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1. Integrated management strategies increased silage maize yield and quality with lower nitrogen losses in cold regions

Author

Changqing Li, Bingxin Tong, Mengyang Jia, Huasen Xu, Jiqing Wang, and Zhimei Sun

Subjects
silage maize, variety and density, nitrogen fertilizer management, yield and quality, nitrogen balance integrated management strategy, Plant culture, SB1-1110
Abstract

IntroductionHigh-yield and high-quality production of silage maize in cold regions is crucial for ensuring the sustainable development of livestock industry.MethodsThis study first conducted an experiment to select the optimized silage maize varieties and densities using a split-plot design. The tested maize varieties were Xuntian 3171, Xuntian 16, Xunqing 858, and Fengtian 12, with each variety planted at densities of 67,500, 79,500, and 90,000 plants ha-1. Following the variety and density selection, another experiment on optimizing nitrogen management for silage maize was carried out using a completely randomized design: no nitrogen fertilizer (T1), applying urea-N 320 kg ha-1 (T2), applying urea-N 240 kg ha-1 (T3), applying polymer-coated urea-N 240 kg N ha-1 (T4), and ratios of polymer-coated urea-N to urea-N at 9:1 (T5), 8:2 (T6), 7:3 (T7), and 6:4 (T8). T5-T8 all applied 240 kg N ha-1. The yield and quality of silage maize, nitrogen use efficiency and balance, and economic benefits were evaluated.ResultsResults showed that Xunqing 858 had significantly higher plant height (8.7%-22.6% taller than the other three varieties) and leaf area (30.9% larger than Xuntian 3171), resulting in yield 11.5%-51.6% higher than the other three varieties. All varieties achieved maximum yields at a planting density of 79,500 plants ha-1. Integrated management strategy 7 (T7: Xunqing 858, 79,500 plants ha-1, polymer-coated urea-N to urea-N ratio of 7:3) achieved the highest yield of 73.1 t ha-1, a 6.1%-58.1% increase over other treatments. This strategy also produced the highest crude protein (11.1%) and starch (19.1%) contents, and the lowest neutral detergent fiber content (50.6%), with economic benefits improved by 10.3%-97.8% compared to other strategies. Additionally, T7 improved nitrogen use efficiency by 15.4%-94.5%, reduced soil nitrate leaching by 4.4%-36.5%, and decreased nitrogen surplus by 7.0%-46.6%.Conclusion and discussionComprehensive analysis revealed that the integrated management strategy 7 significantly improved silage maize yield and quality in cold regions while enhancing nitrogen use efficiency and reducing the risk of nitrate leaching, aligning with green agriculture development requirements. These findings will provide vital theoretical insights and practical guidance for high-yield and high-quality silage maize production in cold regions worldwide.

Published
2024
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2. Stacking order modulated anomalous valley Hall effect in antiferromagnetic MXene

Author

Tong Zhao, Shucheng Xing, Jian Zhou, Naihua Miao, and Zhimei Sun

Subjects
Stacking order, Antiferromagnetism, AVH effect, Electrical control, Materials of engineering and construction. Mechanics of materials, TA401-492
Abstract

The valley index is a promising degree of freedom for information processing in electronic devices. However, the researches on valley polarization are mainly focused on ferromagnetic order, which breaks the time reversal symmetry simultaneously. Here, a novel paradigm for achieving stacking order modulated anomalous valley Hall (AVH) effect is proposed in antiferromagnetic monolayers. The paradigm involves the introduction and reversal of nonuniform potentials by modulating the position of substrate, to break the combined symmetry of spatial inversion and time reversal (PT symmetry) and achieve stacking-dependent valley spin splitting. Based on first-principles calculations, we discover spontaneous valley polarization in antiferromagnetic Cr2CH2 MXene and stacking-dependent valley spin splitting in Cr2CH2/Sc2CO2 heterostructure. Furthermore, switching the ferroelectric polarization of monolayer Sc2CO2 results in a semiconductor-metal transition in Cr2CH2/Sc2CO2, accompanied by the disappearance of valley physics. Our findings provide an alternative way to develop controllable valleytronics devices based on antiferromagnetic monolayers.

