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CHEMICAL ENGINEERING TRANSACTIONS 

VOL. 56, 2017 

A publication of 

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

Guest Editors: Jiří Jaromír Klemeš, Peng Yen Liew, Wai Shin Ho, Jeng Shiun Lim 
Copyright © 2017, AIDIC Servizi S.r.l., 

ISBN 978-88-95608-47-1; ISSN 2283-9216 

Chitosan Flocculation-sedimentation for Harvesting Selected 
Microalgae Species Grown in Monoculture and Mixed 

Cultures 
Yano S. Pradana*,a,b, Yuni Kusumastutia,b, Fadilla N. Rahmaa, Nazrul Effendyc 
aDepartment of Chemical Engineering, Faculty of Engineering, Universitas Gadjah Mada, Jalan Grafika No. 2, Yogyakarta, 
 Indonesia 
bCenter of Advanced Materials and Mineral Processing (CAMMP), Universitas Gadjah Mada, Jalan Grafika No. 2, 
 Yogyakarta, Indonesia 
cDepartment of Nuclear Engineering and Engineering Physics, Faculty of Engineering, Universitas Gadjah Mada, Jalan 
 Grafika No. 2, Yogyakarta, Indonesia 
 yanopradana@ugm.ac.id 

Microalgae is an attractive feedstock for sustainable biodiesel production. The harvesting step of microalgae 
needs technology, which saves energy and time. One of the low cost strategies for addressing this problem is 
the use of flocculation-sedimentation process as an initial step. The aim of the present study is to evaluate the 
flocculation-sedimentation of selected microalgae species grown in monoculture (Nannochloropsis sp.) and 
mixed cultures (South Coast of Yogyakarta) using modified chitosan. The effect of flocculant dosage and 
sedimentation time that might affect the percentage of microalgae cell removal was investigated. Chitosan has 
proved to be highly effective for dewatering of the microalgae, Nannochloropsis sp. and Yogyakarta mixed 
cultures, with the optimum flocculation efficiency reaching over 72.09 % (25 ppm of chitosan dosage; 10 min 
of sedimentation time) and 87.25 % (25 ppm of chitosan dosage; 30 min of sedimentation time) of biomass 
removal. The characteristics of chitosan in term of high positive charge density and long chains allow the 
microalgae to aggregate to form flocs and settle to the bottom due to gravitational effect. 

1. Introduction

The development of renewable energy is gaining attention due to the increasing concern over the depletion of 
petroleum resources (Sathish and Sims, 2012) and the increase in greenhouse gas emissions (Pradana et al., 
2015). Biodiesel, one of the renewable liquid fuels (Huang et al., 2010), has been explored to meet the 
increasing demand for cleaner fuels (Xu et al., 2013). Other than its potential as renewable fuel, It also emits 
less carbon dioxide, sulphur and gaseous pollutants than petroleum diesel (Miao and Wu, 2006). Conventional 
biodiesel is derived from various feedstocks such as palm oil, which uses carbon-based catalyst 
(Raharningrum et al., 2013), rice husk, which uses ash-based catalyst (Chen et al., 2015), jatropha oil 
(Kusumaningtyas et al., 2016), soybean oil, which uses microwave (Encinar et al., 2012) and ultrasound 
systems (Brito et al., 2012), used cooking oil (Kawentar and Budiman, 2013), and palm fatty acid distillate, 
which uses char-based (Hidayat et al., 2015) and sulphated zirconia catalysts (Sawitri et al., 2016). However, 
large plantation area is required to produce biodiesel from conventional biomasses. 
Recently, the utilisation of microalgae for sustainable biofuels production is of interest because of the 
escalating price of fossil fuels (Lei et al., 2015). Microalgae are photosynthetic microorganisms which require 
light, sugar, CO2, nitrogen (N), phosphorus (P), and potassium (K) to grow to produce lipids, proteins and 
carbohydrates in large amounts over short periods of time (Demirbas, 2011). These photosynthetic 
microorganisms have been considered as a potential renewable fuel source (Nafis et al., 2015). They can be 
used as raw material for the production of biodiesel, biomethane, bioethanol, biohydrogen and biobutanol. 
These biofuels are viewed as the most promising alternatives to fossil fuels (Rawat et al., 2011) and are able 
to provide up to 25 % of global energy demand (Christenson and Sims, 2011). Microalgae have a number of 
advantages including faster growth rate (Minowa et al., 1995), and higher photosynthetic efficiency (Dote et 

 

   

DOI: 10.3303/CET1756259

 

 
 
 
 
