The use of chlorine in agriculture and settlements increases and impacts surrounding waters, such as watersheds:  The land area is a unit with rivers and tributaries that function to accommodate, store and distribute water from rainfall to the sea naturally.  The environmental condition of the Tondano watershed is important to study in terms of chlorine distribution, considering that residential and agricultural activities in the watershed can cause residues in the aquatic environment, which harm the environment, especially phytoplankton. This study aims to examine the concentration of chlorine and its impact on the phytoplankton diversity in the Tondano watershed, North Sulawesi, Indonesia. Using the composite method, water quality sampling to calculate chlorine concentration was carried out at 17 river locations using the composite method, while six river stations represented phytoplankton sampling. Chlorine concentration was measured using UV-VIS spectrophotometry, while plankton sampling used a plankton net with a mesh size of 40 µm and a net mouth diameter of 20 cm. The results show that the highest chlorine concentration was found in Tondano Hilir River (0.05 mg/L), followed by the Kakas River downstream (0.04 mg/L). Chlorine concentration distribution in other rivers has the same concentration (0.03 mg/L).  Quality standard Chlorine according to Government Regulation number 22/2021 Appendix VI Class II is 0,03 mg/L. The highest number of species and index of phytoplankton species diversity was found in the Hulu Panasen River, while the highest species abundance was found in the Tondano River downstream. The correlation analysis of species diversity index with chlorine concentration did not show a significant relationship with the diversity of phytoplankton, but aquatic ecosystems have experienced moderate ecological pressure.

Abid, K., Alamgir, A., Zahid, Y., Mahar, K., Arif, S., Zehra, W., ... & Sherwani, S. K. (2014). Chlorine status and drinking water quality in public institutions of Karachi, Pakistan. American-Eurasian Journal of Agricultural & Environmental Science, 14(11), 1317-1321.

Alkhateeb, R. (2014). Influence of Chloride Concentration on Water Quality. International Journal of Applied Engineering Research and Development ( IJAERD), 4(1), 63–68.

Asdak, C. (2018). Hidrologi Dan Pengelolaan Daerah Aliran Sungai. Gadjah Mada University Press.

Atashgahi, S., Liebensteiner, M. G., Janssen, D. B., Smidt, H., Stams, A. J. M., & Sipkema, D. (2018). Microbial synthesis and transformation of inorganic and organic chlorine compounds. Frontiers in Microbiology, 9, 3079.

Azizullah, A., Khattak, M. N. K., Richter, P., & Häder, D. P. (2011). Water pollution in Pakistan and its impact on public health—a review. Environment international, 37(2), 479-497.

Badawi, A. F., Cavalieri, E. L., & Rogan, E. G. (2000). Effect of chlorinated hydrocarbons on the expression of cytochrome P450 1A1, 1A2 and 1B1 and 2-and 4-hydroxylation of 17β-estradiol in female Sprague–Dawley rats. Carcinogenesis, 21(8), 1593–1599.

Bajjali, W. (2018). Watershed delineation. In ArcGIS for environmental and water issues (pp. 235–245). Springer.

Balqis, N., El Rahimi, S. A., & Damora, A. (2021). Keanekaragaman dan kelimpahan fitoplankton di perairan ekosistem mangrove Desa Rantau Panjang, Kecamatan Rantau Selamat, Kabupaten Aceh Timur. Jurnal Kelautan Dan Perikanan Indonesia, 1(1), 35–43.

Bassey, G. I. (2017). Residual chlorine decay in water distribution network. Journal of Scientific Research and Engineering Studies (IJSRES), 3(3), 1-6

Borja, V. M. (2012). Marine phytoplankton of the Western Pacific. Kouseisha Kouseikaku.

Chen, W., He, Z. L., Yang, X. E., Mishra, S., & Stoffella, P. J. (2010). Chlorine nutrition of higher plants: progress and perspectives. Journal of Plant Nutrition, 33(7), 943–952.

Choudhary, S., Yamini, N. R., Yadav, S. K., Kamboj, M., & Sharma, A. (2018). A review: Pesticide residue: Cause of many animal health problems. Journal of Entomology and Zoology Studies, 6(3), 330-333.

Clarke, K. R., & Ainsworth, M. (1993). A method of linking multivariate community structure to environmental variables. Marine Ecology-Progress Series, 92, 205.

