한국버섯학회지 (Journal of Mushroom)

  • 제18권3호
  • /
  • Pages.268-273
  • /
  • 2020
  • /
  • 1738-0294(pISSN)
  • /
  • 2288-8853(eISSN)
한국버섯학회 (The Korean Society of Mushroom Science)
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버섯수확후배지의 퇴비화에 따른 물리 화학적 변화 및 식물 생육 효과

Physicochemical changes and plant growth effect on composting of spent mushroom substrates

  • 송지민 (한경대학교 생명공학부 원예생명공학전공) ;
  • ;
  • 김자윤 (한경대학교 생명공학부 원예생명공학전공) ;
  • 강대선 ((주)케이글로벌) ;
  • 유정연 (한경대학교 생명공학부 원예생명공학전공) ;
  • 강희완 (한경대학교 생명공학부 원예생명공학전공)
  • Song, Ji-Min (Department of Holticultural Biotechnology, Division of Biotechnology, Hankyong National University) ;
  • Phong, Nguyen Hong (Department of Holticultural Biotechnology, Division of Biotechnology, Hankyong National University) ;
  • Kim, Ja-Yoon (Department of Holticultural Biotechnology, Division of Biotechnology, Hankyong National University) ;
  • Kang, Dae-Sun (K-Global Ltd.) ;
  • Yu, Jeong-Yeon (Department of Holticultural Biotechnology, Division of Biotechnology, Hankyong National University) ;
  • Kang, Hee-Wan (Department of Holticultural Biotechnology, Division of Biotechnology, Hankyong National University)
  • 투고 : 2020.09.05
  • 심사 : 2020.09.16
  • 발행 : 2020.09.30
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초록

표고(Lentinula edodes), 노루궁뎅이(Hericium erinaceus), 느타리(Pleurotus ostreatus)의 버섯수확후배지(spent mushroom substrate, SMS)를 퇴비화에 활용하였다. 퇴비화 온도변화는 50℃ 이상에서 7일에서 10일 동안 지속되어 30일에 부숙이 완료되었다. 퇴비화 된 LeCSMS, HeCSMS는 130%, 80% 무종자에 대한 종자 발아지수를 보여 부숙 도에 대한 종자 발아지수를 충족하였다. 퇴비화에 따른 물리 화학적 변화를 조사 한 바 pH 범위가 4-5에서 6-7로 증가 되었고 EC는 1-1.4 dS/m로 소폭 감소되었으며 유기질 함량은 LeCSMS에서 36.9%로 SMS에 비하여 60% 이상 가장 큰 폭으로 감소 되었다. LeCSMS를 기준으로 N (1.2%), P(2.3%), K(0.77%)함량이 조사되었으며 중금속은 모든 CSMS에서 기준치 이하였으며 Ca, Mg는 30%에서 60%이상 증가하였다. C/N비는 LeCSMS, HeCSMS에서 15% 낮았으나 PoSMS에서 32%로 높게 나타났다. LeCSMS 처리에 따른 고추 유묘 생육효과는 시판 유기퇴비 처리구 등 대조 구에 비하여 초장이 60%이상 높게 성장했으며 옆폭, 옆장, 옆수에서 다른 대조 구에 비하여 모두 우수한 생육 효과를 보였다.

This study aimed to assess the feasibility of composting spent mushroom substrate (SMS) materials of Lentinula edodes (Le), Hericium erinaceus (He), and Pleurotus ostreatus (Po). The different SMSs were composted for 7 to 10 days at high temperatures over 50℃; the composting procedure was completed in 30 days. A maturity test was conducted using the radish seed germination index and CoMMe-100. The composted SMS (CSMS) from Le and He showed gemination indices of 130% and 81%, respectively, that satisfied the criteria of maturity standard (gemination index over 70%) and the CoMMe-100 analysis. The physicochemical changes of CSMSs included an increase in the pH range from 4-5 to 6-7, slight reduction in the EC to 1-1.4 dS/m, and an organic content of 36.9% in LeCSMS. In LeCSMS, the contents of N, P, and K were 1.2%, 2.3%, and 0.77%, respectively, and heavy metals were detected below the standard value in all CSMSs; the Ca and Mg contents in the CSMSs were increased from 30% to 60% when compared to those in the SMSs. The C/N ratio (from 26-33) in LeSMS and HeSMS decreased to 15.3-15.9 in CSMSs. The growth effect of LeCSMS treatment on pepper seedlings was 60% higher than that in the control groups, one of which was treated with commercial organic compost; the former showed a superior growth effect on the leaf width, leaf length, and leaf number compared to other control groups. In conclusion, LeCSMS and HeCSMS could be utilized as compost resources capable of efficient soil amendment and plant growth promotion.

