Low Grain Research Articles

Boron's Role in Diminishing Cadmium Concentrations in Rice (Oryza sativa L.): Insights into Absorption Inhibition and Ripening Promotion.

Boron, a crucial element for plant growth, has been demonstrated to mitigate cadmium (Cd) absorption in rice seedlings. However, its impact on Cd accumulation in rice grains and the underlying regulatory mechanisms remain poorly understood. The current study explored the roles of boron in reducing Cd accumulation and promoting ripening in rice through pot and hydroponic experiments. The results revealed that the basal boron application (1.5 mg kg-1) decreased grain Cd concentration by 61.1%, primarily due to the synergistic effects of inhibited Cd uptake and transport, along with increased maturation. Boron mitigated the root Cd2+ influx by 32.4% and transport factors by 36.0-47.3% primarily by downregulating the expression of OsNramp5, OsIRT1, and OsHMA2. Moreover, boron enhanced the activities of key sucrose-metabolizing enzymes and increased the relative expression levels of genes associated with sugar metabolism and transport, thereby shortening the rice growth period from 132 to 120 d. Field experiment confirmed that boron application decreased rice grain Cd concentration by 47.7% while promoting earlier maturation. This study elucidates the mechanism behind boron's ability to lower grain Cd levels and highlights its potential as an effective agronomic approach to mitigate food safety risks in rice grown on Cd-contaminated paddy soils.

Impact of Combined Vermicompost and Inorganic Fertilizers on Bread Wheat Yield, Yield Component and Soil Properties in Sinana District, Bale Highlands, Ethiopia

A field experiment was made to evaluate the effects of organic and inorganic fertilizers on the growth and yield of wheat and soil chemical properties. The study was conducted for two consecutive cropping seasons (2023-2024) on farmers’ fields in the Sinana district of Oromia National Regional State. Therefore, this study has attempted to evaluate the effect of the integrated use of vermicompost and inorganic fertilizer on bread wheat production and soil fertility improvement in the study area. Fertilizer source organic Sources of nutrients both included (vermicompost) and inorganic fertilizer (urea and NPS) were used in the integrated form. These treatments consist of: T1 = Control (no input) T2 = Recommend NP, T3 =25% RVC + 75% N + Rec P, T4 =100% RVC + rec P, T5 =50% RVC + 50% N + rec P and T6 =75% RVC + 25% N + Rec P. The experiment was a randomized complete block design with three replications. Soil sampling and agronomic data on wheat grain yield and yield components were collected. Accordingly, the highest mean grain yield (5403.67kgha-1) was recorded from the plot of T2 (Recommended rate from inorganic) flowed by (5186.00 kgha-1) was recorded from T3 (25% RVC + 75% N + Rec P) while the lowest grain yield (2637.67 kgha-1) was recorded from control plot. The partial budget analysis was performed for alternative uses of integrated organic and inorganic fertilizer applications for bread wheat production. The results showed that the application of integrated vermicompost with recommended rates of inorganic NP significantly increased the yield and yield components. It can be concluded that the application of integrated vermicompost and recommended rate of inorganic NP fertilizers (25 % Equivalent N from + 75 % N + Rec P is desirable) based on environmental sustainability for future productivity. This experiment has to be repeated over seasons and locations to make conclusive recommendations for the study area.

Cereal-legume intercropping enhances the quality of feedstock for lignocellulosic bioethanol production by reducing the carbon: nitrogen ratio

Bioethanol production from cereal straw is a sustainable alternative to meet the current energy demand, but its low nitrogen (N) content and high carbon to nitrogen (C/N) ratio are problematic during bioethanol processing. Intercropping cereals with legumes may increase the N content and reduce the C/N ratio in the harvested straw biomass. In order to investigate the combined production of food, feed, and suitable feedstock (low C/N ratio) for lignocellulosic bioethanol production, a field experiment on cereal-legume intercropping was carried out in southern Sweden. In the experiment, autumn-sown cereals (wheat, triticale, and rye) were grown as monocrops with two different N fertilization levels (60 and 120 kg N ha−1) or intercropped with autumn-sown or spring-sown (undersown) clover-grass, autumn-sown or spring-sown (undersown) alfalfa, or autumn-sown faba bean. Total grain dry matter yield, cereal grain protein content, straw dry matter yield, and straw biomass C/N ratio were estimated. The results showed that the intercrops produced more straw biomass and had a lower C/N ratio, but produced less grain, than cereal monocrops. Among the cereals, rye showed significantly higher grain and straw yields, but lower grain protein content, in all treatments. Among the intercrop treatments, cereal with spring-sown clover-grass produced higher grain and straw yields and had a significantly lower C/N ratio (38:1) than the other treatments. Thus, cereal with spring-sown (undersown) clover-grass is a promising cropping system for lignocellulosic bioethanol production.

