7 
 

Computational and Experimental Research  
in Materials and Renewable Energy (CERiMRE)         
Volume 1, Issue 1, page 7-11 
 
 
 

Submitted  : August 28, 2018  
Accepted  : October 2, 2018 
Online  : November 10, 2018 
doi : 10.19184/cerimre.v1i1.19543 

Characterization of Carbon Derived from Water Hyacinth as a 
Renewable Energy Sources  

 

Rani Kusumaningtyas
1
, Wenny Maulina

1,a
, Supriyadi

1 
 

1
Department of Physics, Faculty of Mathematics and Natural Sciences, University of Jember, 

Jember, Jalan Kalimantan No 37 Jember 68121, Indonesia 

a
wenny@unej.ac.id 

 
Abstract. An alternative renewable energy sources, such as biomass, can be produced using the 
combustion process inside the furnace. In this work, carbon derived from water hyacinth be produced 
through carbonization process. The carbonization of water hyacinth was carried out at different 
temperature i.e. 400°C, 500°C and 600°C and subsequently analyzed with the SEM-EDX to determine 
the microstructure and atomic percentage of present elements. While the FTIR analysis was conducted to 
qualitatively verify the surface functional groups of carbon. The results of SEM-EDX analysis showed that 
the pores began to form at a carbonization temperature of 600°C and carbon content increased with 
increased temperature of carbonization process. FTIR analysis results showed that the functional groups 
in the carbon derived from water hyacinth had an absorption pattern with OH, C-H, C-O, and C=C bonds. 

Keywords: Renewable Energy Sources, Water Hyacinth, SEM-EDX, FTIR 

Introduction 

Improvement of economic activity causes an increase in world energy demand. The use of 
renewable energy is increasingly needed to substitute energy from fossil fuels. The projected 
global energy demand in 2040 will be supplied by 74% from fossil fuels and 26% from 
renewable materials, while the contribution of bioenergy from agricultural waste biomass will be 
10.4% [1]. The advantage of using energy from biomass sources are produces environmentally 
friendly CO2 emissions (zero carbon footprint) and can be regenerated by plants again, so it 
doesn't cause increase emission of greenhouse gases [2]. Thus, renewable biomass plays a 
significant role in the energy supply in the world, especially in Indonesia. 

 

Indonesia is a country that has abundant biodiversity so that it can potentially be exploited. One 
of the most common biodiversity found in water areas is water hyacinth (Eichhornia crassipes). 
Water hyacinth is considered a highly invasive aquatic weed, infecting dam, lakes and irrigation 
channels. One major problem associated with water hyacinth is its rapid growth rate. It can 
easily adapt and compete with other aquatic plants causing a major threat to the aquatic 
environment. When not managed and controlled, these plants will cause blockage in bodies of 
water. Although water hyacinth is seen as a weed and is responsible for many environmental 
and health problems, much research has been done in order to find useful applications for these 
plant [3]. One of the application which is can be used as a biomass sources.  
 
The renewable biomass generally includes three main components: cellulose, hemicellulose, 
and lignin; and cellulose and hemicellulose make up approximately 70% of the entire biomass 
[4]. Water hyacinth can potentially be a resource due its high carbohydrate content (18% 
cellulose, 50% hemicellulose) [5]. Charcoal is a type of black carbon produced from 
carbonization process when biomass is heated in a closed container with little or no available air 
[6,7]. The carbonization is a process in which non-carbon compounds are removed so that 



  

 

 

 

 

8 
 

Computational and Experimental Research  
in Materials and Renewable Energy (CERiMRE)         
Volume 1, Issue 1, page 7-11 
 
 
 

Submitted  : August 28, 2018  
Accepted  : October 2, 2018 
Online  : November 10, 2018 
doi : 10.19184/cerimre.v1i1.19543 

organic cellulose can be decomposed into carbon. Determination of the exact carbonization 
temperature determines the quality of the charcoal. Here, different temperature in carbonization 
process are evaluated to clarify carbon derived from water hyacinth according to spectroscopy 
and microstructure analysis. 

Material and Methods 

The water hyacinth used in charcoal production was collected from one of the rivers in the 
Province of Lumajang in East Java. The water hyacinth is taken part of the stem was washed to 
removed adhering dirt and then dried under the sun. Once the sample dry, biomass cut into 
small pieces and was entered in the furnace, then the temperature of heating was set. The 
carbonization temperature is adjusted (according to variations at 400°C, 500°C, and 600°C) with 
a heating time of 1 hours each. After this carbonization process, sample crush until smooth at 
size of 200 mesh. 
 