Published
2024
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3. An interpretable machine learning strategy for pursuing high piezoelectric coefficients in (K0.5Na0.5)NbO3-based ceramics

Author

Bowen Ma, Xiao Wu, Chunlin Zhao, Cong Lin, Min Gao, Baisheng Sa, and Zhimei Sun

Subjects
Materials of engineering and construction. Mechanics of materials, TA401-492, Computer software, QA76.75-76.765
Abstract

Abstract Perovskite-type lead-free piezoelectric ceramics allow access to illustrious piezoelectric coefficients (d 33) through intricate composition design and experimental modulation. Developing a swift and accurate technology for identifying (K, Na)NbO3 (KNN)-based ceramic compositions with high d 33 in exceedingly large “compositional” space will establish an innovative research paradigm surpassing the traditional empirical trial-and-error method. Herein, we demonstrate an interpretable machine learning (ML) framework for quick evaluation of KNN-based ceramics with high d 33 based on data from published literature. Specifically, a thorough feature construction was carried out from the global and local dimensions to establish tree regression models with d 33 as the target property. Subsequently, the feature-property mapping rules of KNN-based piezoelectric ceramics are further optimized through feature screening. To intuitively understand the correlation mechanisms between ML regression targets and features, the sure independence screening and sparsifying operator (SISSO) method was employed to extract the essential descriptors to explain d 33. A straightforward descriptor, $${\text{e}}^{({{NM}}_{\text{B}}-{{MV}}_{\text{B}})}\cdot {ST}/{(I{D}_{\text{A}})}^{2}$$ e ( NM B − MV B ) ⋅ ST / ( I D A ) 2 , consisting of only four easily accessible parameters, can accelerate the evaluation of a series of novel KNN-based ceramics with high d 33 while exhibiting strong theoretical interpretability. This work not only provides a tool for the rapid discovery of high piezoelectric performance in KNN-based ceramics but also offers a data-driven route for the design of property descriptors in perovskites.

Published
2023
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4. Machine learning interatomic potential: Bridge the gap between small-scale models and realistic device-scale simulations

Author

Guanjie Wang, Changrui Wang, Xuanguang Zhang, Zefeng Li, Jian Zhou, and Zhimei Sun

Subjects
Chemistry, Computer science, Materials science, Physics, Science
Abstract

Summary: Machine learning interatomic potential (MLIP) overcomes the challenges of high computational costs in density-functional theory and the relatively low accuracy in classical large-scale molecular dynamics, facilitating more efficient and precise simulations in materials research and design. In this review, the current state of the four essential stages of MLIP is discussed, including data generation methods, material structure descriptors, six unique machine learning algorithms, and available software. Furthermore, the applications of MLIP in various fields are investigated, notably in phase-change memory materials, structure searching, material properties predicting, and the pre-trained universal models. Eventually, the future perspectives, consisting of standard datasets, transferability, generalization, and trade-off between accuracy and complexity in MLIPs, are reported.

Published
2024
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5. Ordering phenomena in ternary transition‐metal dichalcogenides: Critical role of lattice symmetry and vdW interaction

Author

Tianxu Zhang, Linggang Zhu, Hanyu Liu, Jian Zhou, and Zhimei Sun

Subjects
electronegativity, first‐principles calculation, Monte Carlo simulation, short/long‐range order, transition‐metal dichalcogenide, vdW interaction, Materials of engineering and construction. Mechanics of materials, TA401-492, Computer engineering. Computer hardware, TK7885-7895, Technology (General), T1-995
Abstract

Abstract Concentrated solid solution materials with huge compositional design space and normally unexpected property attract extensive interests of researchers. In these emerging materials, local composition fluctuation such as short‐range order (SRO), has been observed and found to have nontrivial effects on material properties, and thus can be utilized as an additional degree of freedom for material optimization. To exploit SRO, its interplay with factors beyond element‐level property, including lattice symmetry and bonding environment, should be clarified. In this work by using layered transition‐metal dichalcogenide Mo(X0.5X′0.5)2 (X/X′ = O, S, Se, or Te) with mixed element in the non‐metal sublattice as the platform, the ordering phenomena are systematically studied using multiscale simulations. As expected, electronegativity difference between X and X′ strongly regulates SRO. Additionally, SRO and long‐range order (LRO) are observed in the 2H and T/T′ phase of MoXX′, respectively, indicating a strong influence of lattice symmetry on SRO. More importantly, as vdW interaction is introduced, the SRO structure in 2H‐MoXX′ bilayer can be re‐configured, while the LRO in T/T′‐MoXX′ remains unchanged. Electronic insights for SRO and the resultant property variation are obtained. This work presents a thorough understanding of SRO in bonding complex systems, benefiting the SRO‐guided material designs.

