BIOREMEDIATION OF PALM OIL MILL EFLUENT BY USING Spirogyra Sp

Penulis

  • Baihaqi Baihaqi Program Studi Budidaya Perairan. Fakultas Pertanian, Universitas Almuslim
  • Mujibul Rahman Program Studi Budidaya Perairan. Fakultas Pertanian, Universitas Almuslim
  • Ibrahim Ibrahim Program Studi Budidaya Perairan. Fakultas Pertanian, Universitas Almuslim

Abstrak

One type of algae that potentially reduces palm oil mill effluent is Spirogyra sp. Spirogyra sp. Has a wide distribution on the coast of Indonesia and is still underutilized by pond farmers. This study aims to test the efficiency of Spirogyra as a bioremediation agent of palm oil liquid waste and to examine the effect of palm oil liquid waste on the growth of Spirogyra. This research was conducted from March to July 2017. The research design consisted of five treatments, namely treatment A control (0 mL.L-1), B treatment (25 mL.L-1), C treatment (50 mL.L-1) ), Treatment D (75 mL.L-1) and E treatment (100 mL.L-1). Observation parameters include absolute growth, relative growth rate, doubling time and water quality values (pH, temperature, salinity, dissolved oxygen and COD). The stastistic analysis used in this study uses one way ANOVA. The obvious different criteria used in this study was at a 95% confidence level (p <0.05). The results showed that Spirogyra was able to grow well on maintenance media containing oil palm liquid waste with concentration 25 mL.L-1 (treatment B). This can be seen from the absolute growth rate and the relative growth rate better than the treatment of C, D and E.

 

Keywords: Palm Oil Mill Effluent, Spirogyra, Relative Growth Rate, COD

Referensi

Ahmad AL, Ismail S, Bhatia S. 2003. Water recycling from palm oil mill effluent (POME) using membrane technology. Desalination, (157):87–95.

Ahmad AL, Sumathi S, Hameed BH. 2004. Chitosan: a natural biopolymer for the adsorption of residue oil from oily wastewater. Adsorption Science & Technology, 22(1): 75 – 88.

Ali A, Memon MS, Sahato GA, Arbani SN. 2005. Use of Fresh Water Alga Spirogyra ellipsospora Transeau AS Feed Supplement to Broiler Chicks. Hamhard Medicus, 48 (3). 128 – 134.

Apriadi T. 2014. Pemanfaatan Alga Berfilamen (Spirogyra sp.) dan Kijing Lokal (Pilsbryoconcha exilis) Sebagai Agen Bioremediasi Limbah Budidaya Sidat [tesis]. Bogor (ID): Institut Pertanian Bogor.

Apriadi T, Pratiwi TMP, Hariyadi S. 2014. Fitoremediasi limbah budidaya sidat menggunakan filamentous algae (Spirogyra sp.). Depik, 3(1):46-55.

Badan Pusat Statistik Aceh. 2014. Aceh Dalam Angka 2013. Banda Aceh.

Bajpai Pratima. 2015. Management of Pulp and Paper Mill Waste. Springer International Publishing AG. 197 pp.

Belo MM, Nourouzi MM, Abdullah LC, Choong TSY, Koay YS, Keshani S. 2013. POME is treated for removal of color from biologically treated POME in fixed bed column: applying wavelet neural network (WNN).Journal of Hazardous Materials, 262: 106–113.

Chan YJ, Mei-Fong C, Chung-Lim L. 2013. Optimization of palm oil mill effluent treatment in an integrated anaerobic-aerobic bioreactor. Sustainable Environment Research, 23(3): 153-170.

Direktorat Jendral Perkebunan. 2014. Statistik Perkebunan Indonesia Komoditas Kelapa Sawit 2013-2015. Direktorat Jendral Perkebunan Kementrian Pertanian: 68 hal.

Eshaq FS, Ali MN, Mohd MK. 2010. Spirogyra biomass a renewable source for biofuel (bioetanol) production. International Journal Environmental Scence and Technology,2:7045-7054.

Fairolzukry AR, Marsin SM, Wan AWI, Ahmedy AN. 2008. Determination of Polycyclic Aromatic Hydrocarbons in Palm Oil Mill Effluent By Soxhlet Extraction and Gas Chromatography-Flame Ionization Detection. The Malaysian Journal of Analytical Sciences, 12(1): 16-21.

Gupta N, Khan DK, Santra SC. 2008. An assessment of heavy metal contamination in vegetables grown in wastewater-irrigated areas of Titagarh, West Bengal, India. Bulletin of Environmental Contamination.

Hadiyanto, Christwardana M, Soetrisnanto D. 2013. Phytoremediation of Palm Oil Mill Effluent by Using Aquatic Plants and Microalge for Biomass Production. Journal of Environmental Science and Technology: 1-12.

