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Assessment of the feasibility of using a wheat-finger millet composite flour for bread makingBeswa, Daniso 13 August 2012 (has links)
M.Tech. / Sorghum (Sorghum bicolour (L) Moench) and millets are drought resistant cereals (Kent and Evers, 1994) that can grow in areas with poor soils and inconsistent rainfall (Dendy, 1995) where other crops fail. They serve as staple food for many people in tropical sub- Saharan Africa and Asia (Klopfenstein and Hoseney, 1995). Traditionally, bread is made from wheat, which is a temperate cereal not able to grow well in these tropical regions. Leavened bread is seldom made from anything other than wheat (Alais and Linden, 1991) and this is because of the unique visco-elastic property of wheat flour (Hoseney, 1994). Unfortunately in tropical regions such as South Africa wheat is imported at a premium price. The aim of this study was to produce a wheat-finger millet composite flour which is suitable for bread making. Finger millet grain (FMV6) was milled with a laboratory hammer mill fitted with a 0.8 mm screen. The following wheat-finger millet composite doughs were made using standard bread making methods, 0:100 (Control); 90:10; 80:20; 70:30, respectively. Selected quality attributes of the composite dough and the bread thereof were analysed using standard methods. The formulation with 10% finger millet showed better results than other formulations. One formulation (80:20) was selected for improvement which included mixing ingredients at elevated temperatures (50°C and 93°C) and addition of 0.002% of a lipase enzyme, lipopan F; 0.3% vital wheat gluten and a combination of 0.002% lipopan F and 0.3% gluten. All formulations (including the basic formulation) contained Fungamyl Super MA (enzyme combination which contained fungal a-amylase and a xylanase). As the mixing temperatures were elevated, loaf volume decreased but when the industrial baking enzymes were introduced there was an improvement in peak time, dough stability and loaf volume. Image analysis showed that there was an improvement in crumb structure and bubble size distribution after the application of enzyme lipopan F. The crumb colour was lighter and softer when a combination of enzyme lipopan F and vital wheat gluten was applied. The bread made from formulation 80:20 with addition of a combination of enzyme lipopan F and vital wheat gluten (WFM2GL) was more acceptable than other formulations except the control bread. The bread had a high score in taste, crust appearance and mouth feel. The results suggest that there is a potential for producing a composite bread by substituting wheat flour with finger millet flour (up to 20%); mixing at 25°C with application of a combination of a lipase and vital wheat gluten. However, more work is needed to improve the quality of the bread to a greater extent.
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Finger millet grain phenolics and their impact on malt and cookie qualitySiwela, Muthulisi 17 October 2009 (has links)
Phenolics in finger millet (FM) grain, including tannins, may impact significantly on its antimicrobial properties, functionality and health-promoting potential. Unfortunately, the location of tannins in the grain is unknown and there is limited information on the influence of variety on grain phenolic composition and antioxidant activity (AA). The effect of phenolics in FM grain on its malt fungal load and on the functional quality of its food products, including baked goods, is barely known. Twenty two FM grain types of varied visual kernel colour were analysed to determine the influence of grain type on phenolic composition, AA, and tannin localisation in the grain. Condensed tannins, anthocyanins and flavan-4-ols were detected. Light coloured grain types had no tannins and had much lower total phenolics (TP) relative to the pigmented types, and types that stained black with the Bleach test had much higher tannin content and much higher AA. The grains that stained black with the Bleach test and had high tannin content (0.60 to 2.08 mg catechin eqivalents/100 mg, db) had a dark coloured testa layer, indicating that the tannins were located in that layer. The results indicate that occurrence of tannins in FM is a varietal property and the tannins are predominantly responsible for the AA of the grain. Germinative energy (GE), enzymic activity, and total fungal count [TFC], and infection levels of 12 FM grain types of varied phenolic content were measured to determine the impact of phenolics in FM grain on its malt quality. The malt quality of high-phenol FM types was much higher than that of the low-phenol types, with respect to enzymic activity. TFC was negatively correlated with grain total phenolics (TP) and amount of phenolic type (APT) and there were some negative correlations between fungal species infection levels and TP and APT (p<0.05). GE and enzymic activity were positively correlated with TP and APT (p<0.05) and negatively correlated with TFC (p<0.01). The data indicate that phenolics in FM grain impact positively on its malt quality by contributing to its antifungal activity. Cookies in which wheat cake flour was substituted with 15, 35 and 55% (w/w) of either a non-tannin or a high-tannin FM flour were analysed to assess the impact of FM phenolics on cookie quality and AA (health-promoting potential). FM-substituted cookies, particularly those with high levels of the high-tannin FM, were inferior to cake flour cookies (control), with respect to spread, texture and integrity and their dark colour decreased their acceptance by a consumer panel. However, the acceptability of cookies containing up to 35% of either FM type was similar to that of control cookies. Cookies containing the high-tannin FM had antioxidant activities that were similar to or higher than the antioxidant activities of several plant products on the market. Thus, potentially health-promoting cookies can be made by substituting up to approximately 35% wheat with a high-tannin FM. The study indicates that high-phenol FM grain types have good malt quality, which is partly due to the antifungal activity of their phenolics. Although FM phenolics, particularly tannins, seem to affect cookie quality negatively, they contribute significantly to their health-promoting potential. / Thesis (PhD)--University of Pretoria, 2009. / Food Science / unrestricted
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Factors inducing the chloroplast movement in C₄ plants underhigh light-stress conditions and effects of the response on photosynthesis / 強光ストレス環境におけるC₄植物の葉緑体運動の誘導要因および光合成に与える影響Maai, Eri 25 May 2020 (has links)
京都大学 / 0048 / 新制・論文博士 / 博士(農学) / 乙第13360号 / 論農博第2891号 / 新制||農||1080(附属図書館) / 学位論文||R2||N5299(農学部図書室) / (主査)教授 中﨑 鉄也, 教授 白岩 立彦, 教授 土井 元章 / 学位規則第4条第2項該当 / Doctor of Agricultural Science / Kyoto University / DGAM
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Effect of environmental stress and management on grain and biomass yield of finger millet (Eleusine coracana (L.) Gaertn.)Opole, Rachel Adoyo January 1900 (has links)
