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Physiological behaviour and nutritional status of coffee (Coffea arabica L. var. Castillo) trees in response to biochar application

Published online by Cambridge University Press:  29 June 2022

A. D. Sanchez-Reinoso
Affiliation:
Departamento de Agronomía, Facultad de Ciencias Agrarias, Universidad Nacional de Colombia, sede Bogotá, Carrera 30, No. 45-03, Bogotá 111321 Colombia
L. Lombardini
Affiliation:
Department of Horticulture, University of Georgia, Athens, GA, USA
H. Restrepo-Díaz*
Affiliation:
Departamento de Agronomía, Facultad de Ciencias Agrarias, Universidad Nacional de Colombia, sede Bogotá, Carrera 30, No. 45-03, Bogotá 111321 Colombia
*
Author for correspondence: H. Restrepo-Díaz, E-mail: [email protected]

Abstract

Applying coffee pulp biochar (BC) can be a complementary practice to the application of chemical fertilizers (CF) of crops; however, little evidence of its combined effects on coffee cultivation has been reported. A field trial was carried out during two evaluation years (2019 and 2020) to analyse the effect of the application of different BC doses (0, 4, 8 and 16 t/ha) in combination with four levels of fertilization (0, 33, 66 and 100% of the nutritional requirements) on physiological responses of 3-year-old coffee (Coffea arabica L. var. Castillo) trees. The results indicated that trees with 0 t/ha BC and 0% CF showed the lowest values in all the physiological variables studied (gs = 269.9 and 126.8 mmol/m2/s; Chl = 61.7 and 54.7 At-leaf readings; yield = 0.21 and 0.22 kg of dry parchment coffee (DPC)/tree for 2019 and 2020, respectively). Coffee trees treated with 8 t/ha BC and CF levels of 100% registered the highest results in gs (424.9 and 366.9 mmol/m2/s), Chl (71.1 and 69.8 At-leaf readings), yield (0.41 and 0.57 kg of DPC/tree) in 2019 and 2020, respectively. In conclusion, the application of BC from coffee pulp, especially at a dose of 8 t/ha, generates a positive effect on yield, gs, leaf nutrient concentration and Chl of coffee trees. The use of BC can be an alternative to complement the mineral nutrition of commercial coffee crops to help reduce the application of CF.

Type
Crops and Soils Research Paper
Copyright
Copyright © The Author(s), 2022. Published by Cambridge University Press

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References

Abbas, T, Rizwan, M, Ali, S, Zia-ur-Rehman, M, Qayyum, MF, Abbas, F and Ok, YS (2017) Effect of biochar on cadmium bioavailability and uptake in wheat (Triticum aestivum L.) grown in a soil with aged contamination. Ecotoxicology and Environmental Safety 140, 3747.CrossRefGoogle Scholar
Abbas, S, Javed, MT, Ali, Q, Chaudhary, HJ and Rizwan, M (2021) Alteration of plant physiology by the application of biochar for remediation of organic pollutants. In Handbook of Bioremediation. Faisalabad, Pakistan: Academic Press, pp. 475492.CrossRefGoogle Scholar
Akhtar, SS, Andersen, MN and Liu, F (2015) Residual effects of biochar on improving growth, physiology and yield of wheat under salt stress. Agricultural Water Management 158, 6168.CrossRefGoogle Scholar
Al-Wabel, MI, Hussain, Q, Usman, AR, Ahmad, M, Abduljabbar, A, Sallam, AS and Ok, YS (2018) Impact of biochar properties on soil conditions and agricultural sustainability: a review. Land Degradation and Development 29, 21242161.CrossRefGoogle Scholar
