Pelarutan P dan K dari batuan leusit dan apatit menggunakan kombinasi senyawa humat-BPF-BPK

Authors

  • Mohammad Jimmy KURNIATA universitas jember
  • Tri Candra SETIAWATI Pogram Studi Ilmu Tanah, Fakultas Pertanian, Universitas Jember, 68121, Indonesia
  • Jay JAYUS Fakultas Teknologi Pertanian, Universitas Jember, 68121,Indonesia

DOI:

https://doi.org/10.22302/iribb.jur.mp.v87i2.330

Keywords:

leusit, apatit, senyawa humat, asam organik

Abstract

Abstract

Due to the limited availability of potassium and phosphate in soil and the high price of their synthetic mineral fertilizers, the importance of minerals-solubilizing microorganismshas been increasingly significant aimed at sustainable agriculture achievement. Apatite and leucite are considerably abundant minerals; however, their solubility is low. This study was aimed to study the effects of the combination of phosphate-and potassium-solubilizing bacteria (PhSB and PSB) and humic acid of cassava as bioleaching agents in the solubilization process of potassium and phosphate from agromineral material. Some leucite agromineral materials were obtained from Situbondo and Pati, while apatite materials were obtained from Tuban and Ciamis, Indonesia. The minerals were treated with 2.10 x 107CFU/g PhSB and 1.61 x 107CFU/g PSB isolates, combined with 100 ppm organic C humic compounds from cassava as the media. The minerals solubility was monitored every two weeks for 12 weeks ofobservation, which includes the concentration of dissolved K and P, as well as the pH of the media. The presence of organic acids was observed to monitor the bacterial activity by using HPLC, while the physical changes of the rock surface due to bacterial dissolution were scanned by using scanning electron microscopy (SEM). The results showed that the highest dissolution of P was recorded at week 4 (344.23 ppm) released from Tuban apatite with the combination of PhSB and PSB under the humic compound.In contrast, the highest K dissolution was obtained at week 6 for Situbondo leucite (44.21 me/100 g) with a combination of humic cassava compound and PSB only. Statistical analyses showed a mark different on both minerals for dissolution of K and P. The SEM result indicates breakage of the rock surface after a three month observation period indicating that the dissolution minerals occurred. Selected organic acids such as citric, ferulic, coumaric, syringic, and malic acids were detected during the treatment.

[Keywords: leucite, apatite, humic compounds, organic acid]

 

Abstrak

     Ketersediaan kalium (K) dan fosfat (P) dalam tanah terbatas,danharga pupuk sintetik relatif mahal, menjadikan mikroorganismepelarut mineral memegang peranan penting dalam menunjang pertanian berkelanjutan.Batuan mineral apatit dan leusitmerupakan sumber daya mineral dengan ketersediaan tinggi tetapi mempunyai kelarutan mineral rendah. Penelitian bertujuan untukmempelajari pengaruh kombinasi bakteri pelarut fosfat (BPF), bakteri pelarut kalium (BPK), dan humatsingkong sebagai agen bioleachingdalam proses pelarutan K dan P dari bahan agromineral. Bahan agromineral leusitdiperoleh dariKabupatenSitubondo dan Pati, sedangkan bahan apatit berasal dari Kabupaten Tuban dan Ciamis, Indonesia. Bahan mineral diperlakukan dengan 2,10 x107CFU/gBPF dan 1,61 x 107CFU/gBPK, dikombinasikan dengan 100 ppm C organik senyawa humatdari singkong sebagai media. Kelarutan mineral diamati setiap dua minggu sekali selama 12 minggu meliputi kelarutan K dan P, dan pH media. Produksi asam organik dianalisis untuk mengamati aktivitas bakteri menggunakan HPLC dan perubahan fisik permukaan batuan akibat pelarutan bakteri dipindai menggunakan SEM.Hasil penelitian menunjukkan bahwa pelarutan fosfat tertinggi tercatat pada minggu ke 4 (344,23 ppm) yang dilepaskan dari apatit Tuban dengan kombinasi BPF dan BPK dengan senyawa humat, sedangkan pelarutan kalium tertinggi diperoleh pada minggu ke 6 dari leusitSitubondo (44,21 me / 100 g) dengan kombinasi senyawa humatsingkong dan BPK. Secara statistikpada kedua mineral pelarutan K dan P menunjukkan berbedanyata. Hasil analisis dengan menggunakan SEMterjadi kerusakan permukaan batuansetelah periode pengamatan tigabulan yang menunjukkan bahwa terjadi pelarutan mineral. Selama percobaan dideteksi beberapa  asam organik seperti asam sitrat, ferulat, kumarat, siringatdan malat. 

