Araştırma Makalesi
BibTex RIS Kaynak Göster
Yıl 2021, Cilt: 10 Sayı: 3, 38 - 47, 31.12.2021

Öz

Kaynakça

  • Akça, M.O., Usta, S., Uygur, V., & Ok, S. S. (2020). Some Characterization Properties of Biochar Obtained From Rice Straw,/Toprak Bilimi ve Bitki Besleme Dergisi 8(2) 86-97.
  • Akdeniz, N. (2019). A systematic review of biochar use in animal waste composting, Waste Management, 88, 291-300. Anonim, 2021 https://isparta.tarimorman.gov.tr/Menu/27/Bitkisel-Uretim-Ve-Bitki-Sagligi.
  • Dursun, N. (2020). Determination of Animal and Vegetable Wastes-Based Biochar Production Potential: The Case of Malatya Province, Journal of Engineering Sciences and Design, 8(3), 720-727.
  • El-Naggar, A., Lee, S.S., Rinklebe, J., Farooq, M., Song, H., Sarmah, A.K., Zimmerman, A.R., Ahmad, M., Shaheen, S.M., & Ok, Y.S. (2019). Biochar application to low fertility soils: a review of current status, and future prospects, Geoderma, 337, 536-554
  • Huang, Q., Song, S., Chen, Z., Hu, B., Chen, J., & Wang X. (2019) Biochar-based materials and their applications in removal of organic contaminants from wastewater: state-of-the-art review Biochar, 1(1),45-73.
  • Kantarli, İ. C., Kabadayi, A., Ucar, S., & Yanik, J. (2016). Conversion of poultry wastes into energy feedstocks, Waste Management, 56, 530-539.
  • Lee Y., Park, J., Ryu, C., Ki Seop Gang, K.S., Yang, W., Park, Y.K., Jung, J. 2013a. Seunghun Hyun Comparison of biochar properties from biomass residues produced by slow pyrolysis at 500 C. Bioresource Technology, 148 (2013) 196–201.
  • Lehmann, J., & Joseph S. 2009. Biochar for Environmental Management. ISSBN: 978-1-84407- 658-1
  • LIFE 03 TCY/TR/000061. A Guide on Exploitation of Agricultural Residues in Turkey. Exploitation of Agricultural Residues in Turkey, EU-Life Programme Project, Final Report ANNEX XIV, 686-761.
  • Manolikaki I., & Diamadopoulos E. (2019). Positive effects of biochar and biochar-compost on maize growth and nutrient availability in two agricultural soils. Communications in Soil Science and Plant Analysis, 50(5), 512-526.
  • Manya, J. J., Gonzalez, B., Azuara, M., & Arner, G. (2018). Ultra-microporous adsorbents prepared from vine shoots-derived biochar with high CO2 uptake and CO2/N2 selectivity. Chem. Eng. J., 345, 631–639.
  • Masnadi, M.S., Habibi, R., Kopyscinski, J., Hill, J.M., Bi, X., Lim, C.J., Ellis, N., & Grace, J. R. (2014). Fuel characterization and co-pyrolysis kinetics of biomass and fossil fuels. Fuel, 117, 1204-1214.
  • Quan, C., Gao, N., & Song, Q. (2016). Pyrolysis of biomass components in a TGA and a fixed-bed reactor:Thermochemical behaviors, kinetics, and product characterization. Journal of Analytical and Applied Pyrolysis, 121, 84–92.
  • Rehman, A., Nawaz, S., Alghamdi, H. A., Alrumman, S.,Yan, W., & Nawaze, M. Z. (2020). Effects of manure-based biochar on uptake of nutrients and water holding capacity of different types of soils, 2, 1-4.
  • Rodriguez, J.A., Lustosa Filho, J.F., Melo, L.C.A., de Assis, I.R., & de Oliveira, T.S. (2021) Co-pyrolysis of agricultural and industrial wastes changes the composition and stability of biochars and can improve their agricultural and environmental benefits, Journal of Analytical and Applied Pyrolysis, 155,1-12.
  • Sümer, S. K., Kavdır, Y., & Çiçek G. (2016). Determining The Potential of Biochar Production from Agricultural and Livestock Wastes in Turkey, KSU J. Nat. Sci., 19(4), 379-387.
  • Tanczuk, M., Junga, R., Werle, S., Chabiński, M., & Ziółkowski, Ł. (2019). Experimental analysis of the fixed bed gasification process of the mixtures of the chicken manure with biomass. Renewable Energy, 136, 1055-1063.
  • Tripathi, M., Sahu, J.N., & Ganesan, P. (2016). Effect of process parameters on production of biochar from biomass waste through pyrolysis: A review. Renewable and Sustainable Energy Reviews, 55, 467–481.
  • TÜİK, Veritabanları, Tarım. http://www.tuik.gov.tr/PreTabloArama.do. (Erişim Tarihi:01.05.2021).
  • Uzoma, K.C., Inoue, M., Andry, H., Fujimaki, H., Zahoor, A., & Nishihara, E. (2011). Effect of cow manure biochar on maize productivity under sandy soil condition. Soil Use and Management, 27, 205-212.
  • Vu Ly, H., Kim, S.S., Woo, H.C., Choi, J.H., Suh, D.J., & Kim, J. (2015). Fast pyrolysis of macroalga Saccharina japonica in a bubbling fluidizedbed reactor for bio-oil production. Energy, 93, 1436-1446.
  • Zornoza, R., Moreno-Barriga, F., Acosta, J.A., Munoz, M.A., & Faz, A. (2016). Stability, nutrient availability and hydrophobicity of biochars derived from manure, crop residues, and municipal solid waste for their use as soil amendments. Chemosphere, 144, 122-130