Seasonal observations on the influence of groundwater discharge on meiofaunal assemblages in subterranean estuaries of southwest India.

The submarine groundwater discharge (SGD) into the sea is known to alter various biotic and abiotic properties of coastal waters. However, its influence on the lower trophic levels, namely, meiofauna, is poorly understood. This study highlights the impact of SGD on the density, distribution, and diversity of intertidal meiofaunal communities along the subterranean estuaries (STEs) of the southwest coast of India (Arabian Sea). As an outcome of extensive field sampling between 2019 and 2022, we found that groundwater discharge has a direct influence on the local meiofaunal communities. Significant decline in meiofaunal density and diversity in the SGD impacted sites with 2 to 4 times lower densities than the unimpacted sites were documented. Lower groundwater salinity, lesser organic carbon content, hypoxic sediment conditions, and lower mean grain size in STEs can be the major driving factors determining the lower meiofaunal densities. δ13C and δ15N isotopic signatures indicated that major sources of organic carbon in STEs of the Kerala coast are from C3 plants.

Combined effects of climate stressors and soil arsenic contamination on metabolic profiles and productivity of rice (Oryza sativa L.).

Rice productivity and quality are increasingly at risk in arsenic (As) affected areas, challenge that is expected to worsen under changing climatic conditions. Free-Air Concentration Enrichment experiments revealed that eCO2, eO3, and eTemp, whether acting individually or in combination with low and high As irrigation, significantly impact rice yield and grain quality. Elevated CO₂ significantly increased shoot biomass, with minimal impact on root biomass, except under low As irrigation conditions. In contrast, eTemp alone reduced both shoot and root biomass, though the effect was not significant; eO₃ alone had little to no effect. Combined climatic stressors showed slight positive effects on growth. Under low As irrigation, eCO2 and eO3 promoted root growth but reduced shoot growth, while eTemp significantly suppressed both. High As irrigation exacerbated yield reductions, with the most severe decline observed under eTemp (66%), followed by eCO2 (48%), eO3 (36%), and their combination (35%). Arsenic irrigation, whether low or high, reduced macro and micronutrient concentrations in rice grains, with calcium being sole exception, remaining stable or even increasing. Sugar metabolites decreased under eCO2, eO3, and eTemp, but increased with As irrigation. Interestingly, climatic variables generally reduced grain As levels, high As irrigation combined with eCO2 exposure resulted in elevated grain As. This poses a dual concern: increased cancer risk due to As but potential benefit for individuals with diabetes, as the higher amylose content contributes to lower glycemic index. However, rice grown under high As irrigation exhibited significant nutritional imbalances, being rich in maltose and amylose but deficient in organic acids, phytosterols, fatty acids, organosilicons, and carboxylic acids. These findings underscore the dual threat of climate change and As contamination to rice productivity and quality. Developing resilient rice varieties with low grain As content is essential to ensure sustainable agricultural production and nutritional security in As affected regions.

A novel major QTL underlying grain copper concentration in common wheat (Triticum aestivum L.)

Grain copper (Cu) concentrations represent a qualitative trait mainly controlled by genetic factors, which may differ between wheat varieties from the Sichuan Basin of China and other areas. However, the differences are poorly understood. Here, we investigated the grain Cu concentration in a remaining heterozygous line population derived from a multiparental recombinant inbred line. The grain Cu concentration varied from 4.25 to 13.44 mg/kg and 3.32 to 7.74 mg/kg over a two-year investigation, and the broad-sense heritability was 0.67. Bulked-segregation analysis revealed three quantitative trait loci on chromosomes 2A (QGr_Cu_Conc-2A), 2B (QGr_Cu_Conc-2B), and 4D (QGr_Cu_Conc-4D). QGr_Cu_Conc-2B is a novel locus, which was further narrowed between KASP-52.32 and KASP-56.57 with an interval of 52.32–56.57 Mb, explaining 17.10% of the phenotypic variation; its potential candidate gene was TraesCS2B03G0196500, encoding a chloroplast thylakoid lumen protein. KASP-52.32 successfully genotyped two common wheat populations, and the grain Cu concentration of CC genotype varieties was significantly higher than that of TT genotype varieties. Meanwhile, the concentrations of chlorophyll and the expression levels of three TaZIP8 and two TaZIP9 in flag leaves were higher in plants with high grain Cu concentration than in plants with low grain Cu concentration. These results provide guidance for understanding the genetic mechanisms underlying grain Cu concentration and may aid in wheat breeding.