Doctor of Philosophy / Department of Agronomy / P.V. Vara Prasad / Productivity of grain crops is highly sensitive to changing climates and crop management practices. Response of finger millet [Eleusine coracana (L.) Gaertn.] to high temperature stress, and intensive management practices such as increased seeding rates and fertilizer application are not clearly understood. The objectives of this research were to determine the effects of (a) season-long, and short episodes of high temperature stress on growth and yield traits of finger millet, (b) seeding rates and nitrogen fertilizer application rates on grain and biomass yield, and (c) to evaluate the finger millet minicore collection for high grain and biomass yield. Controlled environment studies were conducted to determine the effects of high temperature stress on physiological, growth and yield traits. Field studies were conducted in Manhattan and Hays (Kansas) and Alupe (Kenya) to determine the effects of seeding and nitrogen fertilizer rates on growth and yield traits. Finger millet minicore collection was evaluated under field conditions in India, for phenology, growth and yield traits. Season long high temperature stress of 36/26 or 38/28°C compared to 32/22°C decreased panicle emergence, number of seeds per panicle, grain yield and harvest index. Finger millet was most sensitive to short episodes (10 d) of high temperature (40/30°C) during booting, panicle emergence and flowering stages, resulting in lower number of seeds, and grain yield. Finger millet responded to the interaction between environmental (locations) and temporal (years) factors. In general, locations with higher rainfall had greater grain and biomass yield than those with low rainfall. There was no influence of seeding rates (3.2 or 6.0 kg ha[superscript]-1) at Hays and Alupe. However, in one of the two years in Manhattan, higher seeding rate of 6.0 kg ha[superscript]-1 increased grain yield compared to 3.2 kg ha[superscript]-1. There was no influence of nitrogen rates (0, 30, 60 or 90 kg ha[superscript]-1) on grain or biomass yield at all three locations. However, higher fertilizer rates had greater percentage lodging. The finger millet minicore collection displayed large ranges for most quantitative traits including days to flowering, plant height, number of fingers panicle[superscript]-1, grain yield, biomass yield, and lodging; and had >60% heritability. Some of the genotypes from the minicore collection have the potential to increase grain and biomass yield and abiotic stress tolerance of finger millet.
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Evaluation of finger millet (Eleusine coracana) under irrigated and rainfed conditions as a fooder crop on the Pietersburg Plateau, South AfricaMaenetja, Nurse Pertunia January 2021 (has links)
Thesis (M.Sc. Agriculture (Pasture Science)) -- University of Limpopo, 2021 / Finger millet (Eleusine coracana) is believed to be adapted to the arid and semi-arid
regions, highly tolerant to pests, diseases and drought. It has the potential to produce
a high forage biomass with fewer inputs under good production practices. The aim of
the study was to evaluate the potential of finger millet as a fodder crop on the
Pietersburg Plateau under rainfed and irrigation conditions, planted in rows and
broadcast. The study was conducted for two consecutive seasons (2017 and 2018) at
the Syferkuil Experimental Farm (SEF), University of Limpopo.
Treatments consisted of two watering treatments (irrigation and rainfed) and two
planting methods (broadcast and row planting). Seeding rate was 10 kg ha-1 with the
inter row spacing of 25 cm. Irrigation had a significant effect on the dry matter
production of finger millet (P ≤ 0.05). During 2017 growing season, under rainfed
condition, the crop experienced zero production due to low rainfall. The total dry matter
production of finger millet under rainfed conditions in 2018 was 3371 kg ha-1 for row
planting and 3770 kg ha-1 for broadcasting. The dry matter production of finger millet
under irrigation and row planting was 5318 kg ha-1 compared to 3371 kg ha-1 produced
under row planting in the rainfed conditions. Broadcasting under irrigation produced
4890 kg ha-1 whereas broadcasting under rainfed conditions yielded 3770 kg ha-1.
Planting method had no significant effect on the dry matter production of finger millet
(P ≤ 0.05). The total dry matter production in 2017 was 5668 kg ha-1 and 5122 kg ha 1 under row planting and broadcast respectively, 2018 season produced the total dry
matter production of 5122 kg ha-1 under row planting and 4892 kg ha-1 under
broadcast. Finger millet planted under rainfed in rows had the CP% of 14.76 and
16.87% when broadcasted. In all the treatments CP% was higher than 10%. The
ADF% was 33.02% under rainfed conditions and it ranged between 30.99% and
31.53% in 2017 and 2018 for row planting under irrigation. Finger millet can be
considered an alternative fodder crop for livestock farmers in the Pietersburg Plateau
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Physical, functional and nutritional properties of flours from finger millet (Eleusine coracana) varieties fortified with vitamin B₂ and zinc oxideRamashia, Shonisani Eugenia 21 September 2018 (has links)
PhD (Food Science and Technology) / Department of Food Science and Technology / Finger millet (FM) (Eleusine coracana) grains are the staple food in Africa and India for communities with low socio-economic growth. The grains have high content of calcium, dietary fibre, carbohydrates that are rich in protein, fat, iron, phosphorus, vitamin and essential amino acids. Flours from milky cream (MC), brown and black varieties of FM were fortified with vitamin (vit) B₂ and zinc oxide (ZnO) in order to restore the nutrients that were lost during milling and sieving processes. The main aim of the study was to analyse the physical, nutritional composition and functional properties of flours from three (3) FM varieties fortified with vit B2 and ZnO. Pearl millet was used for comparison with the results obtained from this study. MC, brown and black varieties of FM flour treatments were arranged as a completely randomized design (CRD) in three (3) replicates. Physical properties: dimensional properties, colour attributes, kernel weight, bulk density (BD), true density, porosity, surface area, kernel volume, aspect ratio, sphericity and moisture content of the FM grains were analysed. Vitamins and minerals were also analysed. Functional properties: colour attributes, bulk density (BD), water absorption capacity (WAC), oil absorption capacity (OAC), swelling capacity (SC), swelling index (SI), foaming capacity (FC), foaming solubility (FS), dispersibility (Dis), viscosity (cool & hot paste), pasting properties, thermal properties and microscopic structure of FM flours were determined. Data generated were analysed using SPSS version 23.0. Moisture content of MC FM grain and flour was significantly higher (p < 0.05) than brown and black varieties but was within the specified range of <12%. This indicated the long storage shelf-life of the grains and flours. Length of brown FM grains was significantly higher (p < 0.05) when compared to MC and black varieties. MC variety was significantly higher than other varieties in width, kernel weight, bulk density, true density, aspect ratio and sphericity. The information obtained from this study will help in designing suitable equipment for planting, harvesting, storage, processing and packaging of grains. Pearl millet grain was significantly higher than FM flours in all physical properties. MC FM was significantly higher