 
 
 
 
 
 
 

 
 
 
 
 
 
 
 
 
 
 
 

 
 
 
 
 
 
 

 

 

 

Please cite this article as: Pradana Y.S., Kusumastuti Y., Rahma F.N. , Effendy N., 2017, Chitosan flocculation-sedimentation for harvesting 
selected  microalgae species grown in monoculture and mixed cultures, Chemical Engineering Transactions, 56, 1549-1554  
DOI:10.3303/CET1756259   

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al., 1994) and biomass production compared to other energy crops (Milne et al., 1990). Its cultivation process 
can be integrated with CO2 removal from industrial flue gases and wastewater treatment process. Microalgae 
have the ability to assimilate nutrients and metals from wastewater, which plays an important remediation role 
during tertiary wastewater treatment phase (Barros et al., 2015). Nannochloropsis sp., one of prospective 
microalgae species grown in monoculture, is a widely available strain for commercial application. It exhibits 
great potentials as the future biodiesel feedstock due to its high growth rate and oil contents (Mitra et al., 
2015). The other prospective microalgae species for biodiesel production is mixed cultures strain, such as 
mixed cultures microalgae from South Coast of Yogyakarta. The identified microalgae species of mixed 
cultures from South Coast of Yogyakarta are Cyclotella polymorpha and Chlamydomonas sp., which produce 
high yield from oil extraction process. 
Several studies have been done on to recover microalgae from the growth medium during the harvesting step. 
Most microalgae species have a cell diameter of 1 - 30 µm and a low biomass concentration in culture of 
between 0.5 - 2 g/L (Xu et al., 2013). Microalgae slurry from the harvesting process must be dewatered prior 
to the oil extraction process. Efficient dewatering of biomass from cultivation medium is essential for the mass 
production of biofuels from microalgae. Traditional dewatering methods, such as centrifugation (Gerardo et al., 
2015), filtration (Danquah et al., 2009) and electrocoagulation (Lee et al., 2013), require high energy input. A 
case study conducted by Chisti (2007) reported that the cost of the recovery process contributed about 50 % 
to the total cost of the biofuels production. These methods are too expensive for producing low-cost biodiesel. 
Flocculation, followed by sedimentation step, is a well-established method for removing suspended solids in 
water (Bratby, 2006), but is less developed for harvesting microalgae. The cell surface of microalgae has 
negative charge, which prevents them from adhering to each other by van der Waals forces (Ndikubwimana et 
al., 2015). The strategy is to use cationic flocculants to form large aggregates of microalgae that are heavy 
enough for sedimentation. Commonly used cationic flocculants are salts of multivalent metal ions (Gorin et al., 
2015), such as ferric chloride and aluminium sulphate. The use of these inorganic flocculants requires low 
energy but can contaminate the harvested microalgae (Farid et al., 2013). The wastewater from the harvesting 
process cannot be recycled back to the cultivation stage. Cationic polymers are other widely used but are 
generally more expensive than metal salts. Bioflocculation is another alternative method for making flocs using 
chemicals produced by acceptable co-culture microorganism (Chatsungnoen and Chisti, 2016). 
Chitosan is biopolymer obtained by deacetylation of chitin. It has been proven as an effective cationic 
flocculant for microalgae (Divakaran and Pillai, 2002). The properties of chitosan, including its cationic 
behaviour and molecular weight (Li et al., 2013), can assist in coagulation (particle aggregation induced by 
electrolyte addition) and flocculation (aggregation resulting from the linking of several particles by a polymer 
chain) processes. Unlike metal salts, chitosan is non-toxic, biodegradable and renewable (Renault et al., 
2009). It causes little problem in the downstream processes for producing biofuels and recycling back the 
growth medium (Ahmad et al., 2011). The effectiveness of the flocculation step can be improved by modifying 
chitosan into modified chitosan, to have larger surface area and higher adsorption capacity (Zhang et el., 
2016). 
The aim of the study is to evaluate the flocculation-sedimentation of selected microalgae species grown in 
monoculture (Nannochloropsis sp.) and mixed cultures (South Coast of Yogyakarta) using chitosan. The 
effects of flocculants dosage and sedimentation time on the percentage of microalgae cell removal were 
investigated. 

2. Methods 

2.1 Materials 

Monoculture-grown microalga used in this study was Nannochloropsis sp. obtained from Situbondo, East 
Java, Indonesia. Stock of mixed cultures microalgae was isolated from South Coast of Yogyakarta, Glagah, 
Yogyakarta, Indonesia. They were then cultivated in Biotechnology Laboratory, Faculty of Biology, Universitas 
Gadjah Mada, Yogyakarta. The flocculants used in this study was chitosan. 