Enhanced Mechanical Properties Via the Incorporation of Ti in Cu Alloys

The influence of Ti addition on the microstructure, mechanical properties and electrical conductivity of Cu-14Fe alloy is studied. Great emphasis has been laid on the second phase, texture and mechanical properties. No new phase other than α-Fe phase could be found in Cu-14Fe-0.1Ti alloy using XRD and SEM. With 0.1Ti addition, the distribution of α-Fe phase strip is slightly heterogeneous. Cube, s and brass texture components are largely strengthened in Cu matrix with Ti addition, while copper and goss texture components are rare in Cu matrix of both alloys. In α-Fe phases, α fiber and goss texture components are highly strengthened with Ti addition. It is found that enhanced mechanical properties are achieved in Cu-14Fe-0.1Ti alloy. In detail, with Ti addition, the yield strength and ultimate tension strength increase from 538 and 561 MPa to 580 and 583 MPa, respectively, while maintaining a high value of elongation to failure (6.5%). A lower equivalent grain size and a higher KAM value mainly contributes to the higher yield strengthening effect in Cu-14Fe-0.1Ti alloy. The lower equivalent grain size is derived from the small size distribution range and the small size of Cu matrix in Cu-14Fe-0.1Ti alloy. The dissolution of Ti and formation of nano second phases also improve mechanical properties. However, texture hardly plays a role in the strengthening effect. 0.1Ti addition hardly reduces the electrical conductivity of Cu-14Fe alloy, maintaining a value of 33.43% IACS. The results in this work could provide guidance in texture evolution and property evaluation in Cu-Fe alloys.

COMPARATIVE ANALYSIS OF EARLY ESTABLISHMENT PERFORMANCES OF PERENNIAL WHEAT GENOTYPES

Perennial wheat (Triticum aestivum L. × Thinopyrum spp.) presents a promising alternative to conventional annual wheat for sustainable agriculture, offering advantages such as enhanced soil health and reduced environmental impact. This study evaluated the early establishment performances of 20 perennial wheat genotypes sourced from diverse donors alongside two commercial wheat varieties under rain-fed conditions in Bornova, Izmir, Türkiye. Two separate field trials were conducted over two growing seasons (2018/19 and 2020/21), assessed key yield components, including plant height (PH), spike number (SN), spike length (SL), thousand grain weight (TGW), and overall grain yield (GY). Results showed that perennial wheat genotypes exhibited higher plant height and spike length compared to common wheat but had lower grain numbers per spike and TGW. On average, perennial wheat achieved 40% of the grain yield of commercial wheat varieties, with significant variability among genotypes. Notably, the genotype Pw18 demonstrated satisfactory grain yield performance, achieving 5.21 tons ha-1, close to common wheat yields evaluated in the study. These findings highlight the potential of specific perennial wheat genotypes for further development in sustainable cropping systems. However, further investigation is needed to assess the quality characteristics of these genotypes, which will be crucial for their potential use.

Evaluation of Neem (<i>Azadirachta indica</i>) Seed Extract Against Fall Armyworm, <i>Spodoptera frugiperda</i> (Lepidoptera: Noctuidae) in Maize Fields