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in L* (whiteness/ brightness), b* (yellowness/ blueness), C* (chroma), Hº (hue angle) and ZnO values compared to brown and black flours. MC raw fortified finger millet (RFFM) and instant fortified finger millet (IFFM) flours were significantly higher in vitamin B2. People prefer fortified MC flour because most of people living in South Africa use white maize as their staple food and it is similar to MC. Colour is the most important quality parameter in food processing industries and it is also attracts the consumer’s choice and preference. The vitamins and minerals that were lost during sieving, drying and milling were replaced by the two (2) fortificants added which may help to reduce the micronutrient deficiencies. Milky cream FM flours showed significantly high (p < 0.05) values in BD, WAC, OAC, SI, FC and dis. These are the fundamental physico-chemical properties that reflect the interaction between the composition and molecular structure. Length of brown FM grains was significantly higher (p < 0.05) when compared to MC and black variety. The MC variety was significantly higher than other varieties in width, kernel weight, bulk density, true density, aspect ratio and sphericity. Pearl millet was significantly higher than FM flours in all physical properties. MCFM variety was significantly higher in L* (whiteness/ brightness), b* (yellowness/ blueness), C* (chroma), and Hº (hue angle) values as compared to other FM varieties. Moisture content of MC flour was significantly higher as compared to brown and black FM flours. Pasting properties of MC raw finger millet (RFM) and RFFM flours showed significantly higher in peak viscosity (PV) (3518 cP), final viscosity (FV) (6554 cP), breakdown viscosity (BDV) (703 cP) and setback viscosity (SV) (3868 cP) as compared to other RFM and RFFM flours. Brown instant finger millet (IFM) and IFFM flours had significantly higher of PV (723 cP), trough viscosity (TV) (655 cP) and FV (983 cP). IFFM flours had significantly higher values of PV (712 cP), TV (614 cP) and FV (970 cP), respectively. The instant pearl millet (IPM) and instant fortified pearl millet (IFPM) showed significantly higher value in BDV (330 cP and 131 cP) and SV (362 cP and 346 cP), respectively. Thermal properties of black RFM was significantly higher in onset temperature (To) (74.31), peak temperature (TP) (81.94ºC) and conclusion temperature (Tc) (89.64) and RFFM starches were significantly high in To (81.80ºC), TP (84.22ºC) and TC (92.81ºC), respectively. Milky
ivcream IFM starch showed significantly higher values in TO (84.57ºC), TP (87.27ºC), Tc (92.81ºC) and ΔH (7.63ºC) compared to other starches. Brown IFFM flour was significantly higher value in To (85.88ºC) and TP (87.14ºC). The starch of IFPM was significantly higher in enthalpy of gelatinisation (6.91ºC) and PHI (2.94ºC) as compared to other FM starches. Brown IFM flour showed significantly higher value in gelatinisation temperature range (13.50ºC). The microscopic structure revealed that RFM and RFFM flours had oval and smooth surfaces. RFM and RFFM flours showed positive effect after fortificants were added because the starch granules, protein bodies and protein matrix were visible and formed crystal. IFM and IFFM flours had some holes, dents and rough surfaces. Instant fortified flours showed negative effect after fortificants were added due to technological processes such as recooking and remilling of flours. Different variations observed on physical, nutritional and functional properties after adding the fortificants may affect the physical, chemical and organoleptic properties of food produced from fortified flour. There is need to fortify FM flours with ZnO which may help to replace the value lost during milling and sieving operations. It is possible that the availability of ZnO could reduce the incidence of some non-communicable diseases. / NRF
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The nutritional use of millet grain for food and feedHassan, Zahra Mohammed 05 1900 (has links)
Worldwide, millets are regarded as significant grains; however, they are the least exploited. Millet grain is abundant in nutrients and health-beneficial phenolic compounds, making it suitable as food and feed. The diverse contents of nutrients and phenolic compounds present in finger and pearl millet are good indicators that the variety of millet available is important when selecting it for use as food or feed. The phenolic properties found in millets comprise of phenolic acids, flavonoids, and tannins, which are beneficial to human health. Research has shown that millet phenolic properties have high antioxidant activity. Phytochemicals present in millet grains have positive effects on human health by lowering the cholesterol and phytates in the body. The frantic demands on maize and its uses in multiple industries have merit the search for alternative grains, to ease the pressure. Substitution of maize with pearl and finger millets in the diets of different animals resulted in positive impact on the performance. Of late, millet grain has been incorporated in other foods and used to make traditional beverages. In Chapter 1, the topic of the research was introduced, stating the importance of the study and to motivate on the significance of millet grains. Aims and
objectives were also listed. Chapter 2 presented extensive literature review on millet and their uses in human and livestock nutrition. In addition, the use of tannin as alternative feed was also reviewed. Different studies have been conducted to investigate the suitability of millet grain as an energy source, in the animal industry. However, studies on the Southern African types of millet are limited; this might be due to lack of information on their nutritional composition and their suitability as animal feed. Overall, the aim of this study was to profile the nutritional characteristics of selected millet grains in South Africa and Zimbabwe, their suitability as energy source for human and livestock and to study the effect of pearl millet type on the performance indices of Ross 308 broiler chickens. In Chapter 3, the general materials and methods used to reach the scientific conclusion for this study was summarised. In Chapter 4, physical and chemical analysis were conducted on millet grains obtained from South Africa and Zimbabwe, the results revealed that the physiochemical characteristics of the millet grain qualify it as a suitable candidate in replacing maize as an energy source. To further understand the characteristics of the millet grain, Chapter 5 analysed the phenolic compounds available in the millet grain obtained from South Africa and Zimbabwe. The results showed that the grain is endued with valuable phenolic compounds beneficial in the nutrition of both human and animals and aid as health benefit. Chapter 6 investigated the various inclusion levels of pearl millet in a bid to establish the most suitable combination for the poultry sector.
