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Submitted
October 26, 2020
Accepted
December 29, 2020
Published
December 29, 2020
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Abstract

Desa Sambirejo merupakan salah satu sentra produksi tanaman tomat. Pengaruh cuaca saat ini memberikan dampak yang buruk terhadap hasil produksi tomat. Karena tanaman tomat merupakan tanaman yang mudah diserang penyakit sehingga hasil panennya mengalami fluktuatif. Melalui penerapan teknologi sonic bloom dapat menambah pengetahuan, dan keterampilan serta dapat menjadi solusi pemecahan masalah dalam meningkatkan hasil panen petani. Teknologi sonic bloom merupakan gelombang suara berfrekuensi 3.500 – 5.000 Hz. Gelombang tersebut dapat merangsang pembukaan stomata tanaman sehingga penyerapan pupuk daun meningkat. Penerapan teknologi ini dapat meningkatkan produktivitas tanaman tomat yang lebih baik. Hasilnya batang lebih tinggi, buah jauh lebih besar dan jumlah buah tomat lebih banyak dibandingkan dengan tanaman tomat jauh dari sumber suara.

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Author Biography

Refpo Rahman, Universitas Bengkulu

Prodi D3 Laboratorium Sains
How to Cite
Rahman, R., Fadila, M. A., Saputra, H. E., Novanda, R. R., Salamah, U., Syarkowi, A., Sari, K. N., & Prawanto, A. (2020). Peningkatan Hasil Panen Tomat di Desa Sambirejo Dengan Penerapan Teknologi “Sonic Bloom”. Dharma Raflesia : Jurnal Ilmiah Pengembangan Dan Penerapan IPTEKS, 18(2), 248–258. https://doi.org/10.33369/dr.v18i2.13242
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References

  1. Afifah, E., Nugrahani, M., Prasetyo, N., Berlian, I., Rinojati, N., & Kadarisman, N. (2015). Utilization of Audio Bioha rmony to Improve Rubber (Hevea brasiliensis) Growth in the Nursery. Current Agriculture Research Journal, 3(1), 01–06. https://doi.org/10.12944/carj.3.1.01
  2. Carlson, D. (2020). The Sonic Bloom Growing System. Http://Dancarlsonsonicbloom.Com/. Diakses pada tanggal 27 Maret 2020
  3. Istirochah, P., & Sugiarto. (2017). Pengaruh intensitas bunyi terhadap pembukaan stomata , pertumbuhan dan hasil kedelai ( Glycine Max ( L .) Merril ) melalui aplikasi sonic bloom. Jurnal Folium, 1(1), 60–70.
  4. Kadarisman, N., Agustika, D. K., Purwanto, A., Alvianty, V., & Wibowo, B. (2019). Characterization of Sound Spectrum based on Natural Animals as an Alternative Source of Harmonic System Audio Bio Stimulators for Increasing Productivity of Food Plants. Journal of Physics: Conference Series, 1387(1). https://doi.org/10.1088/1742-6596/1387/1/012098
  5. Murni, N., Achyani, A., & Santoso, H. (2018). Pengaruh amplitude sonic bloom single tone terhadap perkecambahan benih tomat cherry (Lycopersicum cerasiforme Mill). BIOEDUKASI (Jurnal Pendidikan Biologi), 9(2), 154–165.
  6. Prasetyo, J., & Lazuardi, I. B. (2017). Pemaparan Teknologi Sonic Bloom Dengan Pemanfaatan Jenis MusikTerhadap Pertumbuhan Vegetatif Tanaman Selada Krop ( Lactuca Sativa L ). Jurnal Keteknikan Tropis Dan Biosistem, 5(2), 189–199.
  7. Prasetyo, J., Mandang, T., & Subrata, I. (2014). Efek Paparan Musik dan Noise pada Karakteristik Morfologi dan Produktivitas Tanaman Sawi Hijau (Brassica Juncea). Jurnal Keteknikan Pertanian, 2(1), 21959.
  8. Rosana, D., Kadarisman, N., Maryanto, A., & Sugiharsono, A. (2017). The evaluation of science learning program, technology and society application of Audio Bio Harmonic System with solar energy to improve crop productivity. Jurnal Pendidikan IPA Indonesia, 6(1), 63–70. https://doi.org/10.15294/jpii.v6i1.9596
  9. Suryadarma, I. G. P., Widiastuti, Nur Kadarisman, & Dwandaru, W. S. B. (2020). the Increase of Stomata Opening Area in Corn Plant Stimulated By Dundubia Manifera Insect Sound. International Journal of Engineering Technologies and Management Research, 6(5), 107–116. https://doi.org/10.29121/ijetmr.v6.i5.2019.377
  10. Sutan, S. M., Prasetyo, J., & Mahbudi, I. (2018). Pengaruh Paparan Frekuensi Gelombang Bunyi terhadap Fase Vegetatif Pertumbuhan Tanaman Kangkung Darat ( Ipomea Reptans Poir ) The Effect of Exposure Sound Waves Frequency on Plant Growth Vegetative Phase of Kale ( Ipomea Reptans Poir ). Jurnal Keteknikan Pertanian Tropis Dan Biosistem, 6(1), 72–78.
  11. Weinberger, P., & Measures, M. (2011). Effects of the intensity of audible sound on the growth and development of Rideau winter wheat. Canadian Journal of Botany, 57, 1036–1039.