Liquid Smoke of Red Fruit (Pandanus Conoideus. L.) Waste with Pyrolysis Method For Controlling Sweet Potatoes (Ipomea Batatas. L.) Pest

Fransisca Christiana DEWI; Sumiyati TUHUTERU; Andi ALADIN; Setiyawati YANI; Rohimah Handayani Sri LESTARI; Irwan Suluk PADANG; Bhaskara Anggarda Gathot SUBRATA

doi:10.38142/ijesss.v3i1.168

Authors

Fransisca Christiana DEWI Petra Baliem College of Agricultural Sciences, Wamena, Indonesia
Sumiyati TUHUTERU Muslim University of Indonesia (UMI), Makassar, Indonesia
Andi ALADIN Assesment Institute of Agricultural Technology (AIAT) of Papua, Jayapura, Indonesia
Setiyawati YANI Assesment Institute of Agricultural Technology (AIAT) of Central Sulawesi. Palu, Indonesia
Rohimah Handayani Sri LESTARI Assesment Institute of Agricultural Technology (AIAT) of Papua, Jayapura, Indonesia
Irwan Suluk PADANG Assesment Institute of Agricultural Technology (AIAT) of Central Sulawesi. Palu, Indonesia
Bhaskara Anggarda Gathot SUBRATA Department of Agronomy, Amal Ilmiah University, Wamena, Indonesia

DOI:

https://doi.org/10.38142/ijesss.v3i1.168

Keywords:

Biopesticide, liquid smoke, organic, pandanus, pyrolysis

Abstract

Pandanus conoidus, or red fruit, is a nutrient-dense native Papuan plant, whereas Ipomea batatas are the main food for the Wamena people. Biomass from red fruit seed waste can be used as liquid smoke to control Ipomea batatas . At a temperature of between 300 - 450 °C, liquid smoke is produced through a pyrolysis process. Pyrolysis produces phenolic chemicals and aldehydes that have antioxidant and antimicrobial properties (anti-bacterial and anti-fungal). The assessment of pH, acidity, and phenol concentration characterizes the quality of liquid smoke. The potential of red fruit seed waste as a liquid smoke product for biopesticides in Ipomea batatas is explored in this study. Additionally, study development aims to determine the optimal method for pyrolyzing red fruit seed waste, its characteristics, chemical content, and the way to use liquid smoke as a biopesticide in Ipomea batatas . The results showed that the liquid smoke of grade 3 red fruit seed waste contains 7 components that can be detected using a mass spectrometer. The higher the concentration of liquid smoke produced by grade 3 red fruit seeds, the higher the possibility of Cylas formicarius mortality. Cylas formicarius had the highest mortality rate (90%) when tested at a 7% test solution concentration.

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References

Aladin A, Alwi RS, Syarif T. 2017. Design of pyrolysis reactor for the production of bio-oil and bio-char simultaneously. AIP Conf Proc. 1840(1): 110010. DOI:10.1063/1.4982340.

Aladin A, Yani S, Modding B, Wiyani L. 2018. Pyrolisis Of Corncob Waste To Produce Liquid Smoke. IOP Conf Ser Earth Environ Sci. 175(1): 012020. DOI:10.1088/1755-1315/175/1/012020.

Alpian A, Prayitno TA, Pramana J, Sutapa G, Budiadi B. 2014. Kualitas Asap Cair Batang Gelam (Melaleuca sp.). J Penelit Has Hutan. 32(2): 83–92. DOI:10.20886/JPHH.2014.32.2.83-92. [Indonesian]

Baskar K, Ignacimuthu S. 2012. Antifeedant, larvicidal and growth inhibitory effects of ononitol monohydrate isolated from Cassia tora L. against Helicoverpa armigera (Hub.) and Spodoptera litura (Fab.) (Lepidoptera: Noctuidae). Chemosphere. 88(4): 384–388. DOI:10.1016/J.CHEMOSPHERE.2012.02.051.

Dediwanto Y, Oramahi HA, Nurhaida. 2020. The Potential of Liquid Smoke from Bengkirai Wood in Inhibiting The Growth of Schizophyllum commune In Vitro. J Galung Trop. 9(1): 1–9. DOI:10.31850/jgt.v9i1.518. [Indonesian]

Faisal M, Gani A, Baihaqi A. 2014. Potential Development of Liquid Smoke from Oil Palm Solid Waste as Bio fungicides. Int J Sci Eng. 7(1): 65–69. DOI:10.12777/ijse.7.1.65-69.

Faisal M, Gani A, Husni, Baihaqi A, Daimond H. 2016. Pyrolysis of Oil Palm Kernel Shell into Liquid Smoke and its Application to Control Anthracnose Disease on Chili (Capsicum annum L.). J Eng Appl Sci. 11(12): 2583–2587. DOI:10.36478/jeasci.2016.2583.2587.