Biochar production potential analysis of Isparta, Turkey for 2019-2020

Yıl 2021, Cilt: 10 Sayı: 3, 38 - 47, 31.12.2021

Öz

Biochar has been researched globally and is not recognized enough in Turkey. Biohar has many advantages, such as carbon retention, reducing greenhouse gas emissions, soil improvement, and improving crop productivity. In this study, the potential for conversion of agricultural and animal wastes of Isparta,Turkey to biomass was theoretically calculated. Data from the Turkish Statistical Institute for 2019 and 2020 were used to determine the biochar conversion potential. Calculations were made separately for each year and the results were compared. In 2019, it was determined that the total biochar conversion potential value of agricultural and animal production wastes was 42383 tons and in 2020 it was determined that this value was 43592 tons. When the average of both years is taken, approximately 42988 tons of biochar have been obtained annually. Considering the proportional change in biochar production in 2020 compared to 2019, it is seen that there is an increase of approximately 3%.

Kaynakça

  • Akça, M.O., Usta, S., Uygur, V., & Ok, S. S. (2020). Some Characterization Properties of Biochar Obtained From Rice Straw,/Toprak Bilimi ve Bitki Besleme Dergisi 8(2) 86-97.
  • Akdeniz, N. (2019). A systematic review of biochar use in animal waste composting, Waste Management, 88, 291-300. Anonim, 2021 https://isparta.tarimorman.gov.tr/Menu/27/Bitkisel-Uretim-Ve-Bitki-Sagligi.
  • Dursun, N. (2020). Determination of Animal and Vegetable Wastes-Based Biochar Production Potential: The Case of Malatya Province, Journal of Engineering Sciences and Design, 8(3), 720-727.
  • El-Naggar, A., Lee, S.S., Rinklebe, J., Farooq, M., Song, H., Sarmah, A.K., Zimmerman, A.R., Ahmad, M., Shaheen, S.M., & Ok, Y.S. (2019). Biochar application to low fertility soils: a review of current status, and future prospects, Geoderma, 337, 536-554
  • Huang, Q., Song, S., Chen, Z., Hu, B., Chen, J., & Wang X. (2019) Biochar-based materials and their applications in removal of organic contaminants from wastewater: state-of-the-art review Biochar, 1(1),45-73.
  • Kantarli, İ. C., Kabadayi, A., Ucar, S., & Yanik, J. (2016). Conversion of poultry wastes into energy feedstocks, Waste Management, 56, 530-539.
  • Lee Y., Park, J., Ryu, C., Ki Seop Gang, K.S., Yang, W., Park, Y.K., Jung, J. 2013a. Seunghun Hyun Comparison of biochar properties from biomass residues produced by slow pyrolysis at 500 C. Bioresource Technology, 148 (2013) 196–201.
  • Lehmann, J., & Joseph S. 2009. Biochar for Environmental Management. ISSBN: 978-1-84407- 658-1
  • LIFE 03 TCY/TR/000061. A Guide on Exploitation of Agricultural Residues in Turkey. Exploitation of Agricultural Residues in Turkey, EU-Life Programme Project, Final Report ANNEX XIV, 686-761.
  • Manolikaki I., & Diamadopoulos E. (2019). Positive effects of biochar and biochar-compost on maize growth and nutrient availability in two agricultural soils. Communications in Soil Science and Plant Analysis, 50(5), 512-526.
  • Manya, J. J., Gonzalez, B., Azuara, M., & Arner, G. (2018). Ultra-microporous adsorbents prepared from vine shoots-derived biochar with high CO2 uptake and CO2/N2 selectivity. Chem. Eng. J., 345, 631–639.
  • Masnadi, M.S., Habibi, R., Kopyscinski, J., Hill, J.M., Bi, X., Lim, C.J., Ellis, N., & Grace, J. R. (2014). Fuel characterization and co-pyrolysis kinetics of biomass and fossil fuels. Fuel, 117, 1204-1214.
  • Quan, C., Gao, N., & Song, Q. (2016). Pyrolysis of biomass components in a TGA and a fixed-bed reactor:Thermochemical behaviors, kinetics, and product characterization. Journal of Analytical and Applied Pyrolysis, 121, 84–92.
  • Rehman, A., Nawaz, S., Alghamdi, H. A., Alrumman, S.,Yan, W., & Nawaze, M. Z. (2020). Effects of manure-based biochar on uptake of nutrients and water holding capacity of different types of soils, 2, 1-4.
  • Rodriguez, J.A., Lustosa Filho, J.F., Melo, L.C.A., de Assis, I.R., & de Oliveira, T.S. (2021) Co-pyrolysis of agricultural and industrial wastes changes the composition and stability of biochars and can improve their agricultural and environmental benefits, Journal of Analytical and Applied Pyrolysis, 155,1-12.
  • Sümer, S. K., Kavdır, Y., & Çiçek G. (2016). Determining The Potential of Biochar Production from Agricultural and Livestock Wastes in Turkey, KSU J. Nat. Sci., 19(4), 379-387.
  • Tanczuk, M., Junga, R., Werle, S., Chabiński, M., & Ziółkowski, Ł. (2019). Experimental analysis of the fixed bed gasification process of the mixtures of the chicken manure with biomass. Renewable Energy, 136, 1055-1063.
  • Tripathi, M., Sahu, J.N., & Ganesan, P. (2016). Effect of process parameters on production of biochar from biomass waste through pyrolysis: A review. Renewable and Sustainable Energy Reviews, 55, 467–481.
  • TÜİK, Veritabanları, Tarım. http://www.tuik.gov.tr/PreTabloArama.do. (Erişim Tarihi:01.05.2021).
  • Uzoma, K.C., Inoue, M., Andry, H., Fujimaki, H., Zahoor, A., & Nishihara, E. (2011). Effect of cow manure biochar on maize productivity under sandy soil condition. Soil Use and Management, 27, 205-212.
  • Vu Ly, H., Kim, S.S., Woo, H.C., Choi, J.H., Suh, D.J., & Kim, J. (2015). Fast pyrolysis of macroalga Saccharina japonica in a bubbling fluidizedbed reactor for bio-oil production. Energy, 93, 1436-1446.
  • Zornoza, R., Moreno-Barriga, F., Acosta, J.A., Munoz, M.A., & Faz, A. (2016). Stability, nutrient availability and hydrophobicity of biochars derived from manure, crop residues, and municipal solid waste for their use as soil amendments. Chemosphere, 144, 122-130
Toplam 22 adet kaynakça vardır.