2.2 Experimental 

The chitosan was solubilised in a 0.1 M HCL solution and mixed with a stirrer at 100 rpm for 30 min to obtain 1 
mg/mL of stock solution. The jar test was used to optimise the flocculation-sedimentation process and study 
the effect of flocculants dosage and sedimentation time. This study consisted of batch experiments, which 
used beaker glass, heater and stirrer. The beaker was filled with 50 mL of 3.36 g/L microalgae culture for each 
test run. The contents of each flask were simultaneously stirred at the same speed. The samples were mixed 
at 250 rpm for 1 min and then flocculated at 100 rpm for 5 min with different concentrations of chitosan (0 – 
125 ppm) at room temperature. After flocculation, the samples were left to settle at varying sedimentation time 
(3 - 60 min). After sedimentation, 1 mL of each sample was collected from the middle of each respective 

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beaker. The concentration of biomass was measured using spectrophotometer at a wavelength of 682 nm 
(Farid et al., 2013). The percentage of cell removed was calculated using Eq(1). 

% cell removed =
(Iblank − Isample)

Iblank
 ×  100 % (1) 

where Iblank is the absorbance intensity of the reference culture without chitosan and Isample is the absorbance 
intensity of the sample after the flocculation-sedimentation process. 

3. Results and discussion 

3.1 Effect of chitosan dosage 

Figure 1 shows the effect of chitosan dosage on the removal of microalgae cells at sedimentation time of 60 
min. The highest percentage of mixed cultures microalgae cell removal was obtained at low concentration of 
chitosan. 88.79 % of cell removal was obtained at chitosan concentration of 25 ppm. After this point, the 
increase in chitosan concentration resulted in the percentage reduction of cell removal. The highest 
percentage of Nannochloropsis sp. cell removal was 73.03 %, which was obtained at chitosan concentration 
of 62.5 ppm. However, at chitosan concentration of 25 ppm, the resulted Nannochloropsis sp. cell removal of 
72.40 %, is considered as an optimum removal percentage due to the insignificant increase in cell removal 
percentage as chitosan dosage increases.  

 

Figure 1: Effect of chitosan dosage on the removal of microalgae cells 

The decrease in the cell removal of mixed cultures microalgae and constant cell removal of Nannochloropsis 
sp. during the harvesting process as chitosan concentration increased to more than the optimum point can be 
explained based on its properties mechanisms. The likely mechanisms involved in this flocculation-
sedimentation process are adsorption and charge neutralisation. The positively charged chitosan is strongly 
attracted the negatively charged microalgae cells, which promotes flocculation by neutralising the charges 
(Ahmad et al., 2011). Chitosan continually attracted and destabilised the cells to form large aggregates at 
lower concentrations of chitosan. When the chitosan concentrations became higher than the optimum 
concentration, the excess cationic charges led to the restabilisation of the cells, which reduced the efficiency 
of the mechanism and hindered the formation of flocs. 

3.2 Effect of sedimentation time 

Generally, the sedimentation time depends on the floc size. An increase in floc size increases of free settling 
velocity driven by gravitational force which in turn, decreases the sedimentation time. Chitosan promotes 
faster aggregation of cells through charge neutralisation, which allows aggregated particle formation for faster 
settling. 
Figure 2 shows the effect of sedimentation time on the removal of microalgae cells by chitosan at 
concentrations of 0 ppm (no flocculant), 25 ppm (low concentration) and 100 ppm (high concentration). The 

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flocculation-sedimentation of mixed cultures microalgae using chitosan interacted significantly with microalgae 
to form flocs for sedimentation time of less than 30 min. After 30 min, the liquid and solid had become nearly 
neutrally charged, causing only few flocs to form, resulting in fairly constant cell removal percentage. The 
optimum cell removal obtained was 87.25 % at the sedimentation time of 30 min and chitosan concentration of 
25 ppm. Nannochloropsis sp. flocculation needed shorter time for sedimentation than mixed cultures. At 10 
min of sedimentation time, the cell has been removed optimally due to the insignificant floc formation after this 
time. The optimum percentage of Nannochloropsis sp. cell removed was 72.09 % and obtained at 10 min of 
sedimentation time and 25 ppm of chitosan concentration. 
 

