Biocarbón derivado de excretas porcinas con capacidad de disminuir la disponibilidad de Pb en suelos agrícolas contaminados

Rita Jaqueline  Cabello-Torres; John Robert  Romero-Longwell; Lorgio  Valdiviezo-Gonzales; Rubén  Munive-Cerrón; Carlos Alberto  Castañeda-Olivera

doi:10.17268/sci.agropecu.2021.050

Autores/as

Rita Jaqueline Cabello-Torres Universidad César Vallejo, Escuela profesional de Ingeniería Ambiental, Campus San Juan de Lurigancho, Lima https://orcid.org/0000-0002-9965-9678
John Robert Romero-Longwell Universidad César Vallejo, Escuela profesional de Ingeniería Ambiental, Campus Los Olivos, Lima https://orcid.org/0000-0003-1917-6543
Lorgio Valdiviezo-Gonzales Universidad César Vallejo, Escuela profesional de Ingeniería Ambiental, Campus San Juan de Lurigancho, Lima https://orcid.org/0000-0002-8200-4640
Rubén Munive-Cerrón Universidad Nacional del Centro del Perú, Facultad de Agronomía, Huancayo https://orcid.org/0000-0001-8951-2499
Carlos Alberto Castañeda-Olivera Universidad César Vallejo, Escuela profesional de Ingeniería Ambiental, Campus Los Olivos, Lima https://orcid.org/0000-0002-8683-5054

DOI:

https://doi.org/10.17268/sci.agropecu.2021.050

Palabras clave:

excretas porcinas, biocarbón, disponibilidad de Pb, suelo contaminado, bioremediación

Resumen

El uso de enmiendas orgánicas mejora la calidad y aumenta la fertilidad de los suelos debido a sus propiedades de adsorción, estimula el ciclo de nutrientes y puede usarse para reducir la disponibilidad de metales pesados. El principal objetivo de la investigación fue evaluar el efecto del biocarbón (BC) derivado de las excretas porcinas sobre la disponibilidad de Pb en un suelo agrícola contaminado y encalado. Se aplicó un diseño experimental aleatorizado, las excretas de cerdo se secaron a temperatura ambiente (23 °C) y se pirolizaron a 500 °C durante 2 h. Se aplicaron dosis del 5%, 10% y 20% de BC a los suelos contaminados con Pb (165,7 mg/kg), que se dispusieron en macetas de 2 kg con excepción de la muestra control, y posteriormente se cultivó Lactuca sativa para evaluar la disponibilidad de Pb. Los resultados indicaron una mejora en la calidad del suelo a dosis más altas de BC, aumento de 0,34 unidades de pH, disminución de Pb extraído por EDTA (27% a 62% de disminución) y contenido no significativo de Pb en lixiviados (< 1 mg Pb/L) y sin detección en raíces de plantas (< 0,01 mg/kg), excepto para la planta de control (0,7 mg Pb/kg) en el suelo original. Se obtuvo un modelo relacional logarítmico entre la dosis de BC y el Pb adsorbido en el suelo (R² = 0,9938, p < 0,05) que muestra que la disminución de la disponibilidad de Pb en el suelo aumentó para dosis más altas de BC, lo que representa una alternativa de remediación ecológica. Se recomienda investigar las relaciones de interacción entre los parámetros de calidad del suelo y establecer modelos funcionales de bioacumulación y metal extraíble del suelo enmendado.

Citas

Adejumo, S. A., Arowo, D. O., Ogundiran, M. B., & Srivastava, P. (2020). Biochar in combination with compost reduced Pb uptake and enhanced the growth of maize in lead (Pb)-contaminated soil exposed to drought stress. Journal of Crop Science and Biotechnology, 23, 273–288.

Alaboudi, K. A., Ahmed, B., & Brodie, G. (2019). Effect of biochar on Pb, Cd and Cr availability and maize growth in artificial contaminated soil. Annals of Agricultural Sciences, 64, 95-102.

Antonangelo, J. A., & Zhang, H. (2019). Heavy metal phyto-availability in a contaminated soil of northeastern Oklahoma as affected by biochar amendment. Environmental Science and Pollution Research, 26, 33582–33593.

Awasthi, S. K., Liu, T., Awasthi, M. K., & Zhang, Z. (2020). Evaluation of biochar amendment on heavy metal resistant bacteria abundance in biosolids compost. Bioresource Technology, 306, 123114.

Boostani, H. R., Najafi-Ghiri, M., & Safizadeh, M. (2021). Can Addition of Biochar and Zeolite to a Contaminated Calcareous Soil Mitigate the Pb-toxicity Effects on Spinach (Spinacia Oleracea L.) Growth? Communications in Soil Science and Plant Analysis, 52(2), 136-148.

Gaurav, V. K., & Sharma, Ch. (2019). Estimating health risks in metal contaminated land for sustainable agriculture in peri-urban industrial areas using Monte Carlo probabilistic approach. Sustainable computing: informatics and systems, 28, 100310.

Hamid, Y., Tang, L., Hussain, B., Usman, M., Rehman Hashmi, M. L., et al. (2020). Immobilization and sorption of Cd and Pb in contaminated stagnic anthrosols as amended with biochar and manure combined with inorganic additives. Journal of Environmental Management, 257, 109999.