[Kata kunci: leusit, apatit,senyawa humat,asam organik]

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References

Anjanadevi IP, NS John, KS John, ML Jeeva & RS Misra (2016). Rock inhabiting potassium solubilizing bacteria from Kerala, India: characterization and possibility in chemical K fertilizer substitution. J Basic Microbiol 56(1), 67-77.

Archana DS, MS Nandish, VP Savalagi & AR Alagawadi (2012). Screening of potassium solubilizing bacteria (KSB) for plant growth promotional activity. Life Sci 9(6), 627-630.

Badar MA, AM Shafei & ESH Sharaf (2006). The dissolution of K and P-bearing minerals by silicate dissolving bacteria and their effect on sorghum growth. J Agric Biol Sci 2(2), 5-11.

Basak BB & DR Biswas (2012). Modification of Waste Mica for Alternative Source of Potassium: Evaluation of Potassium Release in Soil from Waste Mica Treated with Potassium Solubilizing Bacteria (KSB). India, LAP LAMBERT Academic Publishing.

Etesami H, S Emami & HA Alikhani (2017). Potassium solubilizing bacteria (KSB): Mechanisms, promotion of plant growth, and future prospects. J Soil Sci Plant Nutr 17(4), 897-911.

Ginting RCB, R. Saraswati & E Husen (2016). Bakteri pelarut fosfat (Pengantar). Diunduh dari http://www.anakagronomy.com/2016/01/

bakteri-pelarut-fosfat-pengantar.html. [15 Mei 2016].

Glick BR (2012). Plant growth-promoting bacteria: mechanisms and applications. Scientifica 2(1), 34-39.

Huang Z, L He, XF Sheng & Z He (2013). Weathering of potash feldspar by Bacillus sp. L11. Acta Microbiol Sin J 5(3), 1172-1178.

Irawan, D Setyorini & S Rochayati (2017). Proyeksi kebutuhan pupuk sektor pertanian melalui pendekatan sistem dinamis. Bogor, Balai Penelitian Tanah.

Ismangil & E Hanudin (2005). Degradasi mineral batuan oleh asam-asam organik. J Ilmu Tanah dan Lingkungan 5 (1), 1-17.

Johnston AE (2013). Understanding potassium and its use in agricuture. United Kingdom, European Fertilizer Manufactures Association.

Kukiattrakoon B, C Hentrakool & UK Leggat (2010). Elemental and surface changes of fluorapatite-leucite porcelain upon immersion in acidic agent, J Dental Sci (5), 189-200.

Liu W, X Xu, X Wu, Q Yang, Y Luo, P Christie (2006). Decomposition of silicate minerals by Bacillus mucilaginosus in liquid culture. Env Geochem Health 28 (1), 133-140.

Man LY, XY Cao & DS Sun (2014). Effect of potassium-solubilizing bacteria-mineral contact mode on decomposition behavior of potassium-rich shale. China J Nonferrous Met 2(4), 48-52.

Marista E, K Siti & L Riza (2013). Bakteri pelarut fosfat hasil isolasi dari tiga jenis tanah rizosfer tanaman pisang nipah (Musa paradisiaca var nipah) di Kota Singkawang, Protobiont 2 (2), 93-101.

Meena VS, BR Maurya, JP Verma, & RS Meena. 2016. Potassium Solubilizing Microorganisms for Sustainable Agriculture. India, Springer India.

Mo B & B Lian (2011). Interaction between Bacillus mucilaginosus and silicate minerals (weathered adamellite and feldspar): weathering rate, products, and reaction mechanisms. Chinese J Geochem 30(1), 187-192.

Nath D, BR Maurya & VS Meena (2017). Documentation of five potassium and phosphorus solubilizing bacteria for their K and P-solubilization ability from various minerals. Biocatal Agric Biotechnol 10, 174-181.