Ayrıntılar

Birincil Dil İngilizce
Konular Mühendislik
Bölüm Araştırma Makaleleri
Yazarlar

Kazım Kumaş 0000-0002-2348-4664

Ragıp Yıldırım 0000-0003-0902-3420

Ali Özhan Akyüz

Erken Görünüm Tarihi 31 Aralık 2021
Yayımlanma Tarihi 31 Aralık 2021
Yayımlandığı Sayı Yıl 2021 Cilt: 10 Sayı: 3

Kaynak Göster

APA Kumaş, K., Yıldırım, R., & Akyüz, A. Ö. (2021). Biochar production potential analysis of Isparta, Turkey for 2019-2020. Gaziosmanpaşa Bilimsel Araştırma Dergisi, 10(3), 38-47.
AMA Kumaş K, Yıldırım R, Akyüz AÖ. Biochar production potential analysis of Isparta, Turkey for 2019-2020. GBAD. Aralık 2021;10(3):38-47.
Chicago Kumaş, Kazım, Ragıp Yıldırım, ve Ali Özhan Akyüz. “Biochar Production Potential Analysis of Isparta, Turkey for 2019-2020”. Gaziosmanpaşa Bilimsel Araştırma Dergisi 10, sy. 3 (Aralık 2021): 38-47.
EndNote Kumaş K, Yıldırım R, Akyüz AÖ (01 Aralık 2021) Biochar production potential analysis of Isparta, Turkey for 2019-2020. Gaziosmanpaşa Bilimsel Araştırma Dergisi 10 3 38–47.
IEEE K. Kumaş, R. Yıldırım, ve A. Ö. Akyüz, “Biochar production potential analysis of Isparta, Turkey for 2019-2020”, GBAD, c. 10, sy. 3, ss. 38–47, 2021.
ISNAD Kumaş, Kazım vd. “Biochar Production Potential Analysis of Isparta, Turkey for 2019-2020”. Gaziosmanpaşa Bilimsel Araştırma Dergisi 10/3 (Aralık 2021), 38-47.
JAMA Kumaş K, Yıldırım R, Akyüz AÖ. Biochar production potential analysis of Isparta, Turkey for 2019-2020. GBAD. 2021;10:38–47.
MLA Kumaş, Kazım vd. “Biochar Production Potential Analysis of Isparta, Turkey for 2019-2020”. Gaziosmanpaşa Bilimsel Araştırma Dergisi, c. 10, sy. 3, 2021, ss. 38-47.
Vancouver Kumaş K, Yıldırım R, Akyüz AÖ. Biochar production potential analysis of Isparta, Turkey for 2019-2020. GBAD. 2021;10(3):38-47.