Pearl millet grain used in this experiment went through different breeding improvements and selections conducted at the Grain Crop Institute in Potchefstroom, South Africa. Pearl millet grain was used as the main source of energy for Ross 308 broiler chicks for a period of 42 days with performance indices investigated. The results revealed that pearl millet can be incorporated in the diets of broiler chickens, in replacement of maize, without adversely affecting the performance. In addition, the economic justification of replacing maize with pearl millet was studied. The cost of the grains was determined and the cost per weight gain was determined. The results showed that indeed it is economically sound to replace maize with pearl millet in the diet of poultry. The quadratic function best fitting optimum treatment combination in relation to performance parameters such as body weight, body weight gain, feed conversion ratio and internal organs was also examined. In Chapter 7, the research was generally discussed to tie up the conclusions of the experiments conducted. General recommendations were also given on the compounds of millet varieties and their health benefits to both humans and animals. / Kuwo wonke umhlaba, amabele athathwa njengezinhlamvu ezibalulekile, kodwa
awasetshenziswa kakhulu. Uhlamvu lwebele lunemisoco eminingi kanye nenzuzo yempilo
ngama-phenolic compound, okwenza ukuthi afaneleke kakhulu njengokudla kwabantu kanye
nemfuyo. Imisoco eminingi equkethwe kanye nama-phenolic compound atholakala eminweni
kanye nezinhlamvu zebele ayizinkomba ezinhle zokuthi izinhlobo zamabele ezitholakalayo
zibaluleke kakhulu ekukhethweni njengokudla kanye nokudla kwabantu noma imfuyo. Amaphenolic
properties atholakala kumabele aqukethe ama-phenolic acids, ama-flavonids, kanye
nama-tannins, ayinzuzo kakhulu empilweni yabantu. Ucwaningo luthole ukuthi ama-phenolic
properties amabele anomsebenzi wezinga eliphezulu lama-antioxidant. Ama-phytochemicals
atholakala kwizinhlamvu zamabele anenzuzu enhle kakhulu kwimpilo yabantu ngokwehlisa
izinga le-cholesterol kanye nama-phytate emzimbeni. Ukudingeka kakhulu kombila kanye
nokusetshenziswa kwawo kwizimboni eziningi, kubangele ukuthi kwenziwe ucwaningo
ngezinye izinhlamvu ukwehlisa ingcindezi. Ukuthatha isikhundla sombila, sithathwa amabele
kwidayethi yezilwane ezehlukene kwaba nomphumela omuhle kakhulu ngokusebenza.
Kamuva nje, izinhlamvu zamabele zifakelwe kwezinye izidlo ezisetshenziswa ukwenza
iziphuzo zomdabu. Kwisahluko 1, isihloko socwaningo sethulwa khona, ukuchaza
ukubaluleka kocwaningo kanye nokuqikelela ngokubaluleka kwezinhlamvu zamabele.
Izinhloso nezinjongo nazo zifakelwe kuhla. Isahluko 2, sethula ukubuyekezwa kwemibhalo
ngamabele kanye nokusetshenziswa kwawo kubantu kanye nokudla kwemfuyo. Nangaphezu
kwalokho, ukusetshenziswa kwe-tannin njengokunye ukudla kwemfuyo kuye
kwabuyekezwa.
Kwenziwe ucwaningo olwehlukene ukuphenyisisa ngokufaneleka kwezinhlamvu zamabele
njengomthombo wamandla (we-eneji) kwimboni yezilwane. Kodwa, ucwaningo ngezinhlobo
zamabele eNingizimu ne-Afrika alukenziwa ngokwanele; lokhu kungenzeka kungenxa
yokuswelakala kolwazi ngemisoco equkethwe kanye nokufaneleka njengokudla kwezilwane.
Kanti ngokwengamele, inhloso yalolu cwaningo bekuwukwenza iprofayili yemisoco
ngezinhlamvu zamabele athile eNingizimu Afrika kanye naseZimbabwe, ukufaneleka kwawo
njengomthombo wamandla (we-eneji) kubantu kanye nemfuyo, kanye nokwenza ucwaningo
ngemiphumela yenhlobo yamabele ngama-performance indices wamachwane e-ROss 308.
Kwisahluko 3, kusetshenziswe imetheriyali kanye namamethodi asetshenzisiwe ukufinyelela
isiphetho sezesayense kulolu cwaningo, kwafinyezwa. Kwisahluko 4 kwenziwe uhlaziyo
lokubambekayo kanye namakhemikhali ngezinhlamvu zamabele ngokutholakale eNingizimu
Afrika kanye naseZimbabwe, imiphumela ikhombise ukugqama kwe-physiochemical
kwezinhlamvu zamabele ukufaneleka kwazo njengekhandideti ekuthatheni isikhundla
sombila njengomthombo wamandla. Ukuqhubeka nokuqondisisa ukuphawuleka
kwezinhlamvu zamabele, iSahluko 5 sihlaziye ama-phenolic compound kwizinhlamvu
zamabele aseNingizimu Afrika neZimbabwe. Imiphumela ikhombisa ukuthi uhlamvu
lwamabele lunama-phenolic compound ayinzuzo ekudleni okunomsoco kubantu kanye
nezilwane, kanye nokuba wusizo lwenzuzo kwimpilo. Isahluko 6 siphenyisise ngamazinga
okubandakanywa kwamabele ukwenzela ukuthola ukufaneleka kwawo kumkhakha
wezinkukhu. Izinhlamvu zamabele e-pearl zisetshenziswe kule ekspirimenti, eyenziwa
ezigabeni ezehlukene zokuthuthukisa ukuzalisa kanye nokhetho olwenziwe ngabe-Grain
Crop Institute ePotchefstroom, eNingizimu Afrika. Amabele e-pearl asetshenziswe
njengomthombo omkhulu we-eneji kumachwane eRoss 308 isikhathi sezinsuku ezingu 42
kanti kwaphenyisiswa ngokusebenza kwama-indices. Imiphumela iveze ukuthi amabele epearl
angafakelwa kwidayethi yamachwane, ukuthatha isikhundla sombila, ngaphandle
kokuphazamisa ukusebenza. Nangaphezu kwalokho, ukufaneleka kwezomnotho ngokuthatha
isikhundla zombila sithathwa ngamabele e-pearl kuye kwacwaningwa. Izindleko
zezinhlamvu ziye zabekwa kanti futhi nesisindo ngezinhlamvu kuye kwabekwa. Imiphumela
ikhombisa ukuthi kuyinto enhle kwezomnotho ukuthatha isikhundla sombila sithathwa
ngamabele e-pearl kwidayethi yezinkukhu. Ukusebenza kwe-quadratic function kufaneleke
kakhulu kwi-optimum treatment combination mayelana nama-parameter okusebenza afana
nokwenyuka kwesisindo somzimba, ukuguqula i-feed conversion ratio kanye nezitho
zangaphakathi nazo ziye zahlolwa. KwiSahluko 7, ucwaningo kuye kwaxoxwa ngalo
ukuhlanganisa iziphetho zama-ekspirimenti enziwe. Izincomo ezinabile, ziye zanikezwa
ngama-compound ezinhlobo zamabele kanye nezinzuzo zawo kwezempilo kubantu kanye
nezilwane / Lefaseng ka bophara, leotša le bonwa bjalo ka mabele a bohlokwa kudu; le ge go le bjale, ke
dibjalo tšeo di sa bjalwego kudu. Dithoro tša leotša di tletše ka phepo ye ntši le ditswaki tša
fenoliki tšeo di nago le mohola maphelong, gomme se sa dira gore di be maleba bjalo ka dijo
le phepo. Dikagare tša lona tšeo di fapafapanego le ditswaki tša fenoliki tšeo di whetšagalago
ka gare ga leotša la finger le la pearl ke dilaetši tše kaone tša gore mehutahuta ya leotša yeo e
hwetšagalago e bohlokwa ge e kgethwa bjalo ka sejo le phepo. Diteng tša fenoliki tšeo di
hwetšwago ka agre ga leotša di na le diesiti tša fenoliki, difolabanoite, le dithaninse, tšeo di
lego mohola go maphelo a batho. Dinyakišišo di laeditše gore diteng tša fenoliki tša leotša di
na le mošomo wa godimo wa dihlwekišammele tšeo di bitšwago dianthioksitente.