Based on the treatment of temperature at carbonization process, the following samples were 
obtained in this study: 
Sample A1: water hyacinth charcoal at a carbonization temperature of 400°C 
Sample A2: water hyacinth charcoal at a carbonization temperature of 500°C 
Sample A3: water hyacinth charcoal at a carbonization temperature of 600°C 
Furthermore, sample was characterized using scanning electron microscopy-energy dispersive 
x-ray (SEM-EDX) and Fourier Transform Infrared (FTIR). SEM-EDX to determine the 
microstructure and atomic percentage of present elements in the sample. While the FTIR 
analysis was conducted to qualitatively verify the surface functional groups of carbon. 

Results and Discussion 

Characterization of SEM-EDX 
SEM was used to identify the surface morphology of carbon derived from water hyacinth. The 
surface morphology of carbon derived from water hyacinth with variations in carbonization 
temperature of 400°C, 500°C, and 600°C, can be seen in Figure 1. Sample A1 and A2 with 
carbonization temperature are 400°C and 500°C, respectively, shown nonporous structure of 
carbon. While sample A3 at carbonization temperature 600°C shown porous structure of carbon 
with diameter of pore in the amount of 0.572 µm. Carbonization causes the components of the 
material to degrade to produce gases (CO, CO2, hydrogen and methane), liquid products (tar, 
hydrocarbons, water) and solid products, namely charcoal. The formation of pores at high 
temperatures were due to the evaporation of volatile matter from the materials at the 
carbonization process. The carbonization process causes the breakdown of carbon chains and 
will be more optimal with an increase in temperature [8]. 
 

In this study, characterization of EDX aims to determine the atomic percentage of present 
elements in carbon derived from water hyacinth. Table 1 shown the elements content of carbon 
derived from water hyacinth with various temperature. The EDX results shown the percentage 
of carbon elements present in all the sample is above 80%. The percentage of carbon elements 
in sample A1, A2, and A3 were 82.70%, 87.76%, and 89.37%, respectively. It can be seen that 
the higher of the carbonization temperature causes the greater of the carbon content. This result 
accordance with the carbonization process which is explain that at temperatures of 310°C - 
510°C there is an increase in the amount of CO, CH4, and H2 and tar whereas a decrease in the 



  

 

 

 

 

9 
 

Computational and Experimental Research  
in Materials and Renewable Energy (CERiMRE)         
Volume 1, Issue 1, page 7-11 
 
 
 

Submitted  : August 28, 2018  
Accepted  : October 2, 2018 
Online  : November 10, 2018 
doi : 10.19184/cerimre.v1i1.19543 

amount of pyrolignic acid and CO2. Meanwhile at a carbonization temperature of 500°C - 
1000°C there is an increase in carbon content [9].  

 

                
(a)            (b)     

  

 
(c) 

Figure 1. The surface morphology of carbon derived from water hyacinth at carbonization 
temperature (a) 400°C (sample A1), (b) 500°C (sample A2), and (c) 600°C (sample A3), 

respectively  
 

Table 1. The elements content of carbon derived from water hyacinth at various temperature 

Element 
wt% 

A1 A2 A3 

C 82.70 87.76 89.37 
O 14.47 7.10 7.58 
Na - - - 
Mg 0.41 0.31 0.81 
Al 0.16 - - 
Si 0.37 - - 
S 0.14 - - 
Cl 0.47 2.25 0.99 
K 0.48 2.09 0.97 

Ca 0.50 0.50 0.28 
Zr 0.29 - - 



  

 

 

 

 

10 
 

Computational and Experimental Research  
in Materials and Renewable Energy (CERiMRE)         
Volume 1, Issue 1, page 7-11 
 
 
 

Submitted  : August 28, 2018  
Accepted  : October 2, 2018 
Online  : November 10, 2018 
doi : 10.19184/cerimre.v1i1.19543 

Characterization of FTIR 

 
Figure 2. FTIR spectra of carbon derived from water hyacinth at carbonization temperature 

400°C (sample A1), 500°C (sample A2), and 600°C (sample A3) 
 

Figure 2 shown the surface functional groups of carbon derived from water hyacinth at a various 
carbonization temperature. The spectral pattern of the FTIR results in sample A1 shows that 
there is a vibration of hydroxyl groups (O-H stretching) at the wavenumber 3324 cm

-1
. The 

asymmetric C-H stretching at the wavenumber 2925 cm
-1
. The band at around 1605 cm

-1 

indicates a C=C stretching vibration of aromatic compounds. The asymmetric C-H bending 
vibration mode of hydrocarbon aliphatic bond at the wavelength of 1414 cm

-1
. Whereas, a 

symmetric C-H bending group at the wavenumber of 1316 cm
-1
. C-O stretching vibration 

observed at around 1076 cm
-1
. A weak band at the wavenumber 873 cm

-1 
was describe to C-C 

stretching vibration. From this results shown that carbon derived from water hyacinth at 
carbonization temperature of 400°C has a little amount of carbon elements. 
 