The increasing trends of damage to staple crops as well as the economic losses due to the fall armyworm (<i>Spodoptera frugiperda), </i>the notorious invasive insect pests prompted to devise effective pest management in colonized regions to ensure sustainable crop health. Deploying bioactive plant material is among the novel eco-friendly approaches to managing insect pests in maize agro-ecosystems. Therefore, the present study was conducted to determine the efficacy of neem seed extracts against S.<i>frugiperda</i> under field conditions at Babile, eastern Ethiopia. A total of 8 treatments, including 6 different neem seed extracts, Megathrin 0.5 L/ha, and un-sprayed (untreated) plots were set up in randomized complete block design with three replications to evaluate their efficacy against S.<i>frugiperda</i> in maize fields. Results showed that S.<i>frugiperda</i> infestation was significantly influenced by the treatments both at 32 days after sowing (DAS) and 39 DAS, however, a non-significant difference was observed at 25 DAS. Moreover, except for the number of rows per ear, all crop parameters were significantly influenced by the treatments. Notably, the treatments reduced S.<i>frugiperda</i> incidence and severity and achieved higher crop performance over untreated maize plants. Between 3.9% to 25.7% and 0.0% to 19.6%, reductions were recorded for S.<i>frugiperda</i> incidence at 32 DAS and 39 DAS, respectively, compared to untreated plants. Similarly, 22.7% to 47.7% and 33.8% to 46.2% reductions were observed for S.<i>frugiperda</i> severity at 32 DAS and 39 DAS, respectively. The highest grain yield (36.4 Qt/ha) was obtained from neem @ 75 gm/Lx3, which was followed by Megathrin 0.5 L/ha (31.9 Qt/ha), neem @ 62.5gm/Lx3 (31.6Qt/ha) and neem @ 75gm/Lx2 (31.2 Qt/ha), while significantly the lowest grain yield (21.8 Qt/ha) was obtained from untreated maize plants. Results indicated that the field application of neem seed extracts resulted in a significant reduction of S.<i>frugiperda</i> infestation and provided considerable yield advantages as compared to untreated plants. Hence, the promising efficacy of the locally available botanical insecticide could provide an opportunity to deploy it against S.<i>frugiperda</i> as an eco-friendly approach, although further study is needed to validate the findings of the present study across seasons and agroecologies.

Effect of Mini-Doses of Compost on Maize Development and Yield at the Refugee Site in Maro in the Greater Sido Region of Chad

Chemical fertilizers are polluting for the environment, they are expensive and sometimes inaccessible to producers. With the arrival of refugees from the Central African Republic in Maro in southern Chad, arable land is reduced and soils have become impoverished. An alternative use of locally available organic fertilizers is possible to improve agricultural productivity. The Refugees do not have enough livestock to produce the 5 to 10 t/ha of manure that is recommended for maize cultivation. The objective of the study is to determine the minimum dose of compost that can increase corn productivity. The plant material is composed of 2009 TZEE-W-STR corn variety, with a 90-day cycle. The trial is conducted according to an experimental Fisher block design with 5 treatments (T1, T2, T3, T4 and T0) with 4 replicates. The mini-compost doses (20 g, 40 g, 60 g, 80 g and NPK dose equivalent to 100 kg/ha) correspond respectively to the T1, T2, T3, T4 and T0 control treatments. The results revealed that T0 (16.80 cm ± 0.106) had the longest cob, T1 (14.52 cm ± 0.29) had the lowest cob length. The best biomasses were obtained on T0 (5.14 kgm-2 ± 0.098) and T4 (5.13 kgm-2 ± 0.12), while T2 and T1 recorded the low biomasses. T4 (3.02 tha-1 ± 0.035) and T3 (3.02 tha-1 ± 0.087) obtained better yields, the low yield was observed on T1 (2.33 tha-1 ± 0.055). The T0 (0.253 kg ± 0.005) recorded the best grain weight. T3 and T1 obtained the low grain weights. T2 gave the same results as T4 and T3, which are the high rates of compost and the T0 control. The T2 treatment corresponding to 40 g compost/pocket would be recommended to refugees to increase maize production.

Improvement of maize drought tolerance by foliar application of zinc selenide quantum dots.

Maize (Zea mays L.) is an important cereal crop grown in arid and semiarid regions of the world. During the reproductive phase, it is more frequently exposed to drought stress, resulting in lower grain yield due to oxidative damage. Selenium and zinc oxide nanoparticles possess inherent antioxidant properties that can alleviate drought-induced oxidative stress by the catalytic scavenging of reactive oxygen species, thereby protecting maize photosynthesis and grain yield. However, the effect of zinc selenide quantum dots (ZnSe QDs) under drought stress was not been quantified. Hence, the aim of this study was to quantify the (i) toxicity potential of ZnSe QDs and (ii) drought mitigation potential of ZnSe QDs by assessing the transpiration rate, photosynthetic rate, oxidant production, antioxidant enzyme activity and seed yield of maize under limited soil moisture levels. Toxicity experiments were carried out with 0 mg L-1 to 500 mg L-1 of ZnSe QDs on earthworms and azolla. The results showed that up to 20 mg L-1, the growth rates of earthworms and azolla were not affected. The dry-down experiment was conducted with three treatments: foliar spray of (i) water, (ii) ZnSe QDs (20 mg L-1), and (iii) combined zinc sulfate (10 mg L-1) and sodium selenate (10 mg L-1). ZnSe or Se applications under drying soil reduced the transpiration rate compared to water spray by partially closing the stomata. ZnSe application at 20 mg L-1 at the tasselling stage significantly increased the photosynthetic rate (25%) by increasing catalase (98%) and peroxidase (85%) enzyme activity and decreased the hydrogen peroxide (23%) content compared to water spray, indicating that premature leaf senescence was delayed under rainfed conditions. ZnSe spray increased seed yield (26%) over water spray by increasing the number of seeds cob-1 (42%). The study concluded that foliar application of ZnSe (20 mg L-1) could decrease drought-induced effects in maize.