Difaethokhemikhale tšeo di lego gona ka gare ga dithoro tša leotša di na le diabe tše kaone go
maphelo a batho ka go fokotša kholesterole le difaetheite mmeleng. Dinyakwa tša ka pela go
lefela le mešomo ya lona ka diintastering tše ntši di dirile gore go be le nyakego ye kgolo ya
dithoro tše dingwe tšeo di ka emelago lefela legato, go nolofatša kgatelelo yeo e beilwego go
lefela. Go tšeela lefela legato ka leotša la pearl le la finger ka dijong tša diphoofolo tšeo di
fapafapanego go feleleditše ka seabe se sekaone ka ga go šoma ga lona. Go fihla mo lebakeng
le, dithoro tša leotša di tsentšwe ka dijong tše dingwe gomme tša šomišwa go dira dino tša
setšo. Ka go Kgaolo ya 1, hlogotaba ya dinyakišišo e tsebagaditšwe, ya fa bohlokwa bja
dinyakišišo tše le lebaka mabapi le bohlokwa bja dithoro tša leotša. Maike
mišetšo le dinepo le tšona di filwe. Kgaolo ya 2 e hlagišitše tekodišišo ya dingwalwa ye e
tseneletšego ka ga leotša le mešomo ya lona go phepo ya batho le ya diphoofolo. Godimo ga
fao, tšhomišo ya tannin bjalo ka phepo ya boikgethelo le yona e lekodišišitšwe.
Dinyakišišo tše di fapafapanego di dirilwe go nyakišiša go ba maleba ga thoro ya leotša bjalo
ka methopo wa enetši, ka intastering ya diphoofolo. Le ge go le bjale, dinyakišišo tš0e di
dirilwego mabapi le mehuta ya leotša ka Borwa bja Afrika ke tše nnyane; se se ka ba se
bakwa ke tlhoklego ya Tshedimošo mabapi le sebiopego sa phepo ka hare ha leotša le go ba
maleba ga lona bjalo ka phepo ya diphoofolo. Ka kakaretšo, maikemišetšo a dinyakišišo tše e
bile go lebeledišiša dikokwane tša phepo tša dithoro tša leotša tšeo di kgethilwego ka Afrika
Borwa le ka Zimbabwe, go ba maleba ga lona bjalo ka methopo wa enetši go batho le go
diruiwa le go nyakišiša ka ga seabe ka ga mohuta wa leotša wa pearl go go šoma ga
dipalopalo go dikgogo tša nama tša Ross 308. Ka go Kgaolo ya 3, ditlabelo le mekgwa ka
kakaretšo yeo e šomišitšwego go fihlelela sephetho sa tša mahlale sa dinyakišišo tše di filwe
kakaretšo. Ka go Kgaolo ya 4, tshekatsheko ya naga le ya dikhemikhale e dirilwe mabapi le
dithoro tša leotša tšeo di hweditšwego ka Afrika Borwa le ka Zimbabwe, dipoelo di utollotše
gore dikagare tša dikhemikhale tša thoro ya leotša di le dira le be lebele leo le loketšego go
tšeela legato lefela bjalo ka methopo wa enetši. Go kwešiša go tšwela pele dikagare tša thoro
ya leotša, Kgaoilo ya 5 e sekasekile diteng tša fenoliki tšeo di hwetšagalago ka gare ga thoro
ya leotša leo le hwetšago ka Afrika Borwa le ka Zimbabwe. Dipoelo di laeditše gore thro ya
leotša le tletše ka dikagare tša fenoliki tšeo di lego mohola go phepo ya bobedi batho le
diphoofolo le gore le thuša bjalo ka kholego ya tša phepo. Kgaolo ya 6 e nyakišišitše maemo
a mehutahuta a kakaretšo a leotša la pearl ka nepo ya go hwetša motswako wa maleba kudu
ka lekaleng la dikgogo. Dithoro tša leotša la pearl tšeo di šomišitšwego ka mo tekodišišong
ye di sepedišitšwe ka go dikaonafatšo tše di fapanego tša monontšha gomme dikgetho di
dirilwe ka go Sehlongwa sa Dibjalo tša Dithoro ka Potchefstroom, ka Afrika Borwa. Dithoro
tša leotša la pearl di šomišitšwe bjalo ka mothopo wa enetši go matswiana a nama a Ross 308
mo matšatšing a 42 fao go dirilwego dinyakišišo ka ga dipalopalo tša go gola ga dikgogo.
Dipoelo di laeditše gore leotša la pearl le ka tsenywa ka dijong tša dikgogo tša nama, go
tšeela legato lefela, ka ntle le go ama gampe go gola ga dikgogo. Godimo ga fao, lebaka la tša
ekonomi la go tšeela lefela legato ka leotša la pearl le nyakišišitšwe. Theko ya dithoro e
hweditšwe gomme theko ka boima bjo itšego le yona e hweditšwe. Dipoelo di laeditše gore ka nnete go tloga go kwagalago kudu go tša ekonomi go tšeela lefela legato ka leotša la pearl.