Clesceri, L. S., Greenberg, A. E., & Trussell, R. R. (1989). Chlorophyll Method 10200H. Standard Methods for the Examination of Water and Wastewater, 17th Ed. American Public Health Associate, Washington, DC, 31–39.

Da Costa, J. B., Rodgher, S., Daniel, L. A., & Espíndola, E. L. G. (2014). Toxicity on aquatic organisms exposed to secondary effluent disinfected with chlorine, peracetic acid, ozone and UV radiation. Ecotoxicology, 23(9), 1803–1813.

David, M. B., Mitchell, C. A., Gentry, L. E., & Salemme, R. K. (2016). Chloride sources and losses in two tile‐drained agricultural watersheds. Journal of Environmental Quality, 45(1), 341–348.

Dea, D. G. B. (2000). Teknik pengambilan contoh dan analisis data biofisik sumberdaya pesisir. Pusat Kajian Sumberdaya Pesisir Dan Lautan. Fakultas Perikanan Dan Ilmu Kelautan. Institut Pertanian Bogor. Bogor.

Della Rossa, P., Jannoyer, M., Mottes, C., Plet, J., Bazizi, A., Arnaud, L., Jestin, A., Woignier, T., Gaude, J.-M., & Cattan, P. (2017). Linking current river pollution to historical pesticide use: Insights for territorial management?. Science of the Total Environment, 574, 1232–1242.

Emmanuel, E., Keck, G., Blanchard, J.-M., Vermande, P., & Perrodin, Y. (2004). Toxicological effects of disinfections using sodium hypochlorite on aquatic organisms and its contribution to AOX formation in hospital wastewater. Environment International, 30(7), 891–900.

Erlangga, Y. Y., & Setiawan, H. (2018). Perancangan mesin pengolah air bersih bergerak dengan menggunakan sistim modular untuk penanggulangan keadaan darurat air. Machine: Jurnal Teknik Mesin, 4(1), 21–28.

García-Espinoza, J. D., Mijaylova-Nacheva, P., & Avilés-Flores, M. (2018). Electrochemical carbamazepine degradation: effect of the generated active chlorine, transformation pathways and toxicity. Chemosphere, 192, 142–151.

Gill, H. K., & Garg, H. (2014). Pesticide: environmental impacts and management strategies. Pesticides-Toxic Aspects, 8, 187.

Hadi, A. (2015). Pengambilan sampel lingkungan. Erlangga, Jakarta.

Hassaan, M. A., & El Nemr, A. (2020). Pesticides pollution: Classifications, human health impact, extraction and treatment techniques. The Egyptian Journal of Aquatic Research, 46(3), 207-220.

Hayat, F. (2020). Analisis Kadar Klor Bebas (Cl2) dan Dampaknya Terhadap Kesehatan Masyarakat di Sepanjang Sungai Cidanau Kota Cilegon. Jurnal Kesehatan Masyarakat Mulawarman (JKMM), 2(2), 64–69.

Hou, Z., Jiang, Y., Liu, Q., Tian, Y., He, K., & Fu, L. (2018). Impacts of environmental variables on a phytoplankton community: A case study of the tributaries of a subtropical river, Southern China. Water, 10(2), 152.

Igbinosa, E. O., Odjadjare, E. E., Chigor, V. N., Igbinosa, I. H., Emoghene, A. O., Ekhaise, F. O., Igiehon, N. O., & Idemudia, O. G. (2013). Toxicological profile of chlorophenols and their derivatives in the environment: the public health perspective. The Scientific World Journal, 2013.

Iglesias, A., & Garrote, L. (2015). Adaptation strategies for agricultural water management under climate change in Europe. Agricultural Water Management, 155, 113–124.

Jayaraj, R., Megha, P., & Sreedev, P. (2016). Organochlorine pesticides, their toxic effects on living organisms and their fate in the environment. Interdisciplinary Toxicology, 9(3–4), 90.

Kibria, G. (2016). Pesticides and its impact on environment, biodiversity and human health-A short review.

Koneri, R., Nangoy, M., & Wakhid, W. (2021). Richness and diversity of insect pollinators in various habitats around Bogani Nani Wartabone National Park, North Sulawesi, Indonesia. Biodiversitas Journal of Biological Diversity, 22(1), 288-297.

