Increasing grain yield (GY) and water use efficiency (WUE) of winter wheat in the Huaibei Plain (HP) is essential.  However, the effects of micro-sprinkler irrigation and topsoil compaction after wheat seeds sowing on the GY and WUE are unclear.  Therefore, a two-year field experiment was conducted during the 2021–2023 winter wheat growing seasons with a total six treatments: rain-fed (RF), conventional irrigation (CI) and micro-sprinkler irrigation (MI), as well as topsoil compaction after seeds sowing under three irrigation methods (RFC, CIC, and MIC).  The two years’ results indicated that MI significantly increased GY compared to CI and RF, which averagely increased by 17.9 and 42.1%, respectively.  The increase in GY of MI was due to its significant increase in the number of spikes, kernels per spike, and grain weight.  Chlorophyll concentration in flag leaves of MI after anthesis stage was maintained higher levels than CI and RF, RF was the lowest.  This was due to the dramatically enhanced catalase and peroxidase activity and lower malondialdehyde content under MI.  Compared with RF and CI, MI significantly promoted dry matter remobilization and production after anthesis as well as its contribution to GY.  In addition, MI significantly boosted root growth, and root activity during grain filling stage was remarkably enhanced than CI and RF.  In 2021–2022, there was no significant difference in WUE between MI and RF, but the WUE of RF was significantly lower than MI in 2022–2023.  However, WUE in MI was significantly improved compared to CI, that averagely increased by 15.1 and 17.6% for the two years.  Topsoil compaction significantly increased GY and WUE under rain-fed conditions due to improved spike numbers and dry matter production.  Overall, topsoil compaction is advisable for enhancing GY and WUE in rain-fed conditions, whereas micro-sprinkler irrigation can be adopted to achieve high GY and WUE simultaneously in the HP.

Wheat (Triticum aestivum L.) is a major food crop grown worldwide; yet, field-grown wheat is generally restricted to only one generation per year and has a fluctuating yield, limiting wheat improvement and failing to meet future food demand.  To minimize generation time and increase total annually wheat production, five light regimens with varied day length and spectral distribution, including 12 h light/12 h dark+white light (P12W), 17 h light/7 h dark+white light (P17W), 22 h light/2 h dark+white light (P22W), 22 h light/2 h dark+red:green:blue light=6:3:2 (P22RGB), and 22 h light/2 h dark+red:blue light=6:1 (P22RB), were developed by adjusting the light emitting diodes (LEDs) in the controlled environment.  The results showed that controlled wheat agriculture illuminated by LED sources equipped with various day lengths and spectral distributions had the potential for “faster” and “more” grain production.  Prolonged day length (from 12 h to 17 h and then to 22 h) accelerated wheat development, particularly shortening the duration before flowering, and that the longer the prolonged time, the earlier the flowering.  However, 22 h day length (e.g., P22W treatment) would affect plant morphological traits, reduce dry matter accumulation, and result in a loss of yield-related components due to increased stress and disrupted pollen development.  Surprisingly, regulating the spectral distribution towards the red-light region under long-day conditions (e.g., P22RB treatment) could partially restore the grain yield of wheat.  The light regime with a rich red-light region contributed to dry matter accumulation, carbohydrate flow to reproductive tissues, and sporopollenin biosynthesis, resulting in improved plant morphology and grain yield in wheat.  Collectively, the optimized light regimes, represented by P17W and P22RB treatments in controlled environment agriculture, can produce 5-6 generations of wheat per year, yielding 3.16-5.87 kg m^-2 yr^-1, which is 3.59-6.68 times higher than field cultivation.  Thus, conducting appropriate LED light regimens is a favorable way to achieve the dual goals of “faster and more” in controlled wheat cultivation. 

The Loxostege sticticalis (Lepidoptera: Pyralidae) is a major migratory pest of agriculture and animal husbandry in Asia and Europe. Utilizing plant volatile organic compounds (pVOCs) as attractants for monitoring and controlling pests is considered an environmentally friendly and effective method. However, limited knowledge exists regarding applying pVOCs to manage L. sticticalis. Here, volatile compounds released by Chenopodium album, Setaria viridis, and Medicago sativa, the three preferred oviposition plants for L. sticticalis females, were collected using dynamic headspace sampling techniques. A total of 55 distinct compounds were identified through gas chromatography-mass spectrometry (GC-MS), and 16 compounds in the concentration range from 0.001 to 100 µg µL^-1 elicited consistently enhanced electrophysiological responses in both male and female L. sticticalis. Subsequently, the attraction potential of four bioactive compounds—linalool, cis-anethole, trans-2-hexenal, and 1-octen-3-ol—were further confirmed by indoor behavioral bioassays. The blends of linalool, cis-anethole, trans-2-hexenal, and 1-octen-3-ol mixed at ratios of 5:1:5:10 (formulation No. 25) and 5:1:1:10 (formulation No. 21) were highly attractive to L. sticticalis adults. Field-trapping assays indicated that lure No. 2 baited with formulation 21 demonstrated superior efficacy in field trapping. These findings suggest that pVOC-based attractants can be effectively employed for monitoring and mass trapping L. sticticalis adults, providing insights into the development of botanical attractants.