FRINK Linked Data Fragments server

Matches in SemOpenAlex for { <https://semopenalex.org/work/W4281488210> ?p ?o ?g. }

• W4281488210 endingPage "1251" @default.
• W4281488210 startingPage "1251" @default.
• W4281488210 abstract "Most of the arid and semi-arid regions, particularly in the Mediterranean area, suffer from the lack of a sufficient quantity of high-quality feed, as well as a low amount of rainfall that is unevenly distributed, resulting in the region being highly vulnerable to drought. A field experiment was carried out at the experimental station of the Faculty of Desert and Environmental Agriculture, Fuka, Matrouh University, Egypt during the winter seasons of 2018/19 and 2019/20 to study the performance of triticale (X Triticosecale Wittmack), grown under water deficit conditions, in terms of productivity and quality. The study investigated the influence of five levels of potassium fertilization (PF; 0, 43.2, 86.4, 129.6, and 172.8 kg ha−1) and ascorbic acid (AA; 0, 25, 50, 75, and 100 mg L−1) that was applied to the triticale grains before sowing and humic acid (HA; 0, 2.4, 4.8, 7.2, and 9.6 kg ha−1) that was applied as powder to the soil 21 days after sowing followed by sprinkler irrigation on triticale forage and grain production when forage was removed at variable ages at cutting (AC), determined as days after sowing (AC; 40, 65, 90, 115, and 140 DAS) on forage yield and nutritive value, in addition to the final grain yield of triticale. The experimental design was a central composite design with one replicate. Results indicated that the PF*AC interaction was significant, and it gave values of 84.78 and 238.00 g kg−1 for crude protein (CP) and degraded neutral detergent fiber (DNDF). In addition, the interaction between AA and AC was significant for CP, acid detergent fiber (ADF), 100-grain weight (100 GW), number of spikes m−2 (NSM−2), and plant height (PH). Moreover, the AC*HA interaction was significant with values of 175.17 and 247.00 g kg−1 for CP and DNDF, respectively, and 0.55 t ha−1 for grain yield (GY). Age at cutting exerted the strongest effect on the studied characteristics. It was observed that the contents of neutral detergent fiber (NDF), ADF, acid detergent lignin (ADL), and non-fiber carbohydrates (NFC) in the triticale forage significantly increased when the crop was cut at an advanced age, unlike CP, DNDF, GY, NSM−2, 100 GW, and PH that decreased with advanced AC. The highest values of 271.00, 256.00, and 268.00 g kg−1 for DNDF were obtained with higher levels of either PF, AA, or HA, respectively. However, the highest value of GY (0.97 t ha−1) was obtained with higher levels of PF*HA averaged over the two seasons. The interaction between AA*HA resulted in 393.39, 311.00, 27.13 g kg−1, and 0.94 t ha−1, for NDF, DNDF, ADL, and GY, respectively. The highest significant NDF (413.11 g kg−1) and DNDF (307.50 g ka−1) values were obtained with the application of high levels of either AA or HA. In the dual-purpose production system, it is recommended to cut the triticale crop at 65 DAS to achieve the optimum balance between forage yield and quality on the one hand, and final grain yield on the other hand. In the arid regions, application of PF, AA, and HA could help in reducing the damage caused by water deficit." @default.
• W4281488210 created "2022-05-26" @default.
• W4281488210 creator A5004399083 @default.
• W4281488210 creator A5027935967 @default.
• W4281488210 creator A5037937230 @default.
• W4281488210 creator A5074410091 @default.
• W4281488210 creator A5088261215 @default.
• W4281488210 date "2022-05-24" @default.
• W4281488210 modified "2023-09-27" @default.
• W4281488210 title "The Production of Dual-Purpose Triticale in Arid Regions: Application of Organic and Inorganic Treatments under Water Deficit Conditions" @default.
• W4281488210 cites W1980113381 @default.
• W4281488210 cites W1997087247 @default.
• W4281488210 cites W2001502781 @default.
• W4281488210 cites W2004756646 @default.
• W4281488210 cites W2017989335 @default.
