Full Length Research Paper
References
Amadou I, Gounga ME, Le GW (2013). Millets: Nutritional composition, some health benefits and processing. A review. Emirates Journal of Food and Agriculture 25:501-508. |
|
Bekoye BM (2011). Caractérisation chimique et minérale des grains de mil [Pennisetum glaucum ( L .) R . Br .] de Côte d ' Ivoire. International Journal of Biological and Chemical Sciences 5(5):2039-2044. |
|
Brag H (1972). The influence of potassium on the transpiration rate and stomatal opening in Triticum aestivum and Pisum sativum. Physiology Plant 26:250-257. |
|
Dakheel AJ, Shabbir G, Al-Gailani AQ (2009). Yield stability of pearl millet genotypes under irrigation with different salinity levels. Europ JSR 37:288-301. |
|
Diallo D, Tamini Z, Barry B, Faya AO (2010). Effet de la fumure organique sur la croissance et le rendement du riz Nerica (WAB 450 IBP 28HB) à Faranah. International Journal of Biological and Chemical Sciences 4(6):2017-2025. |
|
Dimkpa CO, Fugice J, Singh U, Lewis TD (2020). Development of fertilizers for enhanced nitrogen use efficiency-Trends and perspectives. Science Total Environment 731:139113. |
|
Dreyer H (2018). Comité De L' Agriculture. Proposition relative à la célébration d'une Année internationale du mil, pp. 1-9 |
|
Drugmand J (2020). Impact des stress thermique et hydrique sur la croissance, la reproduction et la pollinisation de Fagopyrum esculentum et comparaison de la pollinisation chez deux espèces de Fagopyrum 100. |
|
FAOSTAT (2020). Rendement du mil au Burkina Faso. https://www.fao.org/faostat/fr/#data/QCL, october 15th. |
|
FAOSTAT (2022). Rendement des céréales au Burkina Faso. December 21th. |
|
Farouk S, Amany AR (2012). Improving growth and yield of cowpea by foliar application of chitosan under water stress. Egypt JB 14:14-16. |
|
Fournier JM, Roldãn AM, Sãnchez C, Alexandre G, Benlloch M (2005). K+ starvation increases water uptake in whole sunflower plants. Plant Science 168:823-829. |
|
Ghannoum O (2009). C4 photosynthesis and water stress. Annals of Botany 103:635-644. |
|
Grzebisz W, Gransee A, Szczepaniak W, Diatta J (2013). The effects of potassium fertilization on water-use efficiency in crop plants. Journal of Plant Nutrition and Soil Science 176:355-374. |
|
Hamadou M, Idrissa S, Mahamadou C, Oumarou S, Valentin K (2017). Potentialités fourragères du mil (Pennisetum glaucum ( L .) R . Br )?: Revue de littérature. Journal of Animal and Plant Sciences 34(2):5424-5447. |
|
Hayano-Kanashiro C, Calderon-Vazquez C, Ibarra-Laclette E, Herrera-Estrella L, Simpson J (2009). Analysis of gene expression and physiological responses in three Mexican maize landraces under drought stress and recovery irrigation. PLoS ONE 4:7531-7531. |
|
Hanane S (2013). Le pouvoir antioxydant des polyphénols de l'espèce Pennisetum glaucum (millet) du sud de l'Algérie, Université Abou Bakr Belkaid Tlemcen, Algérie. |
|
Harper JE (1994). Nitrogen metabolism. Physiology and determination of crop yield. Boote KJ(Eds), pp. 285-302. |
|
Ibrahim ME, Abd El-Aty MI Ahmed RAT, Taia AAM (2019). Combined Effect of Poultry Manure and Soil Mulching on Soil Properties, Physiological Responses, Yields and Water-use Efficiencies of Sorghum Plants under Water Stress, Communications in Soil Science and Plant Analysis. |
|
Imran H, Muhammad ASR, Rashid I, Muhammad UA, Muhammad HR, Shameem R, Muhammad TK, Muhammad MA, Muhammad W, Salman A (2020). Potential effects of biochar application on mitigating the drought stress implications on wheat (Triticum aestivum L.) under various growth stages. Journal of Saudi Chemical Society 24(12):974-981. |
|
Kapoor D, Bhardwaj S, Landi M, Sharma A, Ramakrishnan M, Sharma A (2020). The Impact of Drought in plant metabolism: How to exploit tolerance mechanisms to increase crop production. Applied Sciences 10(16):5692. |