Mošomo wa tekanelo wa wo o loketšego bokaone motswako wa tlhokomelo ya godimo
mabapi le mahlakore a kgodišo ya dikgogo a go swana le boima bja mmele, go nona, rešio ya
go fetošetša dijo le ditho tša ka gare le ona o lekodišišitšwe. Ka go Kgaolo ya 7, dinyakišišo
di hlalošitšwe ka kakaretšo gore go fihlelelwe sephetho ka ga ditekodišišo tšeo di dirilwego.
Ditšhišinyo ka kakaretšo le tšona di filwe mabapi le dikagare tša mehutahuta tša leotša le
dikholego tša ona go tša maphelo go bobedi batho le diphoofolo / College of Agriculture and Environmental Sciences / D. Phil. Agr. (Animal Science)
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Produtividade da soja em semeadura direta com antecipação da adubação fosfatada e potássica na cultura de Eleusine coracana (L.) Gaertn. / Soybean yield with phosphorus and potassium prefertilization on the Eleusine coracana (L.) Gaertn. in a no-tillage system.Segatelli, Cláudio Roberto 21 December 2004 (has links)
O presente experimento teve por objetivo avaliar a produtividade agrícola da soja em sistema de semeadura direta com antecipação da adubação fosfatada e potássica na cultura de Eleusine coracana, sustentando-se a hipótese de que a produtividade da soja não é reduzida devido à antecipação da adubação de base para a cultura de Eleusine coracana (L.) Gaertn. (capim-pé-de-galinha). O experimento foi conduzido na Estação Experimental Anhembi, Escola Superior de Agricultura "Luiz de Queiroz" (USP/ESALQ), no município de Piracicaba-SP, localizada à margem direita do Rio Tietê, na cabeceira da represa de Barra Bonita-SP, entre as coordenadas 22º 45e 22º 50 de latitude Sul, e 48º 00 e 45º 05de longitude Oeste, durante o ano agrícola de 2001/2002, em LATOSSOLO AMARELO Distrófico. A adubação, segundo a recomendação oficial para o estado de São Paulo, consistiu da aplicação de 90 kg de P2O5 ha-1, 50 kg de K2O ha-1 e de micronutrientes (Co, Cu, Fe, Mn, Mo e Zn). O experimento adotou delineamento em blocos completos ao acaso com três repetições. Os tratamentos experimentais consistiram em diferentes níveis de antecipação da adubação da soja, para a cultura do capim-pé-de-galinha, totalizando 12 tratamentos: T1 = nenhuma adubação; T2 = adubação convencional na soja; T3 = 50% de K, no capim-péde- galinha; T4 = 100% de K, no capim-pé-de-galinha; T5 = 50% de P, no capim-pé-degalinha; T6 = 50% de P e K, no capim-pé-de-galinha; T7 = 50% de P e 100 % de K, no capim-pé-de-galinha; T8 = 100% de P, no capim-pé-de-galinha; T9 = 100% de P e 50% de K, no capim-pé-de-galinha; T10 = 100% de P e K, no capim-pé-de-galinha; T11 = 100% de P e K + micronutrientes, no capim-pé-de-galinha; T12 = adubação foliar com micronutrientes, no capim-pé-de-galinha. As características avaliadas foram: a) capim pé-de-galinha: produção de matéria seca; b) soja: estande final, altura final de planta, porcentagem de plantas com haste verde, grau de acamamento, número de ramificações por planta, número de vagens chochas por planta, número de vagens de 3 cavidades com 3, 2 e 1 grão, número de vagens de 2 cavidades com 2 e 1 grão, número de vagens de 1 cavidade com 1 grão, número total de vagens por planta, número total de grãos por planta, peso de grãos por planta, peso de mil grãos e produtividade agrícola. As principais conclusões são: a) a adubação fosfatada e potássica da cultura da soja, antecipadas parcial ou totalmente para a semeadura do capim Eleusine coracana (L.) Gaertn., podem incrementar a produtividade agrícola de matéria seca do capim-pé-degalinha; b) a antecipação parcial ou total das adubações fosfatada e potássica da soja para a semeadura do Eleusine coracana (L.) Gaertn., nas condições em que foi instalado o experimento, não reduz a produtividade agrícola de grãos de soja; c) Trabalhos de pesquisa agronômica envolvendo estudos sobre adubação de agroecossistemas devem ser incentivados. / The present research evaluated soybean yield in a no-tillage system with previous potassium and phosphorus fertilization on the Eleusine coracana (L.) Gaertn. crop. The hypothesis was that soybean yield does not decrease due to previous fertilization on the Eleusine coracana (L.) Gaertn. (finger millet) crop. The experiment was carried out during the 2001/2002 growing season at the Estação Experimental Anhembi, Escola Superior de Agricultura "Luiz de Queiroz" (USP/ESALQ), in Piracicaba, São Paulo. The area is located at the right side bank of the Tietê river, at the beginning of the Barra Bonita Dam, between the coordinates 22º 45and 22º 50 latitude south, and 48º 00 and 45º 05 longitude west, in an Oxisol. The soybean fertilization was done according to the São Paulo State offical recommendation: 90 kg of P2O5 ha-1, 50 kg of K2O ha-1 and micronutrients (Co, Cu, Fe, Mn, Mo and Zn). The experiment designed in randomized complete blocks, with three replicates. The treatment consisted of differents levels of soybean pre-fertilization, on the finger millet crop, totalizing 12 treatments: T1 = no fertilization; T2 = conventional fertilization, on Soybean; T3 = 50% of K, on finger millet; T4 = 100% of K, on finger millet; T5 = 50% of P, on finger millet; T6 = 50% of both P and K, on finger millet; T7 = 50% of P and 100 % of K, on finger millet; T8 = 100% of P, on finger millet; T9 = 100% of P and 50% of K, on finger millet; T10 = 100% of P and K, on finger millet; T11 = 100% of P and K + micronutrients, on finger millet; T12 = fertilization with micronutrients, on finger millet. The evaluated chacaracters were: a) finger millet: dry matter production; b) soybean: final stand, final plant height, percentage of plants with green stems, bending, number of branches per plant, number of empty pods, number of pods with 3 cavities with 3, 2 and 1 grain, number of pods with 2 cavities with 2 and 1 grain, number of pods with 1 cavity with 1 grain, total number of pods per plant, total number of grains per plant, grain weight per plant, mass of 1,000 grains and total yield. The main conclusions are: a) phosphorus and potassium pre-fertilization on soybean, totally or partial applied to the Eleusine coracana (L.) Gaertn. crop, can increase the finger millet dry matter yield; b) total or partial pre-fertilization of soybean phosphorus and potassium on Eleusine coracana (L.) Gaertn. crop, under experimental conditions tested, does not decrease the soybean yield; c) more studies about fertilization in agroecosystems should be encouraged.