Irvan, Trisakti B, Vincent M, Tandean Y. 2012. Pengolahan Lanjut Limbah Cair Kelapa Sawit Secara Aerobik Menggunakan Effective Microorganism Guna Mengurangi Nilai TSS. Jurnal Teknik Kimia 1(2): 27 – 30.

John RP, Anisha GS, Nampoothiri KM, Pandey A. 2011. Micro and macroalgal biomass: a renewable source for bioethanol. Bioresources and Technology 102: 186-193.

Kamyab H, Fadhil MMD, Keyvanfarb A, Zaimi MA, Talaiekhozania A, Shafaghatb A, Tin CL, Jeng LS, Haidar HI. 2015. Efficiency of Microalgae Chlamydomonas on the Removal of Pollutants from Palm Oil Mill Effluent (POME). Energy Procedia (75): 2400 – 2408.

Li Y, Horsman M, Wu N, Lan CQ, Dubois CN. 2008. Biofuels from Microalgae. Biotechnology Progress,24(4): 815–820.

Mashitah MD, Masitah H, Kamaruddin MY. 2002. Palm oil mill effluent: A potential substrate for cellulase production.The Proceedings of RSCE and 16th SOMChE, Malaysia, 29-216.

Mitchell DS. 1974. Aquatic Vegetation and its use and control. Paris (FR): UNESCO.

Muliari & Zulfahmi I. 2016. Dampak Limbah Cair Kelapa Sawit Terhadap Komunitas Fitoplankton di Sungai Krueng Mane Kabupaten Aceh Utara. Jurnal Perikanan dan Kelautan, 6(2): 137-146.

Park KY, Lim BR, Lee K. 2009. Growth of Microalgae in Diluted Process Water of the Animal Wastewater Treatment Plant. Water Science & Technology, 59(11): 2111–2116.

Pratiwi NTM, Krisanti M, Iswantari A, Ayu IP, Apriadi T. 2015. Serapan Kalsium dan Nutrien Oleh Alga Berfilamen Spirogyra sp. Pada Lama Penyinaran Berbeda. Limnotek, 22 (1): 96 – 105.

Pratiwi NTM, Ayu IP, Nugraha B. 2016. Produktivitas dan Serapan Nutrien Harian Spirogyra sp. dan Hydrodictyon sp. Jurnal Biologi Indonesia 12 (1): 137-143.

Rahardjo PN. 2008. Pengolahan Limbah Cair Pabrik Kelapa Sawit Dengan Bioreaktor Anaerobik Biakan Melekat Dalam Skala Laboratorium (Pengamatan Pengurangan BOD, COD dan TSS Dengan Variabel Waktu Tinggal). Jurnal Teknik Lingkungan: 49 – 57.

Raikar SV, Lima M, Fujita Y. 2001. Effect of temperature, salinity and light intensity on the growth of Glacilaria spp (Glacilariales, Rhodophyta) from Japan, Malaysia and India. Indian Journal of Marine Science, 30: 98-104.

Schulet J, Townsend S, Douglas M, Webster I, Skinner S, Casanova M. 2007. Recommendations For Nutrient Resource Condition Targets For The Daly River. Darwin (AU): Charles Darwin University.

Sheehan J, Dunahay T, Benemann T, Roessler P. 2008. A Look Back at the US Department of Energy's Aquatic Species Program: Biodiesel from Algae. U.S: Knowledge Publications Corporation.

Suresh V, Bhujel RC. 2012. Aquaculture: farming aquatic animals and plants. United Kingdom: Wiley-Blackwell Publishing Company. pp: 338–364.

Taha MR, Ibrahim AH. 2014. COD removal from anaerobically treated palm oil mill effluent (AT-POME) via aerated heterogeneous Fenton process: Optimization study. Journal of Water Process Engineering, (1): 8–16

Vonshak A, Maske H. 1982. Techniques in Bioproductivity and Photosynthesis. Oxford (GB): Pergamon Pr. 66-72 pp.

Wong FPS, Nandong J, Samyudia Y. 2009. Optimised treatment of palm oil mill effluent. International Journal of Environment and Waste Management, 3(3/4): 265-277.

Yulastri, Hazmi A, Desmiarti R. 2013. Aplikasi Plasma Dengan Metoda Dielectric Barrier Discharge (DBD) Untuk Pengolahan Limbah Cair Kelapa Sawit. Jurnal Nasional Teknik Elektro,2(2): 46 – 50 .

Zhang Y, Yan L, Qiao X, Chi L, Niu X, Mei Z. 2008. Integration of biological method and membrane technology in treating palm oil mill effluent. Journal Environmental Science,(20): 558–64.

Zulfahmi I, Muliari, Mawaddah I. 2017. Toksisitas Limbah Cair Kelapa Sawit Terhadap Ikan Nila (Oreochromis niloticus Linneus 1758) dan Ikan Bandeng (Chanos chanos Froskall 1755). Agricola, 7(1): 44-55.

##submission.downloads##

Diterbitkan

2017-11-01