|
Konaté B, Nana R, Nana L S, Badiel B, Sawadogo M, Tamini Z (2016). Morphophysiological response of okra [Abelmoschus esculentus (L.) Moench] subjected to biofertilization and water stresses. International Journal of Biological and Chemical Sciences 10(5):2108-2122. |
|
Khodaei-joghan A, Gholamhoseini M, Agha-alikhani M, Habibzadeh F (2018). Response of sunflower to organic and chemical fertilizers in different drought stress conditions. Acta Agriculturae Slovenica pp. 271-284. |
|
Lawlor DW, Day W, Johnston AE, Legg BJ, Parkinson KJ (1981). Growth of spring barley under drought: crop development, photosynthesis, dry-matter accumulation and nutrient content. The Journal of Agricultural Science 96:167-186. |
|
Lindhauer MG (1985). Influence of K nutritional drought on water relations and growth of sunflower (Helianthus annuus L.). Z. Pflanzenernächr Bodenk 148:654-669. |
|
M'Barek BN, Mounir NMS (1991). Effet d'un déficit hydrique, survenant à différents stades de développement du blé, sur l'humidité du sol, la physiologie de la plante et sur les composantes du rendement. Méditerranée 2:53-60. |
|
Maiti R, Rodríguez HG (2010). Pearl millet: potential alternative for grain and forage for livestock in semi-arid regions of Mexico. International Journal of Bio-resource and Stress Management 1:45-47. |
|
Moreno-Jiménez E, Plaza C, Saiz H, Manzano R, Flagmeier M, Maestre FT (2019). Aridity and reduced soil micronutrient availability in global drylands. Nature Sustainability 2:371-377. |
|
Newman Y, Jennings E, Vendramini J, Blount A (2010). Pearl millet (Pennisetum glaucum): overview and management. University of FL. IFAS Extension. |
|
Peuke AD, Jeschke WD, Hartung W (2002). Flows of elements, ions and abscissic acid in Ricinus communis and site of nitrate reduction under potassium limitation. Journal of Experimental Botany 53:241-250. |
|
Pinheiro C, Chaves MM (2011). Photosynthesis and drought: can we make metabolic connections from available data. Journal of Experimental Botany 62:869-882. |
|
Pirbalouti AG, Malekpoor F, Salimi A, Golparvar A (2017). Exogenous application of chitosan on biochemical and physiological characteristics, phenolic content and antioxidant activity of two species of basil (Ocimum ciliatum and Ocimum basilicum) under reduced irrigation. Scientia Horticulturae 217:114-122. |
|
Shelke GV, Chavan AM (2010). Improvement of agronomically desirable genotypes for downy mildew disease resistance in Pearl millet [Pennisetum glaucum (L.) R. Br.] By recombination breeding. Journal of Ecobiotechnology 2(1):16-20. |
|
Sory A, Nana R, Banhoro A, Ouedraogo WIC, Sawadogo M (2022). Millet (Pennisetum glaucum (l.) R. Br.) Productivity under fertilization with poultry droppings in BURKINA FASO. International Journal of Agriculture, Environment and Bioresearch 7(6):269-282. |
|
Siéné AL, Doumbouya C, Traore M, Condé MS, N'Guettia VMT, Kone M (2020). Effet de quatre types de fertilisants sur la croissance et la productivité de deux génotypes de maïs ( Zea mays L .) en cas d ' un semis tardif à Korhogo au Centre- Nord de la Côte d ' Ivoire pp. 55-68. |
|
Siéné C, Ambroise L (2016). Evaluation of water stress impact on growth and yield of millet (Pennisetum glaucum (L .) R . Br .) for two nitrogen fertilization conditions in a semi-arid tropical environment. International Journal of Innovation and Applied Studies 14(3):779-789. |
|
Wahid BA, Abdellah B (2020). Qualités nutritionnelles de millet perlé. Mémoire P 58. |
|
Zain NAM, Ismail MR (2016). Effects of potassium rates and types on growth, leaf gas exchange, & biochemical changes in rice (Oryza sativa). - Agricultural Water Management 164(1):83-90. |
Copyright © 2024 Author(s) retain the copyright of this article.
This article is published under the terms of the Creative Commons Attribution License 4.0