FRINK Linked Data Fragments server

Matches in SemOpenAlex for { <https://semopenalex.org/work/W4377104042> ?p ?o ?g. }

• W4377104042 endingPage "1390" @default.
• W4377104042 startingPage "1390" @default.
• W4377104042 abstract "Benefiting from the high–farmland construction program in China, one–off irrigation can be guaranteed in most fields in semi–humid drought–prone areas in China. However, little information is available on water and nitrogen (N) management in wheat production under this condition. This study aimed to explore the effects of alternative furrow irrigation (AFI) and topdressing N fertilizer (TN) on wheat productivity under a no–till ridge–furrow planting system in semi–humid drought–prone areas. The experimental design was as follows: two furrow irrigation (FI) methods, namely, EFI (every furrow irrigation) and AFI (alternative furrow irrigation) with 75 mm at the jointing stage were set as the main treatments. Two topdressing N (TN) patterns, namely, NTN (0 kg ha−1 of N) and TN (60 kg ha−1 of N) along with irrigation were set as the secondary treatments. Moreover, a traditional planting practice with no irrigation and no topdressing N (NINTN) was set as control. In 2018–2020, a field experiment was carried out to investigate the effects on soil water, leaf chlorophyll relative content (SPAD) and net photosynthetic rate (Pn), aboveground dry matter assimilates, grain yield, water use efficiency (WUE) and economic benefit. We found that both FI methods and TN patterns significantly influenced soil water content. Compared with NINTN, the soil water content in each combination of the FI method and TN pattern was effectively improved at the booting and anthesis stages, leading to the significant increase in SPAD and Pn in leaves, post–anthesis dry matter accumulation (POA), grain yield, WUE and economic benefit of winter wheat. Compared with the EFI, averaged across years and TN patterns, the AFI technique increased the soil water storage at booting and anthesis stages and significantly improved the Pn at early milk (4.9%) and early dough (7.5%) stages, POA (40.6%) and its contribution to grain (CRPOA, 27.6%), the grain yield (10.2%), WUE (9.1%) and economic benefit (9.1%). In addition, compared with the NTN, the TN pattern significantly increased the water computation by wheat from booting to maturity, enhanced leaf Pn after anthesis and POA, and finally resulted in the increase in grain yield (14.7–21.9%) and WUE (9.6–21.1%). Thus, the greatest improvement in the leaf photosynthetic characteristics, aboveground dry matter assimilates, grain yield, WUE and economic benefit was achieved under AFITN treatment. Above all, it can be concluded that the AFITN with AFI of 75 mm and TN of 60 kg ha−1 at jointing was an alternative management strategy for optimizing yield formation and water use of winter wheat. This study provided new insights into improving wheat productivity in drought–prone areas where one–off irrigation can be guaranteed." @default.
• W4377104042 created "2023-05-20" @default.
• W4377104042 creator A5000925508 @default.
• W4377104042 creator A5002123251 @default.
• W4377104042 creator A5006709916 @default.
• W4377104042 creator A5035667943 @default.
• W4377104042 creator A5054962488 @default.
• W4377104042 creator A5085512975 @default.
• W4377104042 creator A5086452435 @default.
• W4377104042 date "2023-05-18" @default.
• W4377104042 modified "2023-09-26" @default.
• W4377104042 title "Alternative Furrow Irrigation Combined with Topdressing Nitrogen at Jointing Help Yield Formation and Water Use of Winter Wheat under No-Till Ridge Furrow Planting System in Semi-Humid Drought-Prone Areas of China" @default.
• W4377104042 cites W131627916 @default.
• W4377104042 cites W1858464019 @default.
• W4377104042 cites W1861851203 @default.
• W4377104042 cites W1982650049 @default.
• W4377104042 cites W1985599952 @default.