키워드

참고문헌

  1. Ben-Dor E, Banin A. 1989. Determination of organic matter content in arid-zone soils using a simple "loss-on-ignition" method. Commun Soil Sci Plant Anal 20: 75-1695. https://doi.org/10.1080/00103628909368175
  2. Brady NC. 1990. The nature and properties of soils. Macmillan, New York, USA.
  3. Bremner JM. 1965. Total nitrogen. In C. A. Black (ed.) Methods of Soil Analysis. American Society of Agronomy, Wisconsin, USA.
  4. Gonzalez-Marcos A, et al. 2014. Composting of spent mushroom substrate and winery Sludge. Comp Sci Ultiliz 23: 58-65.
  5. Jonathan SG, Lawal MM, Oyetunji OJ. 2011. Effect of spent mushroom compost of Pleurotus pulmonarius on growth performance of four Nigerian vegetables. Mycobiology 39: 164-169. https://doi.org/10.5941/MYCO.2011.39.3.164
  6. Kang DS, et al. 2017. Defense Response and Suppression of Phytophthora blight disease of pepper by water extract from spent mushroom substrate of Lentinula edodes. Plant Pathol J 33: 264-275. https://doi.org/10.5423/PPJ.OA.02.2017.0030
  7. Kang HW. 2019. Industrial utilization of spent mushroom substrate. J Mushrooms 17: 85-92.
  8. Kim EY, et al. 2016. Compost production using vegetable waste and spent oak mushroom substrate (SMS). J Mushrooms 14: 237-243. https://doi.org/10.14480/JM.2016.14.4.237
  9. Kwak AM, et al. 2016. Oxalic acid from Lentinula edodes: Antimicrobial activity on phytopathogenic bacteria and qualitative and quantitative analyses. Mycobiology 44: 338-342. https://doi.org/10.5941/MYCO.2016.44.4.338
  10. Lee CJ, et al. 2009. Applicability of spent mushroom media as horticultural nursery media. Kor J Soil Sci Fertil 42: 117-122.
  11. Lou Z, et al. 2017. Composition variability of spent mushroom substrates during continuous cultivation, composting process and their effects on mineral nitrogen transformation in soil. Geoderma 307: 30-37. https://doi.org/10.1016/j.geoderma.2017.07.033
  12. Paula FS, et al. 2017. Stabilisation of spent mushroom substrate for application as a plant growth-promoting organic amendment. J Environ Manage 196: 476-486. https://doi.org/10.1016/j.jenvman.2017.03.038
  13. Said-Pullicino D, Erriquens FG, Gigliotti G. 2007. Changes in the chemical characteristics of water-extractable organic matter during composting and their influence on compost stability and maturity. Bioresour Technol 98: 1822-1831. https://doi.org/10.1016/j.biortech.2006.06.018
  14. Suess A, Curtis J. 2006. Report: value-added strategies for spent mushroom substrate in BC. British Columbia Mushroom Industry, Columbia, UK. pp. 101.
  15. Uzun I. 2004. Use of spent mushroom compost in sustainable fruit production. J Fruit Ornam Plant Res 12: 157-165.
  16. Zhang L, Sun X. 2014. Changes in physical, chemical, and microbiological properties during the two-stage co-composting of green waste with spent mushroom compost and biochar. Bioresour Technol 171: 274-284. https://doi.org/10.1016/j.biortech.2014.08.079