Arcila-Pulgarín, J, Buhr, L, Bleiholder, H, Hack, H, Meier, U and Wicke, H (2002) Application of the extended BBCH scale for the description of the growth stages of coffee (Coffea spp.). Annals of Applied Biology 141, 1927.CrossRefGoogle Scholar
Baiga, R and Rao, BKR (2017) Effects of biochar, urea and their co-application on nitrogen mineralization in soil and growth of Chinese cabbage. Soil Use and Management 33, 5461.CrossRefGoogle Scholar
Baker, NR (2008) Chlorophyll fluorescence: a probe of photosynthesis in vivo. Annual Review of Plant Biology 59, 89113.Google ScholarPubMed
Chinchilla-Soto, C, Durán-Quesada, AM, Monge-Muñoz, M and Gutiérrez-Soto, MV (2021) Quantifying the annual cycle of water use efficiency, energy and CO2 fluxes using micrometeorological and physiological techniques for a coffee field in Costa Rica. Forests 12, 889.CrossRefGoogle Scholar
Das, SK, Ghosh, GK and Avasthe, R (2020) Valorizing biomass to engineered biochar and its impact on soil, plant, water, and microbial dynamics: a review. Biomass Conversion and Biorefinery 10, 117.Google Scholar
Da Silveira, JS, Mertz, C, Morel, G, Lacour, S, Belleville, MP, Durand, N and Dornier, M (2020) Alcoholic fermentation as a potential tool for coffee pulp detoxification and reuse: analysis of phenolic composition and caffeine content by HPLC-DAD-MS/MS. Food Chemistry 319, 126600.CrossRefGoogle ScholarPubMed
Del Buono, D (2020) Can biostimulants be used to mitigate the effect of anthropogenic climate change on agriculture? It is time to respond. Science of the Total Environment 751, 141763.CrossRefGoogle ScholarPubMed
Di Rienzo, JA, Casanoves, F, Balzarini, MG, Gonzalez, L, Tablada, M and Robledo, CW (2016) InfoStatversion 2016. Grupo InfoStat, FCA, Universidad Nacional de Córdoba, Argentina. http://www.infostat.com.ar.Google Scholar
El-Mageed, A, Taia, A, Belal, EE, Rady, MO, El-Mageed, A, Shimaa, A and Semida, WM (2021) Acidified biochar as a soil amendment to drought stressed (Vicia faba L.) plants: influences on growth and productivity, nutrient status, and water use efficiency. Agronomy 11, 1290.CrossRefGoogle Scholar
Fajardo-Peña, I and Sanz-Uribe, J (2013) La calidad física y el rendimiento del café en los procesos de beneficio tradicional y beneficio ecológico: Becolsub. Cenicafé 323, 8p.Google Scholar
Farhangi-Abriz, S, Torabian, S, Qin, R, Noulas, C, Lu, Y and Gao, S (2021) Biochar effects on yield of cereal and legume crops using meta-analysis. Science of the Total Environment 775, 145869.CrossRefGoogle Scholar
Federación Nacional de Cafeteros de Colombia (2021) Estadísticas cafeteras. Revisado en julio de 2021. En: https://federaciondecafeteros.org/wp/27stadísticas-cafeteras/.Google Scholar
Fernández-Calleja, M, Monteagudo, A, Casas, AM, Boutin, C, Pin, PA, Morales, F and Igartua, E (2020) Rapid on-site phenotyping via field fluorimeter detects differences in photosynthetic performance in a hybrid – parent barley germplasm set. Sensors 20, 1486.CrossRefGoogle Scholar
Fofack, AD and Derick, EA (2020) Evaluating the bidirectional nexus between climate change and agriculture from a global perspective. World (Oakland, Calif) 6, 100.Google Scholar
Gao, Y, Shao, G, Lu, J, Zhang, K, Wu, S and Wang, Z (2020) Effects of biochar application on crop water use efficiency depend on experimental conditions: a meta-analysis. Field Crops Research 249, 107763.CrossRefGoogle Scholar
Gebre, T, Singh, S and Zewide, I (2021) Potato yield enhancement by combined use of NPS blended fertilizer and coffee husk biochar and its economic analysis. Tropical Agriculture 97, 240252.Google Scholar