• W4377104042 cites W1999671405 @default.
• W4377104042 cites W2030563653 @default.
• W4377104042 cites W2044741379 @default.
• W4377104042 cites W2047753898 @default.
• W4377104042 cites W2063146899 @default.
• W4377104042 cites W2068522553 @default.
• W4377104042 cites W2095082318 @default.
• W4377104042 cites W2159051252 @default.
• W4377104042 cites W2165885804 @default.
• W4377104042 cites W2308917383 @default.
• W4377104042 cites W2529746529 @default.
• W4377104042 cites W2553164091 @default.
• W4377104042 cites W2741865589 @default.
• W4377104042 cites W2782514625 @default.
• W4377104042 cites W2788042343 @default.
• W4377104042 cites W2794148606 @default.
• W4377104042 cites W2801804720 @default.
• W4377104042 cites W2910930795 @default.
• W4377104042 cites W2917028099 @default.
• W4377104042 cites W2933165776 @default.
• W4377104042 cites W2973147450 @default.
• W4377104042 cites W2978661116 @default.
• W4377104042 cites W2981166742 @default.
• W4377104042 cites W2999458053 @default.
• W4377104042 cites W3035312638 @default.
• W4377104042 cites W3043702607 @default.
• W4377104042 cites W3095521873 @default.
• W4377104042 cites W3122376434 @default.
• W4377104042 cites W3124607058 @default.
• W4377104042 cites W3166320419 @default.
• W4377104042 cites W3177152493 @default.
• W4377104042 cites W4223500821 @default.
• W4377104042 cites W4288748542 @default.
• W4377104042 cites W4295073587 @default.
• W4377104042 cites W4303945783 @default.
• W4377104042 cites W4353109132 @default.
• W4377104042 cites W597268002 @default.
• W4377104042 cites W4236042297 @default.
• W4377104042 doi "https://doi.org/10.3390/agronomy13051390" @default.
• W4377104042 hasPublicationYear "2023" @default.
• W4377104042 type Work @default.
• W4377104042 citedByCount "0" @default.
• W4377104042 crossrefType "journal-article" @default.
• W4377104042 hasAuthorship W4377104042A5000925508 @default.
• W4377104042 hasAuthorship W4377104042A5002123251 @default.
• W4377104042 hasAuthorship W4377104042A5006709916 @default.
• W4377104042 hasAuthorship W4377104042A5035667943 @default.
• W4377104042 hasAuthorship W4377104042A5054962488 @default.
• W4377104042 hasAuthorship W4377104042A5085512975 @default.
• W4377104042 hasAuthorship W4377104042A5086452435 @default.
• W4377104042 hasBestOaLocation W43771040421 @default.
• W4377104042 hasConcept C127413603 @default.
• W4377104042 hasConcept C159390177 @default.
• W4377104042 hasConcept C159750122 @default.
• W4377104042 hasConcept C168741863 @default.
• W4377104042 hasConcept C187320778 @default.
• W4377104042 hasConcept C197321923 @default.
• W4377104042 hasConcept C24939127 @default.
• W4377104042 hasConcept C2776325102 @default.
• W4377104042 hasConcept C2780138947 @default.
• W4377104042 hasConcept C2780512892 @default.
• W4377104042 hasConcept C39432304 @default.
• W4377104042 hasConcept C41478065 @default.
• W4377104042 hasConcept C6557445 @default.
• W4377104042 hasConcept C75639521 @default.
• W4377104042 hasConcept C86803240 @default.
• W4377104042 hasConcept C88862950 @default.
• W4377104042 hasConceptScore W4377104042C127413603 @default.
• W4377104042 hasConceptScore W4377104042C159390177 @default.
• W4377104042 hasConceptScore W4377104042C159750122 @default.
• W4377104042 hasConceptScore W4377104042C168741863 @default.
• W4377104042 hasConceptScore W4377104042C187320778 @default.
• W4377104042 hasConceptScore W4377104042C197321923 @default.
• W4377104042 hasConceptScore W4377104042C24939127 @default.
• W4377104042 hasConceptScore W4377104042C2776325102 @default.
• W4377104042 hasConceptScore W4377104042C2780138947 @default.
• W4377104042 hasConceptScore W4377104042C2780512892 @default.
• W4377104042 hasConceptScore W4377104042C39432304 @default.
• W4377104042 hasConceptScore W4377104042C41478065 @default.
• W4377104042 hasConceptScore W4377104042C6557445 @default.
• W4377104042 hasConceptScore W4377104042C75639521 @default.

• next