• W4281488210 cites W2052143091 @default.
• W4281488210 cites W2063210991 @default.
• W4281488210 cites W2101803882 @default.
• W4281488210 cites W2125020329 @default.
• W4281488210 cites W2156231662 @default.
• W4281488210 cites W2168825044 @default.
• W4281488210 cites W2169111888 @default.
• W4281488210 cites W2488280985 @default.
• W4281488210 cites W2509112010 @default.
• W4281488210 cites W2517199178 @default.
• W4281488210 cites W2608985635 @default.
• W4281488210 cites W2625544128 @default.
• W4281488210 cites W2784963478 @default.
• W4281488210 cites W2803104938 @default.
• W4281488210 cites W2884837980 @default.
• W4281488210 cites W2899939106 @default.
• W4281488210 cites W2952341691 @default.
• W4281488210 cites W2958865430 @default.
• W4281488210 cites W2978062057 @default.
• W4281488210 cites W2985625903 @default.
• W4281488210 cites W3007862655 @default.
• W4281488210 cites W3028374764 @default.
• W4281488210 cites W3037023496 @default.
• W4281488210 cites W3049665723 @default.
• W4281488210 cites W3098730935 @default.
• W4281488210 cites W3107950208 @default.
• W4281488210 cites W3108053444 @default.
• W4281488210 cites W3113989076 @default.
• W4281488210 cites W3121434130 @default.
• W4281488210 cites W3131803658 @default.
• W4281488210 cites W3167317454 @default.
• W4281488210 cites W3191061040 @default.
• W4281488210 cites W3197082572 @default.
• W4281488210 cites W3212945628 @default.
• W4281488210 cites W4242186041 @default.
• W4281488210 cites W823724422 @default.
• W4281488210 doi "https://doi.org/10.3390/agronomy12061251" @default.
• W4281488210 hasPublicationYear "2022" @default.
• W4281488210 type Work @default.
• W4281488210 citedByCount "1" @default.
• W4281488210 countsByYear W42814882102022 @default.
• W4281488210 crossrefType "journal-article" @default.
• W4281488210 hasAuthorship W4281488210A5004399083 @default.
• W4281488210 hasAuthorship W4281488210A5027935967 @default.
• W4281488210 hasAuthorship W4281488210A5037937230 @default.
• W4281488210 hasAuthorship W4281488210A5074410091 @default.
• W4281488210 hasAuthorship W4281488210A5088261215 @default.
• W4281488210 hasBestOaLocation W42814882101 @default.
• W4281488210 hasConcept C144027150 @default.
• W4281488210 hasConcept C150772632 @default.
• W4281488210 hasConcept C151730666 @default.
• W4281488210 hasConcept C168741863 @default.
• W4281488210 hasConcept C2778053677 @default.
• W4281488210 hasConcept C2779370140 @default.
• W4281488210 hasConcept C2781396250 @default.
• W4281488210 hasConcept C2986274086 @default.
• W4281488210 hasConcept C39432304 @default.
• W4281488210 hasConcept C6557445 @default.
• W4281488210 hasConcept C86803240 @default.
• W4281488210 hasConcept C88862950 @default.
• W4281488210 hasConcept C88972607 @default.
• W4281488210 hasConceptScore W4281488210C144027150 @default.
• W4281488210 hasConceptScore W4281488210C150772632 @default.
• W4281488210 hasConceptScore W4281488210C151730666 @default.
• W4281488210 hasConceptScore W4281488210C168741863 @default.
• W4281488210 hasConceptScore W4281488210C2778053677 @default.
• W4281488210 hasConceptScore W4281488210C2779370140 @default.
• W4281488210 hasConceptScore W4281488210C2781396250 @default.
• W4281488210 hasConceptScore W4281488210C2986274086 @default.
• W4281488210 hasConceptScore W4281488210C39432304 @default.
• W4281488210 hasConceptScore W4281488210C6557445 @default.
• W4281488210 hasConceptScore W4281488210C86803240 @default.
• W4281488210 hasConceptScore W4281488210C88862950 @default.
• W4281488210 hasConceptScore W4281488210C88972607 @default.
• W4281488210 hasIssue "6" @default.
• W4281488210 hasLocation W42814882101 @default.
• W4281488210 hasLocation W42814882102 @default.
• W4281488210 hasOpenAccess W4281488210 @default.
• W4281488210 hasPrimaryLocation W42814882101 @default.
• W4281488210 hasRelatedWork W1970753720 @default.
• W4281488210 hasRelatedWork W1981150190 @default.
• W4281488210 hasRelatedWork W2028158369 @default.
• W4281488210 hasRelatedWork W2037414141 @default.

• next