Adverse effects of heat shock in rice (Oryza sativa L.) and approaches to mitigate it for sustainable rice production under the changing climate: A comprehensive review.

Heat shock, a transient exposure to high temperatures, is a substantial hazard to rice (Oryza sativa L.) production and sustainability. The objective of this review paper is to summarize the impact of heat shock on rice and explore approaches to mitigate its adverse effects to achieve sustainable production. Rice is a staple food for billions of people globally and is extremely sensitive to heat shock. Higher temperatures disturb various physiological and biochemical processes, resulting in decreased growth, development, and ultimately lower grain yield. Heat shock negatively affects important agronomic traits, such as panicle differentiation, pollen viability, fertilization, grain filling, and, ultimately, grain quality. To manage heat shock and sustain rice production, several strategies have been explored, such as modifications to sowing schedules, the substitution of heat-tolerant cultivars for sensitive genotypes, and the use of growth regulators. To improve rice under heat shock, various approaches could be taken: (1) cultivating cultivars that flower early in the morning by adjusting sowing/planting times, modified irrigation, and fertilization; (2) inducing acclimation via growth regulators and organic stimulants and chemicals; (3) breeding genetically resistant cultivars through the integration of appropriate genes; and (4) genetic modification techniques for heat-shock tolerance. Overall, effectively managing heat-shock stress in rice requires a comprehensive strategy that includes developing and using heat shock-tolerant cultivars, adopting suitable cultural practices, utilizing external substances, and applying biotechnological tools. Implementing these strategies collectively will help achieve sustainable rice production in the face of increasing heat-shock conditions.

Investigating the Influence of Fertilizer Application Rates on Soybean Yield Across Diverse Locations

This study investigated the impact of varying fertilizer application rates on soybean yield and agronomic characteristics in three distinct locations within Lao PDR (Laos People’s Democratic Republic-Lao PDR): the Rice and Cash Crop Research Center (RCCRC), the Faculty of Agriculture Nabong Campus (National University of Laos, NUoL), and the Faculty of Agriculture and Environment Nongpheu Campus (Savannakhet University, SKU). The field experiment was conducted during the 2022 growing season (August to December) using a randomized complete block design (RCBD) with three replications. Five fertilizer treatments were applied to a total of 15 experimental units, encompassing varying combinations and rates of organic and inorganic fertilizers. Agronomic traits, including plant height, number of branches, pods per plant, individual plant weight, 100-seed weight, and grain yield, were measured at maturity. Data analysis was performed using Statistix 10.0 software with a significance level of 95% (P < 0.05). Significant differences (P < 0.01) were observed among the fertilizer treatments for the number of branches, pods per plant, individual plant weight, and ultimately, grain yield. However, plant height and 100-seed weight were not significantly affected by the different fertilizer applications (P > 0.05). The highest grain yields were achieved with the application of organic fertilizer at a rate of 2,000 kg/ha (2.48 t/ha) and a combination of organic fertilizer at 1,000 kg/ha with inorganic fertilizer at 100 kg/ha (2.57 t/ha). Conversely, the control treatment, which received no fertilizer, resulted in the lowest grain yield. These results highlight the importance of fertilizer management strategies in optimizing soybean production in Lao PDR. Further research is needed to assess the long-term effects of these fertilizer regimes on soil health and environmental sustainability.