Graber, ER, Harel, YM, Kolton, M, Cytryn, E, Silber, A, David, DR and Elad, Y (2010) Biochar impact on development and productivity of pepper and tomato grown in fertigated soilless media. Plant and Soil 337, 481496.CrossRefGoogle Scholar
Guo, X, Ji, Q, Rizwan, M, Li, H, Li, D and Chen, G (2020) Effects of biochar and foliar application of selenium on the uptake and subcellular distribution of chromium in Ipomoea aquatica in chromium-polluted soils. Ecotoxicology and Environmental Safety 206, 111184.CrossRefGoogle ScholarPubMed
Guo, L, Bornø, ML, Niu, W and Liu, F (2021) Biochar amendment improves shoot biomass of tomato seedlings and sustains water relations and leaf gas exchange rates under different irrigation and nitrogen regimes. Agricultural Water Management 245, 106580.CrossRefGoogle Scholar
Hussien-Ibrahim, ME, Adam-Ali, AY, Zhou, G, Ibrahim-Elsiddig, AM, Zhu, G, Ahmed-Nimir, NE and Ahmad, I (2020) Biochar application affects forage sorghum under salinity stress. Chilean Journal of Agricultural Research 80, 317325.CrossRefGoogle Scholar
Kammann, CI, Linsel, S, Gößling, JW and Koyro, HW (2011) Influence of biochar on drought tolerance of Chenopodium quinoa Willd and on soil–plant relations. Plant and Soil 345, 195210.CrossRefGoogle Scholar
Krall, JP and Edwards, GE (1992) Relationship between photosystem II activity and CO2 fixation in leaves. Physiologia Plantarum 86, 180187.CrossRefGoogle Scholar
Labouisse, JP, Bellachew, B, Kotecha, S and Bertrand, B (2008) Current status of coffee (Coffea arabica L.) genetic resources in Ethiopia: implications for conservation. Genetic Resources and Crop Evolution 55, 10791093.CrossRefGoogle Scholar
Lehmann, J and Joseph, S (2009) Introduction. Biochar for Environmental Management, 450.CrossRefGoogle Scholar
Lehmann, J, Rillig, MC, Thies, J, Masiello, CA, Hockaday, WC and Crowley, D (2011) Biochar effects on soil biota-a review. Soil Biology and Biochemistry 43, 18121836.CrossRefGoogle Scholar
Liao, X, Niu, Y, Liu, D, Chen, Z, He, T, Luo, J and Ding, W (2020) Four-year continuous residual effects of biochar application to a sandy loam soil on crop yield and N2O and NO emissions under maize–wheat rotation. Agriculture, Ecosystems & Environment 302, 107109.CrossRefGoogle Scholar
Lu, Z, Ren, T, Li, J, Hu, W, Zhang, J, Yan, J and Lu, J (2020) Nutrition-mediated cell and tissue-level anatomy triggers the covariation of leaf photosynthesis and leaf mass per area. Journal of Experimental Botany 71, 65246537.CrossRefGoogle ScholarPubMed
Lyu, S, Du, G, Liu, Z, Zhao, L and Lyu, D (2016). Effects of biochar on photosystem function and activities of protective enzymes in Pyrus ussuriensis Maxim. under drought stress. Acta Physiologiae Plantarum 38, 110.CrossRefGoogle Scholar
Mete, FZ, Mia, S, Dijkstra, FA, Abuyusuf, M and Hossain, ASMI (2015) Synergistic effects of biochar and NPK fertilizer on soybean yield in an alkaline soil. Pedosphere 25, 713719.CrossRefGoogle Scholar
Murthy, PS and Naidu, MM (2012) Sustainable management of coffee industry by-products and value addition – a review. Resources, Conservation & Recycling 66, 4558.CrossRefGoogle Scholar
Partey, ST, Saito, K, Preziosi, RF and Robson, GD (2016) Biochar use in a legume–rice rotation system: effects on soil fertility and crop performance. Archives of Agronomy and Soil Science 62, 199215.Google Scholar
Prasad, M, Tzortzakis, N and McDaniel, N (2018) Chemical characterization of biochar and assessment of the nutrient dynamics by means of preliminary plant growth tests. Journal of Environmental Management 216, 8995.CrossRefGoogle ScholarPubMed