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Produtividade da soja em semeadura direta com antecipação da adubação na cultura de \"Eleusine coracana (L.) Gaertn.\" / Soybean yield with anticipated fertilization on the Eleusine coracana (L.) Gaertn. in a no-tillage systemSegatelli, Cláudio Roberto 26 June 2008 (has links)
Com o objetivo de avaliar os efeitos da adubação antecipada sobre a produção de matéria seca da cultura de Eleusine coracana, os caracteres produtivos, a qualidade fisiológica das sementes e a produtividade da cultura da soja em sucessão, sustentando-se a hipótese de que a produtividade da soja não é reduzida devido à antecipação da adubação de base para a cultura do capim-pé-de-galinha, foi conduzido o presente experimento na Estação Experimental Anhembi, Escola Superior de Agricultura Luiz de Queiroz (USP/ESALQ), no município de Piracicaba-SP, durante os anos agrícolas de 2001/2002, 2002/2003 e 2003/2004, em Latossolo Amarelo distrófico. A adubação consistiu da aplicação de 90 kg de P2O5 ha-1, 50 kg de K2O ha-1 e de micronutrientes (Co, Cu, Fe, Mn, Mo e Zn). O experimento adotou delineamento em blocos completos ao acaso com três repetições e 12 tratamentos que consistiram em diferentes níveis de antecipação da adubação da soja para a cultura do capim-pé-degalinha: T1= nenhuma adubação; T2= adubação convencional na soja; T3= antecipação de 50% de K, no capim-pé-de-galinha; T4= antecipação de 100% de K, no capim-pé-de-galinha; T5= antecipação de 50% de P, no capim-pé-de-galinha; T6= antecipação de 50% de P e K, no capim-pé-de-galinha; T7= antecipação de 50% de P e 100 % de K, no capim-pé-de-galinha; T8= antecipação de 100% de P, no capim-pé-degalinha; T9= antecipação de 100% de P e 50% de K, no capim-pé-de-galinha; T10= antecipação de 100% de P e K, no capim-pé-de-galinha; T11= antecipação de 100% de P e K + micronutrientes, no capim-pé-de-galinha; T12= antecipação da adubação foliar com micronutrientes, no capim-pé-de-galinha. As características avaliadas foram: a) capim pé-de-galinha: produtividade de matéria seca da parte aérea; b) soja: estande final, altura final de planta, grau de acamamento, número de ramificações por planta, número de vagens chochas por planta, número de vagens de 3 cavidades com 3, 2 e 1 semente, número de vagens de 2 cavidades com 2 e 1 semente, número de vagens de 1 cavidade com 1 semente, número total de vagens e de sementes por planta, peso de sementes por planta, peso de mil sementes e produtividade agrícola. As sementes de soja foram submetidas aos testes de germinação, de envelhecimento acelerado e de emergência em areia. Conclui-se: a) A antecipação das adubações fosfatada e potássica da soja para a semeadura do Eleusine coracana, incrementa a produtividade de matéria seca deste; b) A ausência de adubação do sistema de produção envolvendo a semeadura direta da soja em sucessão à cultura de cobertura com o capim-pé-degalinha conduz, ao longo das sucessivas safras, a perdas de produtividades agrícolas de matéria seca do capim-pé-de-galinha e de sementes de soja; c) A antecipação da adubação de base da cultura da soja para o capim-pé-de-galinha não interfere com a quantidade total de vagens formadas pelas plantas de soja; e, d) A antecipação da adubação de semeadura com fósforo e potássio da cultura da soja para a semeadura do capim-pé-de-galinha não interfere com a massa de mil sementes e nem com a produtividade agrícola da soja. / A research was carried out with the aim of evaluating the effects of anticipated fertilization on the production of Eleusine coracana dry matter as well as it productive features. In addition to it, the physiological quality of the seeds and the culture yield were also evaluated, taking into account the hypothesis that soybean yield is not reduced due to the anticipated base fertilization of the finger millet culture. The experiment was conducted at the Estação Experimental Anhembi, Escola Superior de Agricultura Luiz de Queiroz (USP/ESALQ), in Piracicaba/SP, during the growing seasons of 2001/2002, 2002/2003 and 2003/2004, in an Oxisol. The fertilization consisted on the application of 90 kg of P2O5 ha-1, 50 kg of K2O ha-1 and micronutrients (Co, Cu, Fe, Mn, Mo and Zn). The experiment adopted a completely randomized blocks design with three repetitions and twelve treatments, which comprehended different levels of anticipated soybean fertilization for the culture of finger millet, as it follows: T1= without fertilization ; T2= traditional soybean fertilization; T3= anticipation of 50% of K on finger millet; T4= anticipation of 100% of K, on finger millet; T5= anticipation of 50% of P on finger millet; T6= anticipation of 50% of K and P on finger millet; T7= anticipation of 50% of P and 100% of K on finger millet; T8= anticipation of 100% of P on finger millet; T9= anticipation of 100% of P and 50% of K on finger millet; T10 = anticipation of 100% of P and K on finger millet; T11 = anticipation of 50% of K on finger millet; T11 = anticipation of 100% of P and K + micronutrients on finger millet; T12 = anticipation of foliar fertilization with micronutrients on finger millet. The evaluated characteristics were: a) finger millet: dry matter production; b) soybean: final stand, final plant height, lodging, number of branches per plant, number of empty pods per plant, number of pods with 3 cavities with 3, 2 and 1 seed, number of pods with 2 cavities with 2 and 1 seed, number of pods with 1 cavity and 1 seed, total number of pods per plant, seed weight per plant, mass of 1,000 seeds and total yield. Soybean seeds were submitted to germination tests, accelerated ageing tests and well as tests of sand emergency. It was concluded that: a) Phosphorus and potassium anticipated fertilization on soybean applied to the Eleusine coracana (L.) Gaertn. crop can increase the finger millet dry matter yield; b) The absence of fertilization on the soybean no-tillage yield system succeeding the finger millet cover culture can cause the decrease of total yield of finger millet dry matter and soybean seeds; c) The anticipation of base fertilization of soybean culture for finger millet does not interfere with the total amount of pods generated by soybean plants; and d) Phosphorus and potassium anticipated fertilization on soybean culture for finger millet crop do not interfere with the mass of 1,000 seeds and total soybean yield.