Improvement of ionic conductivity and relative density of Li6.4La3Zr1.4Ta0.6O12 electrolytes by optimization of composition and sintering aid

Introduction All-solid-state lithium metal batteries (ASSLMBs) are expected to have high energy density. Among various solid electrolytes, oxide-based solid electrolytes have attracted attention in recent years due to their higher air stability compared to sulfide-based solid electrolytes. However, oxide-based solid electrolytes exhibit lower ionic conductivity compared to sulfide-based or liquid electrolytes, leading to inferior high-rate cycle performance. Additionally, when the relative density of solid electrolytes is low, the formation of lithium dendrites through structural defects in the solid electrolyte causes short circuits. Therefore, improving the ionic conductivity and relative density of solid electrolytes is essential for enhancing the performance of oxide-based all-solid-state batteries.In our previous research, we increased the relative density of lithium lanthanum zirconium tantalate (Li6.4La3Zr1.4Ta0.6O12, LLZT) solid electrolytes to 99.3% by co-doping LLZT with alumina (Al2O3)1) and lithium tungstate (Li2WO4)2). The increase in relative density resulted in improved short-circuit resistance performance. However, the drawback of adding these sintering aids is the reduction in ionic conductivity of LLZT due to the substitution effect on the solid electrolyte. According to the paper by N. Hayashi et al., reducing the amount of lanthanum in LLZ-CaBi solid electrolytes can improve ionic conductivity and relative density3). In this study, we attempted to enhance the ionic conductivity and relative density of LLZT by reducing the amount of lanthanum in the raw materials. Experimental The Li6.4La3-xZr1.4Ta0.6O12-1.5x (x=0, 0.03, 0.06, 0.09, 0.12,0.15) powders were synthesized via solid-state synthesis method. Lithium carbonate, lanthanum oxide, zirconium oxide, and tantalum oxide were used as raw materials. The raw materials were mixed and then heated at 900°C for 12 hours to synthesize LLZT powder. During the weighing process, lithium carbonate was added in excess by 20% of the target composition to account for lithium carbonate volatilization. LLZT powder and sintering aids were mixed using a planetary ball mill, and then the powder was pressed into pellets at 98 MPa. The pellets were sintered at 1150°C for 5 hours. Next, dry polishing was conducted to adjust the thickness of LLZT to 0.8 mm, and Au blocking electrodes were sputtered on both sides of LLZT to perform AC impedance. AC impedance measurements were performed at 30°C with an applied voltage of 10 mV over a frequency range from 1 MHz to 1 Hz. Li metal electrodes (diameter 6 mm) were attached to both sides of the Au thin film on LLZT to fabricate Li-Au|LLZT|Au-Li symmetric cells to conduct short-circuit test. In the short-circuit tests, charge-discharge cycles were repeated every 30 minutes, with the current density increasing by 0.1 mA cm- 2 every 20 cycles at 60°C. Results and Discussion Table 1 shows the relative density, resistance, and ionic conductivity of as-prepared LLZT without sintering aid. Decreasing the amount of lanthanum led to improvements in both relative density and ionic conductivity. The highest relative density achieved at x=0.06 and 0.09. Additionally, at x=0.06, bulk ionic conductivity was measured at 1.12 mS, and total ionic conductivity at 0.976 mS. The low grain boundary resistance at x=0.06 is believed to be due to the reduction in voids resulting from the improved relative density. For samples with x=0.09 and above, a gradual decrease in both relative density and ionic conductivity was observed.Figure 1 depicts the XRD patterns of LLZT from 20° to 22°. Pronounced peaks of Li2ZrO3 were observed in samples with x=0.12 and x=0.15. This is believed to result from the reaction of excess lithium, zirconium, and oxygen due to the reduction in lanthanum. Previous our studies have shown that Li2ZrO3 suppresses abnormal grain growth in LLZT particles and improves relative density. Therefore, the enhancement in relative density is likely attributed to Li2ZrO3.Figure 2 shows cross-sectional SEM images of LLZT. Abnormal grain growth and voids were observed in samples with x=0 and 0.03, while samples with x=0.06 and above exhibited no abnormal grain growth, indicating that dense solid electrolytes were successfully fabricated. This is considered evidence of abnormal grain growth suppression due to the formation of Li2ZrO3.In addition to the above, the reasons for the enhancement in bulk ionic conductivity, the characteristics of LLZT (x=0.06) added sintering aids, and the results of short-circuit tests will be discussed in more detail on the poster.