Han, L., Qian, L., Liu, R., Chen, M., Yan, J., & Hu, Q. (2017). Lead adsorption by biochar under the elevated competition of cadmium and aluminium. Scientific Reports, 7(1), 2264.

Heredia-Salgado, M. A., & Tarelho, A. C. (2018). Biochar produc-tion as an alternative for energetic valorization or residual biomass generated in the Ecuadorian agroindustrial sector. Boletín del Grupo Español del Carbón, 49, 6-11.

Instituto Nacional de Estadística e Informática (INEI). (2017). Compendio estadístico Perú 2017. Recuperado de: https://www.inei.gob.pe/media/MenuRecursivo/publicaciones_digitales/Est/Lib1483/cap19/cap19.pdf.

Instituto Nacional de Estadística e Informática (INEI). (2019). Población del Perú totalizó 31 millones 237 mil 385 personas al 2017. Nota de Prensa. Recuperado de: https://www.inei.gob.pe/prensa/noticias/poblacion-del-peru-totalizo-31-millones-237-mil-385-personas-al-2017-10817/

Jing, F., Chen X., Wen, X., Liu, W., Hu, S., et al. (2019). Biochar effects on soil chemical properties and mobilization of cadmium (Cd) and lead (Pb) in paddy soil. Soil Use Manage., 36, 320–327.

Kabiri, P., Motaghian, H., & Hosseinpur, A. (2021). Impact of Biochar on Release Kinetics of Pb (II) and Zn (II) in a Calcareous Soil Polluted with Mining Activities. Journal of Soil Science and Plant Nutrition, 21, 22–34.

Khan, A. Z., Ding, X., Khan, S., Ayaz, T., Fidel, R., & Khan, M. A. (2020a). Biochar efficacy for reducing heavy metals uptake by Cilantro (Coriandrum sativum) and spinach (Spinaccia oleracea) to minimize human health risk. Chemosphere, 244, 125543.

Khan, A. Z., Khan, S., Ayaz, T., Brusseau, M. L., Khan, M. A., et al. (2020b). Popular wood and sugarcane bagasse biochars reduced uptake of chromium and lead by lettuce from mine-contaminated soil. Environmental Pollution, 263, 114446.

Kiran, B. R., & Prasad, M. N. V. (2019). Biochar and rice husk ash assisted phytoremediation potentials of Ricinus communis L. for lead-spiked soils. Ecotoxicology and Environmental Safety, 183, 109574.

Lahori, A. H., Zhang, Z., Guo, Z., Li, R., Mahar, A., et al. (2017). Beneficial effects of tobacco biochar combined with mineral additives on (im)mobilization and (bio)availability of Pb, Cd, Cu and Zn from Pb/Zn smelter contaminated soils. Ecotoxicology and Environmental Safety, 145, 528–538.

Lebrun, M., Alidou Arzika, I., Miard, F., Nandillon, R., Bayçu, G., et al. (2020a). Effect of fertilization of a biochar and compost amended technosol: Consequence on Ailanthus altissima growth and As‐ and Pb‐specific root sorption. Soil Use and Management, 36, 766-772.

Lebrun, M., Van Poucke, R., Miard, F., Scippa, G. S., Bourgerie, S., et al. (2020b). Effects of carbon-based materials and redmuds on metal(loid) immobilization and growth of Salix dasyclados Wimm on a former mine technosol contaminated by arsenic and lead. Land Degradation and Development, 32, 467-481.

Liu, W., Huo, R., Xu, J., Liang, S., Li, J., et al. (2017). Effects of biochar on nitrogen transformation and heavy metals in sludge composting. Bioresource Technology, 235, 43-49.

Meng, J., Tao, M., Wang, L., Liu, X., & Xu, J. (2018). Changes in heavy metal bioavailability and speciation from a Pb-Zn mining soil amended with biochars from co-pyrolysis of rice straw and swine manure. Science of The Total Environment, 633, 300-307.

Ministerio de Energía y Minas de Perú. (2021). Producción minera anual 2011 - 2020. Recuperado de: http://www.minem.gob.pe/_estadistica.php?idSector=1&idEstadistica=12501.

Mitchell, K., Mendoza-González, C. V., Ramos-Gómez, M. S., Yamamoto‑Flores L., Guerrero‑Barrera A. L., et al. (2020). The effect of low-temperature biochar and its non-pyrolyzed composted biosolids source on the geochemical fractionation of Pb and Cd in calcareous river sediments. Environmental Earth Sciences, 79, 164.

Mujtaba, M. A., Liu, G., Yousaf, B., Ali, M. U., Abbas, Q., & Ullah, H. (2020). Synergistic effects of biochar and processed fly ash on bioavailability, transformation and accumulation of heavy metals by maize (Zea mays L.) in coal-mining contaminated soil. Chemosphere, 240, 124845.

Qin, P., Wang, H., Yang, X., He, L., Müller, K., et al. (2018). Bamboo- and pig-derived biochars reduce leaching losses of dibutyl phthalate, cadmium, and lead from co-contaminated soils. Chemosphere, 198, 450-459.