 

Figure 2: Effect of sedimentation time on the removal of microalgae cells 

4. Conclusions 

Chitosan has proved to be highly effective for dewatering of the microalgae, Nannochloropsis sp. and 
Yogyakarta mixed cultures, with the optimum flocculation efficiency reaching over 72.09 % (25 ppm of 
chitosan dosage; 10 min of sedimentation time) and 87.25 % (25 ppm of chitosan dosage; 30 min of 
sedimentation time) of cell removal. The characteristics of chitosan in term of high positive charge density and 
long chains allow the microalgae to aggregate to form flocs and settle to the bottom due to gravitational effect. 
This flocculation-sedimentation process saves energy and time for dewatering processes. 

Acknowledgments  

The authors deeply acknowledge Prof. Arief Budiman as research advisor. The authors are also grateful to 
Devi Asti Prabasiwi and Arina Nur Fitri Fadhila for providing analytical assistance. The authors are thankful to 
Faculty of Engineering, Universitas Gadjah Mada for financial support through Research Grant No. 
2855/H1.17/PL/2015.  

References  

Ahmad A.L., Mat Yasin N.H., Derek C.J.C., Lim J.K., 2011, Optimization of microalgae coagulation process 
using chitosan, Chemical Engineering Journal 173, 879-882. 

Barros A.I., Goncalves A.L., Simoes M., Pires J.C.M., 2015, Harvesting techniques applied to microalgae: A 
review, Renewable and Sustainable Energy Reviews 41, 1489-1500. 

Bratby J., 2006, Coagulation and Flocculation in Water and Wastewater Treatment, 2nd Ed., IWA Publishing, 
Seattle, United States. 

1552



Brito J.Q.A., Silva C.S., Almeida J.S., Korn M.G.A., Korn M., Teixeira L.S.G., 2012, Ultrasound-assisted 
synthesis of ethyl esters from soybean oil via homogeneous catalysis, Fuel Processing Technology 95, 33-
36. 

Chen G., Shan R., Shi J., Yan B., 2015, Transesterification of palm oil to biodiesel using rice husk ash-based 
catalyst, Fuel Processing Technology 133, 8-13. 

Chatsungnoen T., Chisti Y., Continuous flocculation-sedimentation for harvesting Nannochloropsis salina 
biomass, Journal of Biotechnology 222, 94-103. 

Chisti Y., 2007, Biodiesel from microalgae, Biotechnology Advances 25, 294-306. 
Christenson L., Sims R., 2011, Production and harvesting of microalgae for wastewater treatment, biofuels 

and bioproducts, Biotechnology Advances 29, 686-702. 
Danquah M.K., Ang L., Uduman N., Moheimani N., Forde, G.M., 2009, Dewatering of microalgal culture for 

biodiesel production: exploring polymer flocculation and tangential flow filtration, Journal of Chemical 
Technology and Biotechnology 84, 1078–1083. 

Demirbas M.F., 2011, Biofuels from algae for sustainable development, Applied Energy 88, 3473-3480. 
Divakaran R., Pillai V.N.S., 2002, Flocculation of algae using chitosan, Journal of Applied Phycology 14, 419–

422. 
Dote Y., Sawayama S., Inoue S., Minowa T., Yokoyama S., 1994, Recovery of liquid fuel from hydrocarbon-

rich microalgae by thermochemical liquefaction, Fuel 73, 1855–1857. 
Encinar J.M., Gonzalez J.F., Martinez G., Sanchez N., Pardal A., 2012, Soybean oil transesterification by the 

use of a microwave flow system, Fuel 95, 386-393. 
Farid M.S., Shariati A., Badakhshan A., Anvaripour B., 2013, Using nano-chitosan for harvesting microalga 

Nannochloropsis sp., Bioresource Technology 131, 555–559. 
Gerardo M.L., Van Den Hende S., Vervaeren H., Coward T., Skill S.C., 2015, Harvesting of microalgae within 

a biorefinery approach: a review of the developments and case studies from pilot-plants, Algal Research 
11, 248–262. 

Gorin K.V., Sergeeva Y.E., Butylin V.V., Komova A.V., Pojidaev V.M., Badranova G.U., Shapovalova A.A., 
Konova I.A., Gotovtsev P.M., 2015, Methods coagulation/flocculation and flocculation with ballast agent for 
effective harvesting of microalgae, Bioresource Technology 193, 178–184. 

Hidayat A., Rochmadi Wijaya, K., Nurdiawati A., Kurniawan W., Hinode H., Yoshikawaa K., Budiman A., 2015, 
Esterification of palm fatty acid distillate with high amount of free fatty acids using coconut shell char based 
catalyst, Energy Procedia 75, 969-974. 

