References

AMEC 2006. The Beneficial Use of Waste. A report submitted to Alberta Environment. 162 p.

Busato, J.G., dos Santos, L.F., de Paula, A.M., Sodre, F.F., de Oliveira, A.L., Dobbss, L.B., Martins, E.D. and Jindo, K. 2022. Can co-application of silicate rock powder and humic-like acids increase nutrient uptake and plant growth in weathered tropical soil? Acta Agriculturae Scandinavica Section B-Soil and Plant Science. 72: 761-774.

Chang, X.C. and Juma, N.G. 1996. Impact of crop rotations on microbial biomass, faunal populations, and plant C and N in a Gray Luvisol (Typic Cryoboralf). Biology and Fertility of Soils. 22: 31-39.

Dietrich, M, Fongen, M. and Foereid, B. 2020. Greenhouse gas emissions from digestate in soil. International Journal of Recycling of Organic Waste in Agriculture 9: 1-19.

Gross, C.D., Bork, E.W., Carlyle, C.N. and Chang, S.X. 2022. Biochar and its manure-based feedstock have divergent effects on soil organic carbon and greenhouse gas emissions in croplands. Science of the Total Environment. 806, 151337.

Shaaban, M., Wu, Y., Wu, L., Hu, R., Younas, A., Núñez-Delgado, A., Xu, P., Sun, Z., Lin, S., Xu, X., & Jiang, Y. (2020). The Effects of pH Change through Liming on Soil N2O Emissions. Processes. https://doi.org/10.3390/pr8060702.

Ivezic, V., Zebec, V., Popovic, B., Engler, M., Teklic, T., Loncaric, Z. and Karalic, K. 2021. Potential of industrial by-products as liming materials and digestate as organic fertilizer and their effect on soil properties and yield of alfalfa (Medicago sativa L.). Sustainability, 13, 11016.

Kishor, M., Jayakumar, M., Gokavi, N., Mukharib, D.S., Raghuramulu, Y. and Pillai, S.U. Humic acid as foliar and soil application improve the growth, yield and quality of coffee (cv. C x R) in Western Ghats of India. Journal of the Science of Food and Agriculture 101: 2273-2283

Maffia, A., Marra, F., Canino, F., Battaglia, S., Mallamaci, C., Oliva, M., & Muscolo, A. 2024. Humic Substances from Waste-Based Fertilizers for Improved Soil Fertility. Agronomy. https://doi.org/10.3390/agronomy14112657

Ma, B., Lyu, X.F., Cai, Y.J., Chang, S.X. and Dyck, M.F. 2018. Liming does not counteract the influence of long-term fertilization on soil bacterial community structure and its co-occurrence pattern. Soil Biology and Biochemistry 123: 45-53.

Mahadi, S., Alcock, J. and Li, X. 2021. Exploring Carbon Emission Reduction Potential using Cement Kiln Dust (CKD). A report prepared for Norstar Industries Ltd. by Viresco Solutions. 38 p.

Mosa, A., Taher, A., & Al-Jaberi, L. (2017). Improvement of poor subgrade soils using cement kiln dust. Case Studies in Construction Materials, 7, 138-143. https://doi.org/10.1016/j.cscm.2017.06.005

National Zero Waste Council 2021. Waste Prevention: The Environmental and Economic Benefits for Canada. 92 p. http://www.nzwc.ca/Documents/NZWC-WastePreventionReport.pdf

Pfülb, L., Elsgaard, L., Dörsch, P., Fuß, R., & Well, R. (2024). Impact of liming and maize residues on N2O and N2 fluxes in agricultural soils: an incubation study. Biology and Fertility of Soils. https://doi.org/10.1007/s00374-024-01825-w.

PSU 2022. Cement Kiln Dust. https://www.engr.psu.edu/ce/courses/ce584/concrete/library/materials/Altmaterials/Cement%20Kiln%20Dust.htm (accessed October 20, 2025)

Shaaban, M., Wu, Y., Wu, L., Hu, R., Younas, A., Núñez-Delgado, A., Xu, P., Sun, Z., Lin, S., Xu, X., & Jiang, Y. (2020). The Effects of pH Change through Liming on Soil N2O Emissions. Processes. https://doi.org/10.3390/pr8060702.

Rodd, A.V., MacLeod, J.A., Warman, P.R. and McRae, K.B. 2004. Surface application of cement kiln dust and lime to forages: Effect on soil pH. Canadian Journal of Soil Science 84: 317–322.

Rodd, A.V., McRae, K.B., MacLeod, J.A., Warman, P.R. and Grimmett, M.G. 2010. Surface application of cement kiln dust and lime to forage land: Effect on forage yield, tissue concentration and accumulation of nutrients. Canadian Journal of Soil Science 90: 201-213.

Statista 2022. https://www.statista.com/statistics/1168066/largest-waste-producing-countries-worldwide-per-capita/ (accessed October 13, 2025)

Sun, L., Chang, S.X., Feng, Y.S., Dyck, M.F. and Puurveen, D. 2015. Nitrogen fertilization and tillage reversal affected water-extractable organic carbon and nitrogen differentially in a Black Chernozem and a Gray Luvisol. Soil and Tillage Research 146: 253-260.

Sun, L., Feng, Y.S., Dyck, M., Puurveen, D. and Chang, S.X. 2020. Tillage reversal did not reverse N fertilization enhanced C storage in a Black Chernozem and a Gray Luvisol. Geoderma 370, 114355

USEPA 2022. Cement Kiln Dust Waste. https://archive.epa.gov/epawaste/nonhaz/industrial/special/web/html/index-2.html. (accessed October 15, 2025)

Valenzuela, E., & Cervantes, F. (2021). The role of humic substances in mitigating greenhouse gases emissions: Current knowledge and research gaps.. The Science of the total environment, 750, 141677. https://doi.org/10.1016/j.scitotenv.2020.141677