Lestari, H. A., Samawi, M. F., Faizal, A., Moore, A. M., & Jompa, J. (2021). Diversity and abundance of phytoplankton in the coastal waters of South Sulawesi. HAYATI Journal of Biosciences, 28(3), 199–211.

Levillain, J., Cattan, P., Colin, F., Voltz, M., & Cabidoche, Y.-M. (2012). Analysis of environmental and farming factors of soil contamination by a persistent organic pollutant, chlordecone, in a banana production area of French West Indies. Agriculture, Ecosystems & Environment, 159, 123–132.

Li, H., Mehler, W. T., Lydy, M. J., & You, J. (2011). Occurrence and distribution of sediment-associated insecticides in urban waterways in the Pearl River Delta, China. Chemosphere, 82(10), 1373–1379.

Li, Y., Li, J., & Zhang, H. (2014). Effects of chlorination on soil chemical properties and nitrogen uptake for tomato drip irrigated with secondary sewage effluent. Journal of Integrative Agriculture, 13(9), 2049–2060.

Luntungan, J. N. (2014). Dinamika spasial penggunaan lahan pertanian berdasarkan citra penginderaan jauh: Tinjauan dalam rangka menuju pertanian lestari didaerah aliran sungai (DAS) Noongan dan Panasen kabupaten Minahasa Sulawesi Utara. Universitas Gadjah Mada.

Mahmood, I., Imadi, S. R., Shazadi, K., Gul, A., & Hakeem, K. R. (2016). Effects of pesticides on environment. In Plant, soil and microbes (pp. 253–269). Springer.

Medo, J., Hricáková, N., Maková, J., Medová, J., Omelka, R., & Javoreková, S. (2020). Effects of sulfonylurea herbicides chlorsulfuron and sulfosulfuron on enzymatic activities and microbial communities in two agricultural soils. Environmental Science and Pollution Research, 27(33), 41265–41278.

Mottes, C., Deffontaines, L., Charlier, J. B., Comte, I., Della Rossa, P., Lesueur-Jannoyer, M., Woignier, T., Adèle, G., Tailame, A.-L., & Arnaud, L. (2020). Spatio-temporal variability of water pollution by chlordecone at the watershed scale: what insights for the management of polluted territories? Environmental Science and Pollution Research, 27(33), 40999–41013.

Mujiyanto, D. W., Tjahjo, H., & Sugianti, Y. (2011). Hubungan Antara Kelimpahan Fitoplankton dengan Konsentrasi N: P pada Daerah Keramba Jaring Apung (KJA) di Waduk Ir. H. Djuanda. Jurnal Limnotek, 18(1), 15–25.

Nogueira, L. M., Buzetti, S., Filho, M. C. M. T., Galindo, F. S., & Mello, T. F. (2020). Residual effect of KCl coated by polymeters incorporated in a corn crop. IDESIA (Chile), 38(1), 39–46.

Ogunfowokan, A. O., Oyekunle, J. A. O., Torto, N., & Akanni, M. S. (2012). A study on persistent organochlorine pesticide residues in fish tissues and water from an agricultural fish pond. Emirates Journal of Food and Agriculture, 165–184.

Özkara, A., Akyıl, D., & Konuk, M. (2016). Pesticides, environmental pollution, and health. In Environmental health risk-hazardous factors to living species. IntechOpen.

Pan, L., Zhang, X., Yang, M., Han, J., Jiang, J., Li, W., Yang, B., & Li, X. (2019). Effects of dechlorination conditions on the developmental toxicity of a chlorinated saline primary sewage effluent: Excessive dechlorination is better than not enough. Science of the Total Environment, 692, 117–126.

Pereira, D. G. C., Santana, I. A., Megda, M. M., & Megda, M. X. V. (2019). Potassium chloride: impacts on soil microbial activity and nitrogen mineralization. Ciência Rural, 49.

Prasiwi, I., & Wardhani, E. (2018). Analisis Hubungan Kualitas Air Terhadap Indeks Keanekaragaman Plankton dan Bentos Di Waduk Cirata. Rekayasa Hijau: Jurnal Teknologi Ramah Lingkungan, 2(3).

Rochette, R., Bonnal, V., Andrieux, P., & Cattan, P. (2020). Analysis of surface water reveals land pesticide contamination: an application for the determination of chlordecone-polluted areas in Guadeloupe, French West Indies. Environmental Science and Pollution Research, 27(33), 41132–41142.