Huang G., Chen F., We, D., Zhang X., Chen G., 2010, Biodiesel production by microalgal biotechnology, 
Applied Energy 87, 38-46. 

Kawentar W.A., Budiman A., 2013, Synthesis of biodiesel from second-used cooking oil, Energy Procedia 32, 
190-199. 

Kusumaningtyas R.D., Aji I.N., Hadiyanto H., Budiman A., 2016, Application pf tin (II) chloride catalyst for high 
FFA jatropha oil esterification in continuous reactive distillation column, Bulletin of Chemical Reaction 
Engineering and Catalyst 11 (1), 66-74. 

Lee A.K., Lewis D.M., Ashman P.J., 2013, Harvesting of marine microalgae by electroflocculation: the 
energetics, plant design, and economics, Applied Energy 108, 45–53. 

Lei X., Chen Y., Shao Z., Chen Z., Li Y., Zhu H., Zhang J., Zheng W., Zheng T., 2015, Effective harvesting of 
the microalgae Chlorella vulgaris via flocculation-flotation with bioflocculant, Bioresource Technology 198, 
922–925. 

Li J., Jiao S., Zhong L., Pan J., Ma Q., 2013, Optimizing coagulation and flocculation process for kaolinite 
suspension with chitosan, Colloids and Surfaces A: Physicochemical and Engineering Aspects 428, 100-
110. 

Miao X., Wu Q., 2006, Biodiesel production from heterotrophic microalgal oil, Bioresource Technology 97, 
841–846. 

Milne T.A., Evans R.J., Nagle N., 1990, Catalytic conversion of microalgae and vegetable oils to premium 
gasoline, with shape-selective zeolites, Biomass 21, 219–232. 

Minowa T., Yokoya S.Y., Kishimoto M., Okakura T., 1995, Oil production from algae cells of Dunaliella 
Tereiolata by direct thermochemical liquefaction, Fuel 74, 1731–1738. 

Mitra M., Patidar S.K., Mishra S., 2015, Integrated process of two stage cultivation of Nannochloropsis sp. for 
netraceutically valuable eicosapentaenoic acid along with biodiesel, Bioresource Technology 193, 363–
369. 

Nafis G.A., Mumpuni, P.Y., Indarto, Budiman A., 2015, Combination pulsed electric field with ethanol solvent 
for Nannochloropsis sp. Extraction, AIP Conference Proceeding 1699, DOI: 10.1063/1.4938306. 

1553



Ndikubwimana T., Zeng X., He N., Xiao Z., Xie Y., Chang J.S., Lin L., Lu Y., 2015, Microalgae biomass 
harvesting by bioflocculation-interpretation by classical DLVO theory, Biochemical Engineering Journal 
101, 160–167. 

Pradana Y.S., Budiman A., 2015, Bio-syngas derived from Indonesian oil palm empty fruit bunch (EFB) using 
middle-scale gasification, Journal of Engineering Science and Technology 10 (8), 1-8. 

Raharningrum F., Pradana Y.S., Hidayat A., Budiman A., 2013, Synthesis of biodiesel using carbon based-
solid catalyst, Proceeding of the International Seminar on Chemical Engineering, Bio Energy, Chemical 
and Materials, 10-11 October 2013, Bandung, Indonesia, 77-84. 

Rawat I., Ranjith R.K., Mutanda T., Bux F., 2011, Dual role of microalgae: phycoremediation of domestic 
wastewater and biomass production for sustainable biofuels production, Applied Energy 88, 3411–3424. 

Renault F., Sancey B., Badot P.M., Crini G., 2009, Chitosan for coagulation/ flocculation processes – an eco-
friendly approach, European Polymer Journal 45, 1337–1348. 

Satish A., Sims R.C., 2012, Biodiesel from mixed culture algae via a wet lipid extraction procedure, 
Bioresource Technology 118, 643–647. 

Sawitri D.R., Sutijan, Budiman A., 2016, Kinetics study of free fatty acids esterification for biodiesel production 
from palm fatty acid distillate catalysed by sulphated zirconia, ARPN Journal of Engineering and Applied 
Sciences 11 (16), 9951-9957. 

Xu Y., Purton S., Baganz F., 2013, Chitosan flocculation to aid the harvesting of the microalga Chlorella 
sorokiniana, Bioresource Technology 129, 296–301. 

Zhang L., Zeng Y., Cheng Z., 2016, Removal of heavy metal ions using chitosan and modified chitosan: A 
Review, Journal of Molecular Liquids 214, 175-191. 

1554