Puerta-Quintero, GI (2000). Calidad en taza de algunas mezclas de variedades de café de la especie Coffea arabica L. Cenicafé 51, 519.Google Scholar
Rathinavelu, R and Graziosi, G (2005) Potential alternative use of coffee wastes and by-products. Coffee Organization 942, 14.Google Scholar
Reichembach, LH and de Oliveira-Petkowicz, CL (2020) Extraction and characterization of a pectin from coffee (Coffea arabica L.) pulp with gelling properties. Carbohydrate Polymers 245, 116473.CrossRefGoogle ScholarPubMed
Restrepo-Diaz, H, Benlloch, M, Navarro, C and Fernández-Escobar, R (2008) Potassium fertilization of rainfed olive orchards. Scientia Horticulturae 116, 399403.CrossRefGoogle Scholar
Reyes-Moreno, G, Fernández, ME and Contreras, ED (2021) Balanced mixture of biochar and synthetic fertilizer increases seedling quality of Acacia mangium. Journal of the Saudi Society of Agricultural Sciences 20, 371378.CrossRefGoogle Scholar
Rodrigues, WP, Silva, JR, Ferreira, LS, Machado-Filho, JA, Figueiredo, FA, Ferraz, TM and Ramalho, JC (2018) Stomatal and photochemical limitations of photosynthesis in coffee (Coffea spp.) plants subjected to elevated temperatures. Crop and Pasture Science 69, 317325.CrossRefGoogle Scholar
Ronga, D, Caradonia, F, Parisi, M, Bezzi, G, Parisi, B, Allesina, G and Francia, E (2020) Using digestate and biochar as fertilizers to improve processing tomato production sustainability. Agronomy 10, 138.CrossRefGoogle Scholar
Sadaf, J, Shah, GA, Shahzad, K, Ali, N, Shahid, M and Ali, S (2017) Improvements in wheat productivity and soil quality can accomplish by coapplication of biochars and chemical fertilizers. Science of the Total Environment 608, 715724.CrossRefGoogle Scholar
Sadeghian, S (2013) Nutrición de cafetales. En Gast, F, Benavides, P, Sanz, JR, Herrera, JC, Ramírez, VH, Cristancho, MA and Marín, SM (eds). Manual del Cafetero Colombiano, Investigación y Tecnología para la Sostenibilidad de la Caficultura- Postcosecha y subproductos del café. Cenicafé: Federación Nacional de Cafeteros, pp. 2326.Google Scholar
Salamanca-Jimenez, A (2017) Coffee crop fertilization in Colombia: a mini- review. International Potash Institute 50, 2230.Google Scholar
Sánchez-Reinoso, AD, Ávila-Pedraza, EA and Restrepo-Díaz, H (2020) Use of biochar in agriculture. Acta Biológica Colombiana 25, 327338.Google Scholar
Sanz-Uribe, JR, Oliveros-Tascón, CE, Ramírez-Gómez, CA, Peñuela-Martínez, AE and Ramos-Giraldo, PJ (2013) Proceso de Beneficio. En Gast, F, Benavides, P, Sanz, JR, Herrera, JC, Ramírez, VH, Cristancho, MA and Marín, SM (eds). Manual del Cafetero Colombiano, Investigación y Tecnología para la Sostenibilidad de la Caficultura – Nutrición de Cafetales. Cenicafé: Federación Nacional de Cafeteros, pp. 948.Google Scholar
Shaaban, M, Van Zwieten, L, Bashir, S, Younas, A, Núñez-Delgado, A, Chhajro, MA and Hu, R (2018) A concise review of biochar application to agricultural soils to improve soil conditions and fight pollution. Journal of Environmental Management 228, 429440.CrossRefGoogle ScholarPubMed
Sorrenti, G, Muzzi, E and Toselli, M (2019) Root growth dynamic and plant performance of nectarine trees amended with biochar and compost. Scientia Horticulturae 257, 108710.CrossRefGoogle Scholar
Tang, JW, Zhang, SD, Zhang, XT, Chen, JH, He, XY and Zhang, QZ (2020) Effects of pyrolysis temperature on soil-plant-microbe responses to Solidago canadensis L.-derived biochar in coastal salinealkali soil. Science of the Total Environment 731, 138938.CrossRefGoogle Scholar