In a sample A2 with carbonization temperature of 500°C, the band at around 3324 cm

-1
 could be 

ascribed to hydroxyl groups (O-H stretching). Band observed appearing at around 1585 cm
-1
 for 

aromatic compounds (C=C stretching). The vibration of the asymmetric C-H bending at the 
wavenumber 1409 cm

-1
. C-O stretching vibration observed at around 1069 cm

-1
.The band at 

wavenumber 875 cm
-1
  for C-C stretching vibration. The peak of the absorption band in FTIR 

spectra sample A2 was lower than sample A1. This occurs because at a temperature of 500°C 
the absorbance decreases of aromatic compounds and increases in the carbon element which 
is formed based on the increase in the absorbance value of the C-C stretching vibration group. 
 
The functional group in sample A3 looks alike in sample A2. Vibration group of O-H stretching, 
C=C stretching, asymmetric C-H bending, C-O stretching, and C-C stretching were observed at 
a wavenumber 3338 cm

-1
, 1571 cm

-1
, 1413 cm

-1
, 1039 cm

-1
, and 875 cm

-1
, respectively. 

Spectroscopy analyzed of carbon derived from water hyacinth at a various carbonization 
temperature shown that the carbonization process with higher temperatures will result in 



  

 

 

 

 

11 
 

Computational and Experimental Research  
in Materials and Renewable Energy (CERiMRE)         
Volume 1, Issue 1, page 7-11 
 
 
 

Submitted  : August 28, 2018  
Accepted  : October 2, 2018 
Online  : November 10, 2018 
doi : 10.19184/cerimre.v1i1.19543 

changed in functional groups, shifted in wavenumbers, reduced absorption rates and formed a 
new compounds. 

Conclusions 

SEM patterns reveal the porous structure of carbon derived from water hyacinth occurs at 
carbonization temperature 600. While, temperature 400 and 500 not reveal the porous 
materials. The carbonization process of water hyacinth at various temperature (400, 500, and 
600) indicates that an increase in carbonization temperature causes an increase in the 
percentage of carbon elements. The resulting sequences were 82.70%, 87.43%, and 89.37%. 
The FTIR peaks shown OH, C-H, C-O, and C=C bonds. The atomic groups and structure 
present are aromatic, aliphatic, tertiary and secondary hydroxyl structures. The presence of 
aliphatic and aromatic hydrocarbons in carbon means that it contains fats and oils that are 
related to butane or isobutene, making it easier to burn or heat up. Likewise, the presence of 
hydroxyl groups means that there is an alcohol present which could contribute to higher 
flammability of substances. Hence, water hyacinth is considered a suitable raw material as a 
renewable energy sources. 

References 

[1] International Energy Agency, World Energy Outlook 2018, executive Summary, 
www.iea.org/weo/, accessed on 16 August 2019. 

[2] A Kadiyala, R Kommalapati and Z Huque, 2016, Sustainability, volume 8, page 1181-
1192. 

[3] N P Carnaje, R B Talagon, J P Peralta, K Shah and J Paz-Ferreiro, 2018, PLOS ONE, 
volume 13(11), page 1-14. 

[4] X Shen, R R Kommalapati and Z Huque, 2015, Sustainability, volume 7, page 12974-
12987. 

[5] H A Fileto-Perez, J G Rutiaga-Quinones, C N Aguilar-Gonzales, J B Paez, J Lopez and O 
M Rutiaga-Quinones, 2013, BioResources, volume 8(4), page 5340-5348. 

[6] L M Deem and S E Crow, 2017, Reference Module in Earth Systems and Environmental 
Sciences, page 1-5. 

[7] O D Nartey and B Zhao, 2014, Advances in Materials Science and Engineering, page 1-
12. 

[8] H Nurdiansah and D Susanti, 2013, Jurnal Teknik POMITS, volume 2(1), page 2301-
9271. 

[9] Desi, A Suharman and R Vinsiah, 2015, Prosiding SEMIRATA, page 294-303. 

 

 

http://www.iea.org/weo/