L, respectively, and the 
material was reacted at 70 ℃ for 30 minutes. The monomer concentration [B] varied from 0.7 
mol/L to 1.5 mol/L and the fitting curve of Rp is presented in Figure 7. 

-0.5 -0.4 -0.3 -0.2 -0.1 0.0 0.1 0.2 0.3 0.4

4.8

5.0

5.2

5.4

5.6

5.8

y = 5.35 + 1.13x

R
2
=0.915

 

 

 

-l
n

[R
p

]

-ln[B]

 

Fig 7. The relationship between -lnRp and -ln[B] 

3.6. Starch Concentration 

It can be seen that the curve of Rp with [B] exhibits a positive linear correlation within the range 
that studied. The R2 is 0.915 and the reaction order (coefficient b in Eq 3) is 1.135 for the 
monomer. This relationship indicates that low monomer concentration means monomer 
molecules have enough chance to cover the surface of the starch, so the active reaction center on 
the surface is relatively poor. Within a certain range, the monomer amount caused by free 
radicals increases, thus Rp increases significantly. 

In order to further study the relationship between Rp and starch concentration [C], the monomer 
concentration [B] and the initiator concentration [A] were kept at 1.5 mol/L and 0.012 mol/L 
with the graft reaction at 70 ℃ for 30 minutes. The chosen starch concentration was changed 
from 0.03 mol/L to 0.23 mol/L. The correlation curve is shown in Figure 8. It shows that the Rp 
presents a good linear relationship with the starch concentration. With the R2 value of 0.999, the 
obtained reaction order is 0.506 (coefficient c in Eq 3) for the starch. 



 Rongjin et al., J. Build. Mater. Struct. (2018) 5: 185-196 193 

 

 

1.5 2.0 2.5 3.0 3.5

4.8

5.0

5.2

5.4

5.6

5.8

6.0

y = 4.05 + 0.506x

R
2
=0.999

  

 

 

-l
n

[R
p

]

-ln[C]

 

Fig 8. The correlation between -lnRp and -ln[C] 

This linear correlation is due to the fact that the reaction occurs mainly on the surface of starch 
molecules at first. Then, with the increasing starch concentration, the active reaction sites on the 
surface of starch molecules will increase, which causes the significant increasing of Rp. 

From the reaction orders of initiator concentration [A], monomer concentration [B], and starch 
concentration [C], the Eq (2) of Rp can be revised as follows: 

     
0.509 1.135 0.506

P
R K A B C   (4) 

3.7. Reaction Temperature 

In order to investigate the influencing factors on the rate constant K, both the Rp and K values are 
listed in Table I when the reaction temperature T was changed from 50℃ to 80℃while the 
concentration of starch, monomer, and initiator constant were kept at 0.23 mol/L, 1.5 mol/L, 
and 0.012 mol/L, respectively. 

Table 1. The Relationship of the Rp and K with T 

T 
(℃) 50 55 60 65 70 75 80 

(K) 323.15 328.15 333.15 338.15 343.15 348.15 353.15 

Rp×103 1.079 1.576 2.988 5.01 7.905 8.295 8.412 

K(min-1) 0.0136 0.0199 0.0377 0.0631 0.0997 0.1046 0.1061 

The table indicates that both Rp and K increase with the increasing reaction temperature. 
However, the Rp value increases slowly when temperature increases from 50 to 55℃, it increases 
notably faster after that. This is due to the faster initiator (NH4)2S2O8 decomposition rate caused 
by the higher temperature. When the initiator produces more free radicals, the increased grafted 
monomer leads to the higher number of free radicals, causing graft reaction chain initiation and 
chain growth rate to increase correspondingly. At the same time, the higher temperature is 
beneficial to the starch gelatinization and the increase of active sites on the starch molecule 
surface, which makes the Rp to increase in the end. 



194 Rongjin et al., J. Build. Mater. Struct. (2018) 5: 185-196  

 

 

According to Table 1, the relationship between the rate constant K and the temperature T (in 
Kelvin) is plotted in Figure 9. Instead of a linear relationship proposed by Lutfor et al. (2001) 
and Wang (2003), it can be seen from the figure that the K-T relationship satisfies a sigmoid 
function. The rate constant, which should be called rate coefficient, increases slightly within the 
low and high temperature ranges, but it increases sharply during intermediate temperature 
section. This indicates that the copolymer reaction of starch-graft-AM-AMPS is more complex 
than ordinary radical copolymerization. Since a ternary starch graft system is easier to form gel 
for copolymerization, the reaction temperature of STAGAA should not be limited to the range 
from 60 to 70℃. 

320 325 330 335 340 345 350 355
0.00

0.02

0.04

0.06

0.08

0.10

0.12

K=0.10583-0.09462/(1+exp((T-337.298)/3.2769) )

R 
2
=0.9888

 

 

K

T (K) 

 

Fig 9. The fitting curve of K with T 

This relationship can also be expressed by Eq (5), where the correlation coefficient R2 is 0.9888. 

   / 1  0 337.289 / 3.276.10853 0.0 2 9946K exp T     (5) 

The final expression for Rp (Eq 4) can be rewritten as follows: 

          
0.509 1.135 0.506

/ 1  337.289 / 3.27690.10853 0.09462
P

R exp T A B C      (6) 

As Eq (6) includes the effect of temperature on starch graft reaction, it provides the production 
of such a starch graft copolymer with a solid background of the influence of processing condition 
on material reactivity in the future. This result is supported by the experimental data and can be 
used to verify the reaction kinetic related to the draft fractions of AM and AMPS on cassava 
starch. 

4. Conclusion 

Based on the represented research, following conclusions can be drawn. First, the developed 
reaction kinetics model for starch-graft-AM-AMPS copolymer can be expressed as: 

          
0.509 1.135 0.506

/ 1  337.289 / 3.27690.10853 0.09462
P

R exp T A B C    
 

Which agrees well with the law of free radical polymerization. The factors of initiator 
concentration [A], monomer concentration [B], starch concentration [C] are positively correlated 



 Rongjin et al., J. Build. Mater. Struct. (2018) 5: 185-196 195 

 

 

with Rp. When the correlation between temperature and Rp is considered specifically, it can be 
expressed with a sigmoid function instead of a linear function. The research also found that the 
synthesis reaction of STAGAA copolymer is characterized by disproportion termination and 
coupling termination. Both terminations coexist and the latter is the dominant reaction format.

 

Acknowledgements  

This research was financially supported by the National Natural Science Foundation of China 
(51202039, 21566008), National Science Foundation of Guangxi (2014GXNSFAA118314) and 
Science and technology development plan of Guangxi (1348011-2). The support from the Civil 
and Environmental Engineering Department at the University of Louisville is also appreciated. 

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