Jurnal Kelautan Nasional

Gelembung udara dapat terbentuk secara alami maupun buatan. Gelembung udara buatan tercipta dari kegiatan antropogenik seperti pergerakan profiler kapal, penambangan, pembangunan bawah air, dan aerator (alat pembentuk gelembung udara).  Dalam ilmu hidroakustik, gelembung udara merupakan faktor utama dalam propagasi suara dekat-permukaan.   Oleh sebab itu dalam pengambilan data hidroakustik gelembung udara harus minimalkan agar hasil pengukuran hidroakustik menjadi akurat, baik dalam pengambilan data di lapangan maupun dalam skala laboratorium. Tujuan penelitian ini untuk mengetahui hambur balik dari gelembung udara buatan dalam kondisi terkontrol.  Penelitian ini  menggunakan Alat  aerator jenis Roston Q3 Aquarium Air Pump yang beroperasi apada 220-240 Volt mampu menghasilkan laju gelembung udara sebesar 2.5 watt dan 3 watt. Perekaman data akustik menggunakan Echosounder EK-15 dan analisis data menggunakan sofware echoview (4) versi demo.  Nilai hambur balik gelembung udara dengan daya 3 watt memiliki rentang -45.06 sampai -45.01 dB (ref:1μPa) dengan rata-rata hambur balik -45,02 dB (ref:1μPa). Adapun gelembung dengan daya 2.5 watt memiliki nilai hambur balik dengan rentang -45.07 sampai -45.01 dB (ref:1μPa), dengan nilai  hambur balik rata-rata sebesar -45.03 dB (ref:1μPa).

Akita, K. & Yoshida, F. (1974). Bubble Size, Interfacial Area, and Liquid-Phase Massa Transfer Coefficient in Bubble Columns, Ind. Eng. Chem., Process Des. Develop., 13(1), 84-90

Bjerne, L. (1994). Underwater rain noise: sources, spectra and interpretations. J. de Physique IV Colloque C5, supplement au Journal de Physique III, (4). mai.

Blanchard, D.C., & Woodcock. A.H. (1957). Bubble Formation and Modification in the Sea and its Meteorological Significance. Tellus A: Dynamic Meteorology and Oceanography 9(2):145-158. DOI.org/10.1111/J.2153-3490.1957.th01867x

Davies, R.M., & Taylor, G.I. (1950). The Mechanics of Large Bubbles Rising Through Extended Liquids and Through Liquids in Tubes, Proc. Royal Society, London, A200, pp 375- 390.

Del Grosso, V.A., & Mader, C.W. (1972). Speed of sound in pure water. Journal Acoustic. Soc. Am. 52: 1442 – 1446.

FAO. (1983). Hydroacoustic assessment in high density fish schools. Roma

Foote, K.G., & Maclennen, D.N. (1983). Comparison of copper and tungsten carbide calibration spheres. https://core.ac.uk/download/pdf/10127024.pdf (download 8 Oktober 2021)

Folds, D.L., & Loggins, C.D. (1983). Target strength of Liquid-filled spheres. The Journal of the Acoustical Society of America 73, 1147 (1983); https://doi.org/10.1121/1.389285

Howard, F. R., & Holmes, J. R. (1977). Chemical Reactor Design for Process Plants, Vol. 1: Principles and Techniques. New York. Wiley.

Hisyam, H., Pujiyati, S., Wijopriono, Nurdin, E., Ma’mun. A. (2021). Sebaran Ikan Pelagis Kecil Berdasarkan Kedalaman Dan Waktu Di Perairan Teluk Cenderawasih. J.Lit.Perikan.Ind. Vol.26 (4): 221-232

Koga, M. (1982). Bubble entrainment in breaking wind waves, Tellus, 34:5, 481-489, DOI: 10.3402/tellusa.v34i5.10833

Kugou, N., Ishida, K., Yoshida, A. (2003). Experimental study on motion of air bubbles in seawater (terminal velocity and drug coefficient of air bubble rising in seawater). Transactions on the Built Environment vol 68: 145-148

LaFond, E.C., & Dill, R.F. (1957). Do invisible bubbles exist in the sea. University of California Libraries. 58pp.

Leighton, J.G. (2017). The acoustic bubble: Ocean, cetacean and extraterrestrial acoustics, and cold water cleaning. J. Phys.: Conf. Ser. 797 012001.

Medwin, H. (1974). Acoustic fluctuation due to microbubbles in the nearsurface ocean. Journal of The Acoustical Society of America. 56: 1100–1104.

Medwin, H., & Clay, C.S. (1997). Fundamentals of acoustical oceanography. United Kingdom Edition published by ACADEMIC PRESS LIMITED 24-28 Oval Road, London NW1 7DX. 712pp

Medwin, H., Nystuen, J.A., Jacobu, P.W., Snyder, D.E., Ostwald, L.H. (1992). The anatomy of underwater rain noise. J. of Acoustical society of America. (92): 13- 23.

Pujiyati, S., Hamuna, B., Rohilah, Hisyam, M., Srimariana, E.S., Natih, I.M.N. (2021). Distributions of environmental parameters and Plankton’s volume backscattering strength at Yos Sudarso Bay, Jayapura, Indonesia. Egyptian Journal of Aquatic Research. Volume 48 (1):37-44. https://doi.org/10.1016/j.ejar.2021.08.001

Scrimger, J. A., D. J. Evans, G. A. McBean, D. M. Farmer and B. R. Jerman. (1987). Underwater noise due to rain, hail and snow, J. Acoust. Soc. Am. 81: 79-86.

Simmonds, J., & MacLennan, D. (2005). Fisheries Acoustics. New Jersey (USA) : Blackwell Publishing Company.

SIMRAD EK 15. (2012). Multi purpose scientific echosounder. Diunduh [https://www.SIMRAD.online/ek15/sales/ek15_ds_en_a4.pdf] pada 2 Maret 2021.

Sonar-Info. (2021). Scattered Gas Bubbles. http://www.sonar-info.info/p278/TS.pdf ( download 8 Oktober 2021)

Thoenes, D. (1994). Course on Two-phase Reactors, Jurusan Teknik Kimia, UGM. Yogyakarta

Urick, R.J. (1967). Principles of Underwater Sound. New York (USA) : McGraw-Hill Book Company.

Woolf, D.K. (2001). Bubbles, Academic press, Southampton Oceanography Center, UK Academic press.