Impact of Structural Motifs on the Ionic Diffusion Mechanism in Sulfide-Based Solid Electrolytes

Sulfide-based solid electrolytes, such as lithium thiophosphate (LPS) with compositions (Li2S) 𝑥 (P2S5)1− 𝑥 and lithium Germanium thiophosphate (LGPS [Li10GeP2S12]), exhibit high ionic conductivity, rendering them promising for solid-state batteries (SSBs). However, their practical application is limited due to their low electrochemical stability and grain boundary resistance. To overcome these challenges, we explore the formation of glass-ceramic phases within the lithium thiophosphate family. Our investigation centers on the mechanism of ionic diffusion in LPS (with three compositions) and LGPS (with two distinct crystal systems) in their crystalline and glass-ceramic phases. Employing ab initio molecular dynamics (AIMD) simulations, we identify and classify the structural motifs responsible for the diffusion of Li-ions. Notably, Li2P2S6 (x = 0.5) exhibits a high activation energy for diffusion, while Li7P3S11 (x = 0.7) demonstrates elevated Li-ion diffusivity in its crystalline phase. Interestingly, the transport properties do not vary with compositions suggesting that the ion mobility is independent of the underlying structural motifs present in the glass-ceramic phases of LPS. Our structural similarity analysis also reveals a similar Li environment in the glass-ceramic phase, regardless of LPS compositions. Furthermore, increasing the crystallinity in glass-ceramic Li7P3S11 increases the amount of P2S7 4- motifs, and its percolation changes the Li environment creating a conduction pathway for Li-ion diffusion. In the case of LGPS, disorder within the glass-ceramic phase significantly diminishes ion transport similar to the behavior observed in LPS. However, the tetragonal and triclinic crystal structures reveal distinct ionic diffusion mechanisms in terms of conduction pathways. Our study emphasizes the importance of structural motifs to devise the optimal strategy for designing solid electrolyte materials. Figure 1

Eco-physiological response of grain amaranth to regulated deficit and conventional deficit irrigation applied with surface and subsurface drip irrigation systems

Abstract Understanding the water use of drought-tolerant crops of the drought-prone Mediterranean regions is important for sustainable agriculture. The aim of this study was to evaluate the yield and yield responses of amaranth (Amaranthus hybridus L.) to different irrigation strategies conducted in 2019 and 2020 under Mediterranean climatic conditions using surface drip (SD) and subsurface drip (SSD) systems. Strategies investigated were: regulated deficit irrigation (RDI), conventional deficit irrigation (DI25, DI50, DI75), full irrigation (FI) and rainfed treatment. The highest grain yield was observed in FI treatments; RDI treatments produced 5% lower grain yield than the FI treatments, although the RDI treatments resulted in water savings of 23 and 21% for SD and SSD systems, respectively. DI treatments resulted in lower leaf water potential (LWP) and higher crop water-stress index (CWSI) compared to FI in both systems values. The results showed that optimum irrigation conditions to obtain the highest amaranth grain yields were associated with an LWP of −1.0 MPa and an average CWSI of about 0.25. The FI treatments under SSD systems had the highest grain production, followed by FI under SD and RDI under both the drip systems. Under SD and SSD systems, RDI saved 23 and 21% water, respectively, and produced a yield statistically comparable to that of FI. The SSD methods generated higher net income than SD. From these results it can be concluded that both RDI and DI75 could be a good alternative to FI under the conditions of water scarcity in the Mediterranean region.

Yield determination of temperate maize hybrids with different end‐uses: An ecophysiological analysis

AbstractMaize (Zea mays L.) production in Argentina changed markedly during the last decade due to the widespread adoption of late sowing dates, expanding its productive area, and diversifying crop end‐uses. This study was conducted to assess how the sowing date and nitrogen (N) availability affect grain yield, its physiological determinants (biomass and its partitioning), and numeric components (kernel number and kernel weight) of maize hybrids marketed for different end‐uses. Field experiments were conducted in two growing seasons (2019–2020 and 2020–2021) and two sowing dates within each season (early and late) at a site in the main maize‐producing region of Argentina. Within each season × sowing date combination, eight commercial maize hybrids (commercialized as grain, dual‐purpose, or silage) were tested under two N levels (N0: no N applied; N250: fertilized with 250 kg N ha−1). The greatest grain yield, biomass, kernel number, and harvest index corresponded to the grain hybrids. Dual‐purpose hybrids showed an intermediate grain yield, the highest kernel weight, and a more “silage” than “graniferous” behavior. Silage hybrids had improved light interception up to silking + 15 days (R2) but exhibited the lowest grain yield. Differences in end‐use steered crop breeding efforts toward different physiological strategies. The improved understanding of the physiological mechanisms underlying the productivity among maize hybrids with varying end‐uses will assist in the selection and management of suitable cultivars to be grown under different systems and environmental variations associated with an extended sowing date period.

Quantitative trait locus mapping and OsFLOq12 identification for rice grain hardness: towards improved rice flour for wheat substitution.

