CARBON ABSORPTION CAPABILITY THE WATERS IN THE RUPAT STRAIT OF RIAU PROVINCE

Siti Ramlah Hasibuan, Rifardi Rifardi, Sampe Harahap

Abstract


The purpose of this study isto analyze the uptake of carbon in polluted waters and unpolluted based on suspended sediment concentration in Rupat Strait. This study used multivariate statistics of Principle Component Analysis (PCA) and regression analysis to clarity the relationship between suspended sediments and primary productivity with carbon uptake. The results indicate that carbon uptake in polluted waters range from 0.023-0.026 tonC/m2/year and unpolluted ranged from 0.034- 0.038 tonC/m2/year. PCA analysis shows that the two main axes (F1 and F2) can represent 82.26% of the total diversity of distribution, indicate the contribution of F1 is 70.08% and F2 is 12.18%. The relationship between total suspended sediment with carbon uptake clearly show if total suspended sediment is higher, the carbon uptake will be lower. On the other hand the relationship between primary productivity and carbon uptake, indicate abundance of primary productivity, the carbon uptake will behigher. 

Keywords


Serapan CO2; Selat Rupat; TSS; Tercemar; Tidak tercemar

Full Text:

PDF

References


Afdal. 2007. Siklus Karbon dan Karbodioksida di Atmosfer dan Samudera. Oseana 32 (2): 29-

Arvianto, S.E, A. Satriadi dan G.

Handoyo. 2016. Pengaruh Arus Terhadap Sebaran Sedimen Tersuspensi di Muara Sungai

SC (tonC/m2/tahun)

Siti Ramlah, Berkala Perikanan Terubuk, Vol 46. No.2. Juli (2018) Hal. 59– 65

Silugonggo Kabupaten Pati. Jurnal Oseanografi. 5(1): 116 – 125.

Behrenfeld MJ, Falkowski PG. 1997. A comumers guide to primary productivity models. Limnol.

Oceanogr. 42: 1479-1491. Bengen, D. G. 1998. Sinopsis Analisis

Statistik Multivariabel/Multidimensi. Program Pascasarjana. IPB. Bogor.

BPTPM (Badan Pelayanan Terpadu dan Penanaman Modal Kota Dumai). 2012. Potensi dan peluang investasi Kota Dumai.

Dumai (ID): Dumai Indonesia. Chen H. 2017. Simplified, Rapid, and Inexpensive Estimation Of Water Primaryproductivity Based On Chlorophyll Fluorescence Parameter Fo. Journal Of Plant Physiology,

: 128–135.

Darussalam, D. 2011. Pendugaan Potensi

Serapan Karbon Pada Tegakan Pinus di KPH Cianjur Perum Perhutani Unit III Jawa Barat dan Banten (skripsi). Institut Pertanian Bogor. Bogor (tidak diterbitkan).

Duan, W.L., B. He, K. Takara, P.P. Luo, D. Nover dan M.C. Hu. 2015. Modeling Suspended Sediment Sources and Transport in The Ishikari River Basin, Japan, Using SPARROW. Hydrol. Earth Syst. SCI. 19: 1293–1306. Fitriya N., H. Surbakti dan R. Aryawati. 2011. Pola Sebaran Fitoplankton Serta Klorofil-A pada Bulan November di Perairan Tambelan, Laut Natuna. Maspari Journal 03 (1):

-08.

Legendre, L. dan P. Legendre. 1983.

Numerical Ecology. Elsevier Scientific Publishing Company. 419 p.

Rifardi. 2011. Lingkungan Pengendapan Perairan Selatan Estuaria Bagan dan Sekitarnya Pantai Timur Sumatera Indonesia. Jurnal

Rifardi.

Ilmu Lingkungan.

Analisis Degradasi

Sumberdaya Perairan Selat Rupat Pantai Timur Sumatera Berdasarkan Aspek Sedimentasi Sebagai Dasar dalam Perencanaan Pembangunan dan Pengelolaan Wilayah Pesisir Kota Dumai Provinsi Riau. Penelitian Fundamental Universitas Riau.

N., A. Mulyanto dan S. Sehabudin. 2013. Pengaruh Kelimpahan Sel Mikroalgae Air Tawar (Chlorella sp.) Terhadap Penambatan Karbondioksida. Jurnal Teknologi Lingkungan. 14(1): 1- 6.

Sopiah

Standar Nasional Indonesia (SNI). 2004. Air dan Air Limbah – Bagian 3: Cara Uji Padatan Tersuspensi

Total (TSS) Secara Gravimetri. Tanjung, A. 2014. Rancangan Percobaan. Tantaramesta Asosiasi Direktori Indonesia,

Bandung. 127 hal.

Zhang Y, Li Zhang dan W.J. Mitscha.

Predicting River Aquatic Productivity and Dissolved Oxygen Before and After Dam Removal. Ecological Engineering, 72 :125–137.




DOI: http://dx.doi.org/10.31258/terubuk.46.2.59-65

Refbacks

  • There are currently no refbacks.


Copyright (c) 2019 Berkala Perikanan Terubuk