Tanure, MM, da Costa, LM, Huiz, HA, Fernandes, RBA, Cecon, PR, Junior, JDP and da Luz, JMR (2019) Soil water retention, physiological characteristics, and growth of maize plants in response to biochar application to soil. Soil & Tillage Research 192, 164173.Google Scholar
Tian, X, Li, C, Zhang, M, Wan, Y, Xie, Z, Chen, B and Li, W (2018) Biochar derived from corn straw affected availability and distribution of soil nutrients and cotton yield. PLoS ONE 13, e0189924.CrossRefGoogle ScholarPubMed
Vaccari, F, Maienza, A, Miglietta, F, Baronti, S, Di-Lonardo, S, Giagnoni, L and Genesio, L (2015) Biochar stimulates plant growth but not fruit yield of processing tomato in a fertile soil. Agriculture, Ecosystems & Environment 207, 163170.CrossRefGoogle Scholar
Vassilev, N, Martos, E, Mendes, G, Martos, V and Vassileva, M (2013) Biochar of animal origin: a sustainable solution to the global problem of high-grade rock phosphate scarcity. Journal of the Science of Food and Agriculture 93, 17991804.CrossRefGoogle Scholar
Vijayaraghavan, K (2021) The importance of mineral ingredients in biochar production, properties and applications. Critical Reviews in Environmental Science and Technology 51, 113139.CrossRefGoogle Scholar
Wang, D, Jiang, P, Zhang, H and Yuan, W (2020). Biochar production and applications in agro and forestry systems: a review. Science of the Total Environment 723, 137775.CrossRefGoogle Scholar
Wang, S, Zheng, J, Wang, Y, Yang, Q, Chen, T, Chen, Y and Wang, T (2021) Photosynthesis, chlorophyll fluorescence, and yield of peanut in response to biochar application. Frontiers in Plant Science 12, 1000.Google ScholarPubMed
Xu, X, He, P, Pampolino, MF, Johnston, AM, Qiu, S, Zhao, S and Zhou, W (2014) Fertilizer recommendation for maize in China based on yield response and agronomic efficiency. Field Crops Research 157, 2734.CrossRefGoogle Scholar
Ye, L, Camps-Arbestain, M, Shen, Q, Lehmann, J, Singh, B and Sabir, M (2019) Biochar effects on crop yields with and without fertilizer: a meta-analysis of field studies using separate controls. Soil Use and Management 36, 218.CrossRefGoogle Scholar
Zabini, AV, Martinez, HEP, Neves, JCL, Cruz, CD and Valadares, SV (2021) Chemical analyses of flowers and leaves for nutritional diagnoses of coffee trees. Ciência Rural 51, 17.CrossRefGoogle Scholar
Zeeshan, M, Ahmad, W, Hussain, F, Ahamd, W, Numan, M, Shah, M and Ahmad, I (2020) Phytostabalization of the heavy metals in the soil with biochar applications, the impact on chlorophyll, carotene, soil fertility and tomato crop yield. Journal of Cleaner Production 255, 120318.CrossRefGoogle Scholar
Zhang, Q, Song, Y, Wu, Z, Yan, X, Gunina, A, Kuzyakov, Y and Xiong, Z (2020) Effects of six-year biochar amendment on soil aggregation, crop growth, and nitrogen and phosphorus use efficiencies in a rice-wheat rotation. Journal of Cleaner Production 242, 118435.CrossRefGoogle Scholar
Zheng, W, Luo, B and Hu, X (2020) The determinants of farmers’ fertilizers and pesticides use behavior in China: an explanation based on label effect. Journal of Cleaner Production 272, 123054.CrossRefGoogle Scholar
Zhu, L, Yang, H, Zhao, Y, Kang, K, Liu, Y, He, P and Wei, Z (2019) Biochar combined with montmorillonite amendments increase bioavailable organic nitrogen and reduce nitrogen loss during composting. Bioresource Technology, 294, 122224.CrossRefGoogle ScholarPubMed