花改場--滿江紅取代田菁作為宜蘭休耕綠肥之減碳效益評估--09 - 農業知識入口網

參考文獻

1.      李祿豐 1999 氣象因素對宜蘭地區水稻產量之影響 花蓮區研究彙報 17：93-102。

2.      經濟部產發署 2025 114 年經濟部產業發展署 iPAS 低碳化精修班公版教材(114 年 1 月版) 產業節能減碳資訊網。https://ghg.tgpf.org.tw/CVData/CVData_more?id=a69e3f7686054dfabffd8e7c3b8c95fd

3.      Adhya, T.K., K. Bharati, S.R. Mohanty, B. Ramakrishnan, V.R. Rao, N. Sethunathan and R. Wassmann 2000 Methane emission from rice fields at Cuttack, India. Nutrient Cycling in Agroecosystems 58(1-3):95-105.

4.      Ali, M.A., P.J. Kim and K. Inubushi 2015 Mitigating yield-scaled greenhouse gas emissions through combined application of soil amendments: A comparative study between temperate and subtropical rice paddy soils. Science of the Total Environment 529:140-148.

5.      Chen, G.X., G.H. Huang, B. Huang, K.W. Yu, J. Wu and H. Xu 1997 Nitrous oxide and methane emissions from soil-plant systems. Nutrient Cycling in Agroecosystems 49(1-3):41-45.

6.      Chin, K.J., Lukow, T., Conrad, R. 1999. Effect of temperature on structure and function of the methanogenic archaeal community in an anoxic rice field soil. Applied and Environmental Microbiology 65(6):2,341-2,349.

7.      Fatma, Y.S., I. Rusmana and A.T. Wahyudi 2021. Community structure of total bacteria and methane emission-related prokaryotes in the rice fields applied with urea and biofertilizer. Asian Journal of Agriculture and Biology 2021(02).

8.      Fey, A., Conrad, R. 2000. Effect of temperature on carbon and electron flow and on the archaeal community in methanogenic rice field soil. Applied and Environmental Microbiology 66(11):4,790-4,797.

9.      Humphreys, J., K.R. Brye, C. Rector and E.E. Gbur 2019 Methane emissions from rice across a soil organic matter gradient in Alfisols of Arkansas, USA. Geoderma Regional 16: e00200.

10.   Ji, C., J. Wang, C. Xu, Y. Gu, J. Yuan, D. Liang, L. Wang, Y. Ning, J. Zhou and Y. Zhang 2024 Amendment of straw with decomposing inoculants benefits the ecosystem carbon budget and carbon footprint in a subtropical wheat cropping field. Sci Total Environ 923:171,419.

11.   Kimani, S.M., W.G. Cheng, T. Kanno, T. Nguyen-Sy, R. Abe, A.Z. Oo, K. Tawaraya and S. Sudo 2018 Azolla cover significantly decreased CH4 but not N2O emissions from flooding rice paddy to atmosphere. Soil Science and Plant Nutrition 64(1):68-76.

12.   Lauren, J.G. 1994. Isotopic Studies of Azolla and Nitrogen Fertilization of Rice. Journal of Environmental Quality 23(5):1,121-1,122.

13.   Le Mer, J. and P. Roger 2001 Production, oxidation, emission and consumption of methane by soils: A review. European Journal of Soil Biology 37(1):25-50.

14.   Losada, J.M., J.M. G. Hol, C. Rappoldt and J. Dolfing 2007 Precise soil management as a tool to reduce CH4 and N2O emissions from agricultural soils.

15.   Ma, Y., C. Tong, W. Wang and C. Zeng 2012 Effect of Azolla on CH4 and N2O emissions in Fuzhou Plain paddy fields. Zhongguo Shengtai Nongye Xuebao / Chinese Journal of Eco-Agriculture 20(6):723-727.

16.   Malyan, S.K., A. Bhatia, S.S. Kumar, R.K. Fagodiya, A. Pugazhendhi and P. A. Duc 2019 Mitigation of greenhouse gas intensity by supplementing with Azolla and moderating the dose of nitrogen fertilizer. Biocatalysis and Agricultural Biotechnology 20:101,266.

17.   Malyan, S.K., A. Bhatia, R. Tomer, R.C. Harit, N. Jain, A. Bhowmik and R. Kaushik 2021 Mitigation of yield-scaled greenhouse gas emissions from irrigated rice through Azolla, Blue-green algae, and plant growth-promoting bacteria. Environmental Science and Pollution Research 28(37):51,425-51,439.

18.   Oertel, C., J. Matschullat, K. Zurba, F. Zimmermann and S. Erasmi 2016 Greenhouse gas emissions from soils-A review. Geochemistry 76(3):327-352.

19.   van der Gon, H.A.C.D. and H. U. Neue 1995 Influence of organic matter incorporation on the methane emission from a wetland rice field. Global Biogeochemical Cycles 9(1):11-22.

20.   van der Steen, N.P., P. Nakiboneka, L. Mangalika, A.V.M. Ferrer and H.J. Gijzen 2003 Effect of duckweed cover on greenhouse gas emissions and odour release from waste stabilisation ponds. Water Science and Technology 48(2):341-348.

21.   Vlek, P.L.G., M.Y. Diakite and H. Mueller 1996 The role of Azolla in curbing ammonia volatilization from flooded rice systems. Nitrogen Economy in Tropical Soils: Proceedings of the International Symposium on Nitrogen Economy in Tropical Soils, held in Trinidad, W.I., January 9-14, 1994. N. Ahmad. Dordrecht, Springer Netherlands: 165-174.

22.   Wang, Y., Z. Hu, B. Gu, J. Xing, X. Hu and Y. Xu 2024 Reduced nitrogen fertilizer application mitigated CH4 fluxes from rice paddies under an elevated CO2 concentration. Journal of Soils and Sediments 24(8):3,028-3,040.

23.   Xu, H.S., B. Zhu, J.N. Liu, D.Y. Li, Y.D. Yang, K. Zhang, Y. Jiang, Y.G. Hu and Z.H. Zeng 2017 Azolla planting reduces methane emission and nitrogen fertilizer application in double rice cropping system in southern China. Agronomy for Sustainable Development 37(4).

24.   Yagi, K. and K. Minami 1990 Effect of organic matter application on methane emission from some Japanese paddy fields. Soil Science and Plant Nutrition 36(4):599-610.

25.   Yang, Y., F. Yao, Y. Sun, Z. Yang, R. Li, G. Bai, W. Lin and H. Chen 2024 Appropriately Reduced Nitrogen and Increased Phosphorus in Ratooning Rice Increased the Yield and Reduced the Greenhouse Gas Emissions in Southeast China. Plants 13 DOI: 10.3390/plants13030438.

26.   Ying, Z., P. Boeckx, G.X. Chen and O. Van Cleemput 2000 Influence of Azolla on CH4 emission from rice fields. Nutrient Cycling in Agroecosystems 58(1-3):321-326.