Potential of Ecoenzymes and N2 Nanobubbles on the Growth of Phalaenopsis sp. Orchid at the Acclimatization Stage
Abstract
Growth is a quantitative change during one plant’s life cycle and is irreversible.withaddition An in crease the volume or dry weight of plants or other organs is due to the adding, of new structural elements. Phalaenopsis (moth orchid) is a genus of orchids appeal. The diversity of colors, shapes, and textures, as well as its aroma, make Phalaenopsis orchids one of the charming flowers of Indonesia. Ecoenzyme is a solution of complex organic substances produced from the fermentation of organic residues, sugar, and water. Nanobubbles (NBs) are an example of nanotechnology. NBs have a diameter of 1-100 nm and are nanoscopic gas bubbles in a solution or water that can change the characteristics of water and are stable. This study aims to determine the potential of giving Ecoenzyme and NBs N2 on the growth of Phalaenopsis orchids during the acclimatization stage. This research was conducted from October to December 2022 at the Orchidology and Nursery Laboratory, Islamic University of Malang. This study used an experimental method with a completely randomized design (CRD) with 10 treatments, namely 0 mL/L (control), 1 mL/L Ecoenzyme, 2 mL/L Ecoenzyme, 3 mL/L Ecoenzyme, 4 mL/L Ecoenzyme, 4 combination NBs N2 and Ecoenzymes, and 5 mL NBs N2 with 3 replications, making a total of 30 treatment units. The research parameters included the number of leaves, leaf length, number of roots, root length, plant height, fresh weight, and plant dry weight. The results of this study showed that the treatment of 3 mL/L Ecoenzyme showed potential in increasing the number of leaves by 4 pieces: at the same time the optimal concentration of the combination of Ecoenzyme and NBs was 2 mL/L plus 5 mL NBs N2 in increasing the number of roots by 10 pieces, and the optimal concentration of NBs was 5 mL in increasing the root length by 7.07 cm, plant height by 17.10 cm leaf. length, plant weight by 4.16 g and dry weight by 0.85 g in Phalaenopsis orchids.
References
Gardner FP, Pearce RB & Mitchell RL. 1991. Fisiologi Tanaman Budidaya. Terjemahan Herawati Susilo. Universitas Indonesia Press. Jakarta.
Gorendra RW, Ginting YC & Kushendarto. 2015. Pengaruh Konsentrasi Nitrogen dan Plant Catalyst terhadap Pertumbuhan dan Hasil Tanaman Selada (Lactuca sativa L.) Secara Hidroponik. Jurnal Penelitian Pertanian Terapan. 15(2): 100-106.
Gultom F, Hernawaty, Brutu H, Karo-karo S. 2022. Pemanfaatan Pupuk Ekoenzim dalam Meningkatkan Pertumbuhan dan Produksi Tanaman Bawang Merah (Allium cepa L.) J. Darma Agung. 30(1) : 142-159.
Hanik N, Harsono S & Eskundari S. 2021. The Effect of Peanut Skin Compost Mix Variaries on Planting Media on the Growth of Dendrobium sp. Jurnal Biologi Tropis. 21(1): 237-247.
Haryana N & Supriadi H. 2011. Pengaruh Indole Butyric Acid (IBA) dan Naphalene Acetic Acid (NAA) terhadap Keberhasilan Grafting Tanaman Pala. Buletin Risti. 2(3): 279-284.
He J, Liu Y, Wang T, Chen W, Liu B, Zhou Y & Li Y. 2022. Effects of Nanobubble in Subsurface Drip Irrigation on the Yield, Quality, Irrigation Water use Efficiency and Nitrogen Partial Productivity of Watermelon and Muskmelon, Int. Agrophys. 36:163-171.
Hemalatha M & Visantini P. 2020. Polybagential use of eco-enzyme for the treatment of metal base effluent. IOP Conf. Series:Materials Science and Engineering. 716: 1-6.
Khasanah U. 2011. Pemanfaatan Pupuk Daun, Air kelapa dan Bubur Pisang Sebagai Kombinasi Medium Kultur Jaringan untuk Mengoptimalkan Plantlet Anggrek Dendrobium kelemense. Skripsi. Semarang: Universitas Negeri Semarang.
Lakitan B. 1996. Fisiologi Pertumbuhan dan Perkembangan Tanaman. Raja Grafindo Persada. Jakarta.
Larcher W. 1975. Physiological Plant Ecology: University Innsbruck. London.
Lingga. P & Marsono. 2013. Pertunjuk Penggunaan Pupuk. Penebar Sedaya. Jakarta.
Novitasari B, Meiriani & Haryati. 2015. Pertumbuhan Setek Tanaman Buah Naga (Hylocereus costaricensis (Web.) Britton & Rose) dengan Pemberian Kombinasi Indole Butyric Acid (IBA) dan Naphthalene Acetic Acid (NAA). Jurnal Agroteknologi. 4(1): 1735-1740.
Nurdin. 2011. Penggunaan Lahan Kering Di Das Limboto Provinsi Gorontalo Untuk Pertanian Berkelanjutan. Jurnal Balitbang. 30(3): 98-107.
Pramitasari H, Wardiati T & Nawawi M. 2016. Pengaruh Dosis Pupuk Nitrogen dan Tingkat Kepadatan Tanaman Terhadap Pertumbuhan dan Hasil Tanaman Kailan (Brassica oleraceae L.). Jurnal Produksi Tanaman. 4(1): 49-56.
Rahayu T, Jayanti GE & Hayati A. 2023. Induksi Nanobubbles (NBs) untuk Pertumbuhan Anggrek Dendrobium Imelda Marina Masagung x Bumi Menangis. J. Metamorfosa. 10(1): 126:132.
Rahayu T, Jayanti GE & Agisimanto D. 2022. Indole-3-butryc acid Menginduksi Akar Adventif Dendrobium milla nylax, Dendrobium straenopsis Ditanam pada Sabut Kelapa dan Arang Kayu Selama Tahap Aklimatisasi. Berkala Penelitian Hayati. 28(1): 39-43.
Silva M, Jifon J, Da Silva J & Sharma V. 2007. Use of Physiological Parameters as Fast Tools to Screen for Drought Tolerancein Sugarcane. Jurnal Plant Physiology Brazil. 19(1): 193-201.
Supriadi & Sujarsono. 2005. Kombinasi Pupuk Urea Dengan Pupuk Organik Pada Tanah Inceptisol Terhadap Reason Fisiologis Rumput Hermada (Sorghum Bicolor). Balai Pengkajian Teknologi Pertanian, Yogyakarta.
Tini E, Sulistyanto P & Sumartono G. 2019. Aklimatisasi Anggrek (Phalaepnopsis amabilis) dengan Media. J. Hort. Indonesia 10(2): 119- 127.
Tisdale L & Nelson L. 2020. Soil Fertility and Fertilizers. Macmillan Publishing Co. New York.
Wareing PF & Phillips IDJ. 1970. The Control of Growth and Differentiation in Plants: Pergaman Press. New York.
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