Faisal M, R.YelviaSunarti A, Desvita H. 2018. Characteristics of liquid smoke from the pyrolysis of durian peel waste at moderate temperatures. Rasayan J Chem. 11(2): 871–876. DOI:10.31788/RJC.2018.1123035.

Gani A, Husni H, Baihaqi A, Faisal M. 2014. Potential Development of Liquid Smoke from Oil Palm Solid Waste as Bio fungicides. Int J Sci Eng. 7(1): 65–69. DOI:10.12777/IJSE.7.1.65-69.

Indriati G, Samsudin S. 2018. Potential of Liquid Smoke as Botanical Insecticide to Control Coffee Berry Borer Hypothenemus hampei. J Tanam Ind dan Penyegar. 5(3):123–134. DOI:10.21082/jtidp.v5n3.2018.p123-134. [Indonesian]

Isa I, Musa WJA, Rahman SW. 2019. Pemanfaatan Asap Cair Tempurung Kelapa Sebagai Pestisida Organik Terhadap Mortalitas Ulat Grayak (Spodoptera Litura F.). Jamb J Chem.(1): 15–20. [Indonesian]

Kendra PE, Montgomery WS, Niogret J, Schnell EQ, Deyrup MA, Epsky ND. 2014. Evaluation of seven essential oils identifies cubeb oil as most effective attractant for detection of Xyleborus glabratus. J Pest Sci 2014 874. 87(4): 681–689. DOI:10.1007/S10340-014-0561-Y.

Kim SP, Kang MY, Park JC, Nam SH, Friedman M. 2012. Rice hull smoke extract inactivates Salmonella typhimurium in laboratory media and protects infected mice against mortality. J Food Sci. 77(1): M80–M85. DOI:10.1111/J.1750-3841.2011.02478.X.

Kumar J, Ramlal A, Mallick D, Mishra V. 2021. An overview of some biopesticides and their importance in plant protection for commercial acceptance. Plants. 10(6):1185. DOI:10.3390/PLANTS10061185.

Li H, Chen C, Cao X. 2015. Essential oils-oriented chiral esters as potential pesticides: Asymmetric syntheses, characterization and bio-evaluation. Ind Crops Prod. 76:432–436. DOI:10.1016/J.INDCROP.2015.07.027.

Oramahi HA, Wardoyo ERP, Kustiati K. 2018. Efikasi Asap Cair dari Kayu Bengkirai terhadap Phytophthora citrophthora. J Perlindungan Tanam Indones. 22(2): 160–166. DOI:10.22146/JPTI.33113.

Risfaheri R, Hoerudin H, Syakir M. 2018. Utilization of Rice Husk for Production of Multifunctional Liquid Smoke. J Adv Agric Technol. 5(3): 192–197. DOI:10.18178/joaat.5.3.192-197.

Rumbaina Mustikawati D, Mulyanti N, Wylis Arief R. 2016. Study Effectiveness of Liquid Smoke as a Natural Insecticide for Main Pest Control of Soybean Crops. Int J Sci Basic Appl Res. 30(1): 237–245.

Sari Y, Sari YP, Samharinto S, Langai BF. 2018. Penggunaan asap cair tandan kosong kelapa sawit (tkks) sebagai pestisida nabati untuk mengendalikan hama perusak daun tanaman sawi (Brassica juncea L.). EnviroScienteae. 14(3): 272–284. DOI:10.20527/es.v14i3.5699.

Soedijo S, Pramudi MI, Salamiah SA. 2015. Introduction study of potential of natural insecticide liquid smoke from solid waste oil palm to brown planthopper (Nilaparvata lugens stall) in south Kalimantan. Asian J Appl Sci. 3(1):2321–0893.

Sukharnikov YI, Esengaraev EK, Turgenbaev AT, Iskakov MS. 2015. Production, properties and use of the rice hulls pyrolysis organic product as a disinfectant. World J Vet Med Eng. 1(1):1–9.

Tima S La, Yopi, Ifa L. 2016. Pemanfaatan asap cair kulit biji mete sebagai pestisida. J Chem Process Eng. 1(2): 16–22. DOI:10.33536/JCPE.V1I2.66. [Indonesian]

Wagania L, Dewe I, Anom K, Kapahang A. 2018. Pyrolisis of Salak Seed (Salacca zallaca) and Toxicity Test of Its Liquid Smoke to the Mortality of Artemia salina Leach Larvae. Int J Appl Eng Res. 13 :10593–10597.

Wagiman FX, Ardiansyah A, Witjaksono. 2014. Activity of coconut-shell liquid-smoke as an insecticide on the rice brown planthopper (Nilaparvata lugens). ARPN J Agric Biol Sci. 9(9): 293–296.