Recent shifts in consumer dietary preferences have led to a significant decline in rice consumption in Korea, resulting in surplus rice production. To address this issue, rice flour has been proposed as a substitute for wheat flour. However, the physical, chemical and structural differences between rice and wheat, particularly in grain hardness, pose challenges in using rice flour as an alternative. Understanding the genetic factors that influence rice grain hardness is crucial for improving the milling process and producing high-quality rice flour suitable for wheat flour substitution. In this study, various grain traits, including length, width, thickness, length-to-width ratio and hardness, were measured in a population of brown and milled rice. Quantitative trait locus (QTL) analysis revealed a significant association between grain hardness and thickness, with QTLs for grain hardness mapped on chromosomes 1 and 12 for brown and milled rice, respectively. A total of 20 candidate genes related to grain hardness were identified through QTL analysis. Among them, OsFLOq12 (LOC_Os12g43550) was identified as a key gene influencing grain hardness, which encodes a Ras small GTPase. Phenotypic analysis showed differences in endosperm appearance and particle size between lines with low and high grain hardness. The genetic analysis of OsFLOq12 revealed a single nucleotide polymorphism associated with grain hardness. This study provides valuable insights into the genetic background of grain hardness, offering a foundation for breeding rice varieties optimized for flour production as a viable substitute for wheat flour. © 2024 Society of Chemical Industry.

Analysis of Ash Content of Red Salak Bean Coffee (Salacca edulis) Based on Duration of Roasting Length

Maluku province, Seram district in the west, found a strawberry. Fruit is a tropical and horticultural commodity with a fairly high availability. Protein, ash, fat, and water are the closest analysis, carbohydrates as well as fiber. Coffee has a distinctive aroma from the coffee plant and contains high levels of caffeine compounds. The presence of this compound under certain conditions will make coffee unsuitable for consumption, so several types of coffee have emerged which are made from grains from certain plants. One of the potential seeds is snake fruit seeds. Coffee seeds are a new beverage product, the researchers used the old coagulation factor, because long coagulation will affect the formation of aroma and the color of the coffee powder produced will determine the characteristic taste of coffee, which is caused by long variations in coagulation times that vary. The results obtained are presented in the form of tables and analyzed descriptively. The resulting ash composition of red coffee seeds (Salacca edulis) based on different grain durations was 3.46% for 30 minutes, 4.24% for 60 minutes, and 4.70% for 90 minutes. The highest ash content found in red coffee was 4.70% and the lowest grain is 2.46%. Keywords: Red Salak, ash content, roasting duration

Integrating Nitrogen, Water, and Other Management Practices to Improve Grain and Ratoon Forage Yields in Perennial Rice.

Perennial rice has recently garnered global attention due to its potential to save on seeds and labor costs and its high production efficiency. The "mid-season rice-ratoon forage" mode is a new planting system that has emerged in recent years. However, detailed information is still lacking on the regenerative characteristics, grain and ratoon forage yields, and forage nutrient content of perennial rice under different planting densities, nitrogen (N) rates, stubble heights, and water management practices. Four experiments with perennial rice were conducted in Sichuan Province, Southwest China, from 2017 to 2022. The results show that the rice grain and ratoon forage yields were significantly affected by year, planting density, and N. The grain yield was 28.18% and 60.81% lower in 2018F and 2019F, respectively, than in 2017F; similarly, the ratoon forage yield was 29.01% and 52.74% lower in 2018S and 2019S, respectively, than in 2017S. The low grain yield was mainly associated with lower numbers of spikelets per panicle and panicles per m2, which resulted from a lower regrowth rate, and the low ratoon forage yield was mainly attributed to the lower regrowth rate. The rice grain and ratoon forage yields increased with an increase in the N rate and planting density. The ratoon forage was found to be rich in crude protein, crude fat, crude fiber, calcium, nitrogen, phosphorus, potassium, and other nutrients. Moreover, the content of these nutrients increased significantly with an increase in the N rate. The regrowth rate and maximum tillers showed trends of first increasing and then decreasing with an increase in the stubble height under dry and wet alternation irrigation during the winter season. When the relative soil moisture decreased to below 80% during the winter season, the regrowth rate and seedling development index could reach more than 99% and 84%, respectively. Our results suggest that integrating N, water, and other management practices (including the combination of a 150 kg ha-1 N rate, 18.0 hills per m2, 10-20 cm rice stubble height, and alternating dry and wet irrigation during the winter season) is a feasible approach for achieving high grain and ratoon forage yields in perennial rice systems.