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Produtividade da soja em semeadura direta com antecipação da adubação fosfatada e potássica na cultura de Eleusine coracana (L.) Gaertn. / Soybean yield with phosphorus and potassium prefertilization on the Eleusine coracana (L.) Gaertn. in a no-tillage system.Cláudio Roberto Segatelli 21 December 2004 (has links)
O presente experimento teve por objetivo avaliar a produtividade agrícola da soja em sistema de semeadura direta com antecipação da adubação fosfatada e potássica na cultura de Eleusine coracana, sustentando-se a hipótese de que a produtividade da soja não é reduzida devido à antecipação da adubação de base para a cultura de Eleusine coracana (L.) Gaertn. (capim-pé-de-galinha). O experimento foi conduzido na Estação Experimental Anhembi, Escola Superior de Agricultura Luiz de Queiroz (USP/ESALQ), no município de Piracicaba-SP, localizada à margem direita do Rio Tietê, na cabeceira da represa de Barra Bonita-SP, entre as coordenadas 22º 45e 22º 50 de latitude Sul, e 48º 00 e 45º 05de longitude Oeste, durante o ano agrícola de 2001/2002, em LATOSSOLO AMARELO Distrófico. A adubação, segundo a recomendação oficial para o estado de São Paulo, consistiu da aplicação de 90 kg de P2O5 ha-1, 50 kg de K2O ha-1 e de micronutrientes (Co, Cu, Fe, Mn, Mo e Zn). O experimento adotou delineamento em blocos completos ao acaso com três repetições. Os tratamentos experimentais consistiram em diferentes níveis de antecipação da adubação da soja, para a cultura do capim-pé-de-galinha, totalizando 12 tratamentos: T1 = nenhuma adubação; T2 = adubação convencional na soja; T3 = 50% de K, no capim-péde- galinha; T4 = 100% de K, no capim-pé-de-galinha; T5 = 50% de P, no capim-pé-degalinha; T6 = 50% de P e K, no capim-pé-de-galinha; T7 = 50% de P e 100 % de K, no capim-pé-de-galinha; T8 = 100% de P, no capim-pé-de-galinha; T9 = 100% de P e 50% de K, no capim-pé-de-galinha; T10 = 100% de P e K, no capim-pé-de-galinha; T11 = 100% de P e K + micronutrientes, no capim-pé-de-galinha; T12 = adubação foliar com micronutrientes, no capim-pé-de-galinha. As características avaliadas foram: a) capim pé-de-galinha: produção de matéria seca; b) soja: estande final, altura final de planta, porcentagem de plantas com haste verde, grau de acamamento, número de ramificações por planta, número de vagens chochas por planta, número de vagens de 3 cavidades com 3, 2 e 1 grão, número de vagens de 2 cavidades com 2 e 1 grão, número de vagens de 1 cavidade com 1 grão, número total de vagens por planta, número total de grãos por planta, peso de grãos por planta, peso de mil grãos e produtividade agrícola. As principais conclusões são: a) a adubação fosfatada e potássica da cultura da soja, antecipadas parcial ou totalmente para a semeadura do capim Eleusine coracana (L.) Gaertn., podem incrementar a produtividade agrícola de matéria seca do capim-pé-degalinha; b) a antecipação parcial ou total das adubações fosfatada e potássica da soja para a semeadura do Eleusine coracana (L.) Gaertn., nas condições em que foi instalado o experimento, não reduz a produtividade agrícola de grãos de soja; c) Trabalhos de pesquisa agronômica envolvendo estudos sobre adubação de agroecossistemas devem ser incentivados. / The present research evaluated soybean yield in a no-tillage system with previous potassium and phosphorus fertilization on the Eleusine coracana (L.) Gaertn. crop. The hypothesis was that soybean yield does not decrease due to previous fertilization on the Eleusine coracana (L.) Gaertn. (finger millet) crop. The experiment was carried out during the 2001/2002 growing season at the Estação Experimental Anhembi, Escola Superior de Agricultura Luiz de Queiroz (USP/ESALQ), in Piracicaba, São Paulo. The area is located at the right side bank of the Tietê river, at the beginning of the Barra Bonita Dam, between the coordinates 22º 45and 22º 50 latitude south, and 48º 00 and 45º 05 longitude west, in an Oxisol. The soybean fertilization was done according to the São Paulo State offical recommendation: 90 kg of P2O5 ha-1, 50 kg of K2O ha-1 and micronutrients (Co, Cu, Fe, Mn, Mo and Zn). The experiment designed in randomized complete blocks, with three replicates. The treatment consisted of differents levels of soybean pre-fertilization, on the finger millet crop, totalizing 12 treatments: T1 = no fertilization; T2 = conventional fertilization, on Soybean; T3 = 50% of K, on finger millet; T4 = 100% of K, on finger millet; T5 = 50% of P, on finger millet; T6 = 50% of both P and K, on finger millet; T7 = 50% of P and 100 % of K, on finger millet; T8 = 100% of P, on finger millet; T9 = 100% of P and 50% of K, on finger millet; T10 = 100% of P and K, on finger millet; T11 = 100% of P and K + micronutrients, on finger millet; T12 = fertilization with micronutrients, on finger millet. The evaluated chacaracters were: a) finger millet: dry matter production; b) soybean: final stand, final plant height, percentage of plants with green stems, bending, number of branches per plant, number of empty pods, number of pods with 3 cavities with 3, 2 and 1 grain, number of pods with 2 cavities with 2 and 1 grain, number of pods with 1 cavity with 1 grain, total number of pods per plant, total number of grains per plant, grain weight per plant, mass of 1,000 grains and total yield. The main conclusions are: a) phosphorus and potassium pre-fertilization on soybean, totally or partial applied to the Eleusine coracana (L.) Gaertn. crop, can increase the finger millet dry matter yield; b) total or partial pre-fertilization of soybean phosphorus and potassium on Eleusine coracana (L.) Gaertn. crop, under experimental conditions tested, does not decrease the soybean yield; c) more studies about fertilization in agroecosystems should be encouraged.
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