Rowe, M. D., Anderson, E. J., Vanderploeg, H. A., Pothoven, S. A., Elgin, A. K., Wang, J., & Yousef, F. (2017). Influence of invasive quagga mussels, phosphorus loads, and climate on spatial and temporal patterns of productivity in Lake Michigan: A biophysical modeling study. Limnology and Oceanography, 62(6), 2629–2649.

Sardet, C. (2015). Plankton: wonders of the drifting world. University of Chicago Press.

Sharma, P. P., Yadav, V., Rajput, A., & Kulshrestha, V. (2018). Synthesis of chloride-free potash fertilized by ionic metathesis using four-compartment electrodialysis salt engineering. ACS Omega, 3(6), 6895–6902.

Singh, N., & Singh, S. B. (2012). Sorption-desorption behavior of metsulfuron-methyl and sulfosulfuron in soils. Journal of Environmental Science and Health, Part B, 47(3), 168–174.

Sittadewi, E. H. (2008). Fungsi strategis Danau Tondano, Perubahan ekosistem dan masalah yang terjadi. Jurnal Teknologi Lingkungan, 9(1), 5-66.

Sofia, E., & Riduan, R. (2017). Evaluasi dan analisis pola sebaran sisa klor bebas pada jaringan distribusi ipa sungai lulut pdam bandarmasih. Jukung (Jurnal Teknik Lingkungan), 3(2), 10-24.

Sriwijayanti, L. A., Setiawan, R. Y., Firdaus, M. R., Fitriya, N., & Sugeha, H. Y. (2019). Community structure of phytoplankton in the surface and thermocline layers of Sangihe and Talaud waters, Indonesia. International Journal of Bonorowo Wetlands, 9(2), 51-58.

Tsitsifli, S., & Kanakoudis, V. (2018). Disinfection impacts to drinking water safety—A review. Multidisciplinary Digital Publishing Institute Proceedings, 2(11), 603, 1-7.

Vannoni, M., Créach, V., Lozach, S., Barry, J., & Sheahan, D. (2021). Chlorination in power station cooling water systems: Effect on biomass, abundance and physiology of natural phytoplankton communities. Aquatic Toxicology, 239, 105954.

Wang, Y. S., Chen, W. C., Lin, L. C., & Yen, J. H. (2010). Dissipation of herbicides chlorsulfuron and imazosulfuron in the soil and the effects on the soil bacterial community. Journal of Environmental Science and Health Part B, 45(5), 449-455.

Wantasen, S., Luntungan, J. N., & Tarore, A. E. (2020). Spatio-temporal distribution of chlorine in the upper Tondano Watershed North Sulawesi Indonesia. IOP Conference Series: Earth and Environmental Science, 535(1), 12029.

Wantasen, S., Luntungan, J. N., Tarore, A. E., & Lumingkewas, A. (2019). Water quality of the Panasen River in the upstream of the Tondano Watershed in a five-year period (2014-2018). Journal of Physics: Conference Series, 1321(3), 32115.

Widigdo, B., & Wardiatno, Y. (2013). Dinamika komunitas fitoplankton dan kualitas perairan di lingkungan perairan tambak udang intensif: sebuah analisis korelasi. Jurnal Biologi Tropis, 13(2), 160-184.

Yunandar, D., Effendi, H., & Setiawan, Y. (2020). Plankton biodiversity in various typologies of inundation in Paminggir peatland, South Kalimantan, Indonesia on dry season. Biodiversitas Journal of Biological Diversity, 21(3), 1012-1019.

Yusuf, Z. H. (2020). Phytoplankton as bioindicators of water quality in Nasarawa reservoir, Katsina State Nigeria. Acta Limnologica Brasiliensia, 32, 1-11.

Zhang, Q., Gaafar, M., Yang, R.-C., Ding, C., Davies, E. G. R., Bolton, J. R., & Liu, Y. (2018). Field data analysis of active chlorine-containing stormwater samples. Journal of Environmental Management, 206, 51–59.

Zhao, C., Xie, H., Zhang, J., Xu, J., & Liang, S. (2013). Spatial distribution of organochlorine pesticides (OCPs) and effect of soil characters: a case study of a pesticide producing factory. Chemosphere, 90(9), 2381–2387.