Nugroho PA (2015). Dinamika hara kalium dan pengelolaannya di perkebunan karet. Warta Perkaretan 34(2), 89-102.

Padma SD & J Sukumar (2015). Respones of mulberry to inoculation of potash mobilizing bacterial isolate and other bio-inoculants. Global J Biosci Biotechnol 4(1), 50-53.

Parmar P & SS Sindhu (2013). Potassium solubilization by rhizosphere bacteria: influence of nutritional and environmental conditions. J Microbiol 3(1), 25-31.

Setiawati TC & L Mutmainnah (2016). Solubilizing of potassium containing mineral by microorganisms from sugarcane rhizosphere. Procedia. 9, 108-117.

Setiawati TC, M Mandala & MH Pandutama (2017). Bioleaching agromineral fosfat dan kalium oleh mikrobia fungsional dan asam humik guna peningkatan ketersediaan hara P dan K tanah. Penelitian Unggulan Perguruan Tinggi. Jember. Universitas Jember.

Saha M, BR Maurya, VS Meena, I Bahadur & A Kumar (2016). Identification and Characterization of potassium solubilising bacteria (KSB) from indo-gangetic Plains of India. Biocatal Agric Biotechnol 7, 202-209.

Santi LP & DH Goenadi (2017). Solubilization of silicate from quartz mineral by potential silicate solubilizing bacteria. Menara Perkebunan 85(2), 95-104.

Santi LP, DH Goenadi, Siswanto, I Sarlah & Isroi (2000). Solubilization of insoluble phosphates by Aspergillus niger. Menara Perkebunan 68(1), 39-52.

Shanware AS, SA Kalkar & MM Trivedi (2014). Potassium solubilisers: occurrence, mechanism and their role as competent biofertilizers. Curr Microbiol App Sci 3 (9), 622-629.

Shelobolina E, H Xu, H Konishi, R Kukkadapu, T Wu, M Blothe & E Roden (2012). Microbial lithotrophic oxidation of structural Fe (II) in biotite. App Env Microbiol 78(1), 5746-5752.

Sheng XF & LY He (2006). Solubilization of potassium bearing minerals by a wild- type strain of Bacillus edaphicus and its mutants and increased potassium uptake by wheat. Can J Microbiol. 52(1), 66-72.

Straaten, VP (2002). Rocks for crops: Agrominerals of sub-saharan Africa. Canada, University of Guelph.

Tekmira (2016) Teknologi mineral dan batubara. Feldspar [internet]. Diunduh dari :http://www.tekmira.esdm.go.id/data/Feldspar/ulasan.asp?xdir=Feldspa&commId=12&comm=Feldspar [31 November 2017].

Wahyudi A & T Wahyudi (2013). Literature study of benefiting k-bearing silicate rocks as raw materials for potassium fertilizer. Indonesian Mining J 16(2), 101 – 110.

Widiastuti H, DH Goenadi, T Panji, LP Santi, P Faturachim, N Mardiana, I Harianto & Isroi. (2000). Bioactivation of phosfate rocks by Indigenous phosphate-solubilizing fungi. Menara Perkebunan 68(1), 39-52.

Xiao Y, X Wang, W Chen & Q Huang (2017). Isolation and identification of three potassium-solubilizing bacteria from rape rhizospheric soil and their effects on ryegrass. Geomicrobiol J 1(1), 1-8.

Zhang C & F Kong (2014). Isolation and identification of potassium-solubilizing bacteria from tobacco rhizospheric soil and their effect on tobacco plants. Appl Soil Ecol 82(1), 18-25.

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Submitted

31-03-2019

Accepted

06-10-2019

Published

31-10-2019

How to Cite

KURNIATA, M. J., SETIAWATI, T. C., & JAYUS, J. (2019). Pelarutan P dan K dari batuan leusit dan apatit menggunakan kombinasi senyawa humat-BPF-BPK. Menara Perkebunan, 87(2). https://doi.org/10.22302/iribb.jur.mp.v87i2.330

Issue

Vol. 87 No. 2 (2019): 87 (2), 2019

Section

Articles

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Authors retain copyright and grant the journal right of first publication with the work simultaneously licensed under a Creative Commons Attribution License that allows others to share the work with an acknowledgement of the work's authorship and initial publication in this journal.