Rinklebe, J., Shaheen, S. M., El-Naggar, A., Wang, H., Du Laing, G., et al. (2020). Redox-induced mobilization of Ag, Sb, Sn, and Tl in the dissolved, colloidal and solid phase of a biochar-treated and un-treated mining soil. Environment International, 140, 105754.

Samsuri, A. W., Fahmi, A. H., Jol, H., & Daljit, S. (2019). Particle size and rate of biochar affected the phytoavailability of Cd and Pb by mustard plants grown in contaminated soils. International Journal of Phytoremediation, 1-11.

Sarwar, N., Imran, M., Shaheen, M. R., Ishaque, W., Kamran, M. A., Matloob, A., Rehimb, A., & Hussain, S. (2017). Phytoremediation strategies for soils contaminated with heavy metals: Modifi-cations and future perspectives. Chemosphere, 171, 710-721.

Tareq, R., Akter, N., & Azam, Md. S. (2019). Biochars and Biochar Composites: Low-Cost Adsorbents for Environmental Remediation. Biochar from Biomass and Waste. Fundamentals and Applications, 169-209.

Vejvodová, K., Száková, J., García-Sánchez, M., Praus, L., Romera, I. G., & Tlustoš, P. (2020). Effect of Dry Olive Residue–Based Biochar and Arbuscular Mycorrhizal Fungi Inoculation on the Nutrient Status and Trace Element Contents in Wheat Grown in the As-, Cd-, Pb-, and Zn-Contaminated Soils. Journal of Soil Science and Plant Nutrition, 20, 1067-1079.

Voca, H., Piscitelli, L., Mezzapesa, G. N., Mondelli, D., Miano, T., & D’Orazio, V. (2020). Biochar effect on crop performance and Pb and Zn uptake of tomato (Solanum lycopersicum, L.) plants grown on heavy metals contaminated Kosovo soils. Journal of Environmental Science and Health, Part B, 1–10.

Wang, T., Sun, H., Ren, X., Li, B., & Mao, H. (2017). Evaluation of biochars from different stock materials as carriers of bacterial strain for remediation of heavy metal-contaminated soil. Scientific Reports, 7(1), 12114.

Wang, L., Ok, Y. S., Tsang, D. C., Alessi, D. S., Rinklebe, J., et al. (2020). New trends in biochar pyrolysis and modification strategies: Feedstock, pyrolysis conditions, sustainability concerns and implications for soil amendment. Soil Use and Management, 1-29.

Wei, L., Huang, Y., Huang, L., Huang, Q., Li, Y., et al. (2021). Combined biochar and soda residues increase maize yields and decreases grain Cd/Pb in a highly Cd/Pb-polluted acid Udults soil. Agriculture, Ecosystems & Environment, 306, 107198.

Xu, P., Sun, C.-X., Ye, X.-Z., Xiao, W.-D., Zhang, Q., & Wang, Q. (2016). The effect of biochar and crop straws on heavy metal bioavailability and plant accumulation in a Cd and Pb polluted soil. Ecotoxicology and Environmental Safety, 132, 94–100.

Xu, X., Zhao, Y., Sima, J., Zhao, L., Mašek, O., & Cao, X. (2017). Indispensable role of biochar-inherent mineral constituents in its environmental applications: A review. Bioresource Technology, 241, 887-899.

Xu, W., Shafi, M., Penttinen, P., Hou, S., Wang, X., Ma, J., et al. (2019). Bioavailability of heavy metals in contaminated soil as affected by different mass ratios of biochars. Environmental Technology, 1-9.

Yang, X., Pan, H., Shaheen, S. M., Wang, H., & Rinklebe, J. (2021a). Immobilization of cadmium and lead using phosphorus-rich animal-derived and iron-modified plant-derived biochars under dynamic redox conditions in a paddy soil. Environment International, 156, 106628.

Yang, F., Wang, B., Shi, Z., Li, L., Li, Y., et al. (2021b) Immobilization of heavy metals (Cd, Zn, and Pb) in different contaminated soils with swine manure biochar. Environmental Pollutants and Bioavailability, 33(1), 55-65.

Zhang, M., Wang, J., Bai, S. H., Zhang, Y., Teng, Y., & Xu, Z. (2019a). Assisted phytoremediation of a co-contaminated soil with biochar amendment: Contaminant removals and bacterial community properties. Geoderma, 348, 115-123.

Zhang, Z., Zhu, Z., Shen, B., & Liu, L. (2019b). Insights into Biochar and Hydrochar Production and Applications: A Review. Energy, 171, 581-598.

Zhou, H., Meng, H., Zhao, L., Shen, Y., Hou, Y., et al. (2018). Effect of biochar and humic acid on the copper, lead, and cadmium passivation during composting. Bioresource Technology, 258, 279-286.

Zhuo, F., Zhang, X.-F., Lei, L.-L., Yan, T.-X., Lu, R.-R., et al. (2020). The effect of arbuscular mycorrhizal fungi and biochar on the growth and Cd/Pb accumulation in Zea mays. International Journal of Phytoremediation, 1-10.