Published
2023
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6. Comparative effectiveness of ustekinumab vs. vedolizumab for anti-TNF-naïve or anti-TNF-exposed Crohn's disease: a multicenter cohort studyResearch in context

Author

Hongsheng Yang, Zhaopeng Huang, Miao Li, Haiyan Zhang, Lingyu Fu, Xiaoling Wang, Qiaoqiao Yang, Yun He, Wenhong Wu, Taofeng Jiang, Zhimei Sun, Tao Zhang, Dongping Lai, Xixin Wu, Lishuo Shi, Qin Guo, Yanhui Wu, Jian Tang, Kang Chao, and Xiang Gao

Subjects
Crohn’s disease, ustekinumab, vedolizumab, Medicine (General), R5-920
Abstract

Summary: Background: Ustekinumab and vedolizumab are both effective for treating Crohn’s disease (CD). However, no head-to-head trials have been conducted thus far. We aimed to compare the effectiveness of ustekinumab and vedolizumab in CD patients either naïve or exposed to tumor necrosis factor-alpha inhibitors (TNFi). Methods: Patients treated with vedolizumab or ustekinumab for luminal CD were included from six centers in China from May 2020 to July 2023. Steroid-free remission, clinical remission, objective response, and remission at Weeks 26 and 52 were evaluated in a retrospective multicenter propensity score–weighted cohort. Findings: A total of 536 patients were included (386 ustekinumab, and 150 vedolizumab). After adjustment, ustekinumab showed higher rates of clinical remission (56.4% vs. 47.8%, P = 0.005), steroid-free remission (55.4% vs. 46.1%, P = 0.003), and objective response (67.8% vs. 42.7%, P

Published
2023
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7. Interfacial engineering of ferromagnetism in wafer-scale van der Waals Fe4GeTe2 far above room temperature

Author

Hangtian Wang, Haichang Lu, Zongxia Guo, Ang Li, Peichen Wu, Jing Li, Weiran Xie, Zhimei Sun, Peng Li, Héloïse Damas, Anna Maria Friedel, Sylvie Migot, Jaafar Ghanbaja, Luc Moreau, Yannick Fagot-Revurat, Sébastien Petit-Watelot, Thomas Hauet, John Robertson, Stéphane Mangin, Weisheng Zhao, and Tianxiao Nie

Subjects
Science
Abstract

Abstract Despite recent advances in exfoliated vdW ferromagnets, the widespread application of 2D magnetism requires a Curie temperature (Tc) above room temperature as well as a stable and controllable magnetic anisotropy. Here we demonstrate a large-scale iron-based vdW material Fe4GeTe2 with the Tc reaching ~530 K. We confirmed the high-temperature ferromagnetism by multiple characterizations. Theoretical calculations suggested that the interface-induced right shift of the localized states for unpaired Fe d electrons is the reason for the enhanced Tc, which was confirmed by ultraviolet photoelectron spectroscopy. Moreover, by precisely tailoring Fe concentration we achieved arbitrary control of magnetic anisotropy between out-of-plane and in-plane without inducing any phase disorders. Our finding sheds light on the high potential of Fe4GeTe2 in spintronics, which may open opportunities for room-temperature application of all-vdW spintronic devices.

Published
2023
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8. Self-Assembly TiO2-Ti3C2Tx Ball–Plate Structure for Highly Efficient Electromagnetic Interference Shielding

Author

Zhen Zhang, Xingyang Ning, Bin Liu, Jian Zhou, and Zhimei Sun

Subjects
electromagnetic interference shielding, MXene, TiO2-Ti3C2Tx, ball–plate structure, Technology, Electrical engineering. Electronics. Nuclear engineering, TK1-9971, Engineering (General). Civil engineering (General), TA1-2040, Microscopy, QH201-278.5, Descriptive and experimental mechanics, QC120-168.85
Abstract

MXene is a promising candidate for the next generation of lightweight electromagnetic interference (EMI) materials owing to its low density, excellent conductivity, hydrophilic properties, and adjustable component structure. However, MXene lacks interlayer support and tends to agglomerate, leading to a shorter service life and limiting its development in thin-layer electromagnetic shielding material. In this study, we designed self-assembled TiO2-Ti3C2Tx materials with a ball–plate structure to mitigate agglomeration and obtain a thin-layer and multiple absorption porous materials for high-efficiency EMI shielding. The TiO2-Ti3C2Tx composite with a thickness of 50 μm achieved a shielding efficiency of 72 dB. It was demonstrated that the ball–plate structure generates additional interlayer cavities and internal interface, increasing the propagation path for an electromagnetic wave, which, in turn, raises the capacity of materials to absorb and dissipate the wave. These effects improve the overall EMI shielding performance of MXene and pave the way for the development of the next-generation EMI shielding system.

Published
2023
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9. Quantitative Evaluation of the Crop Yield, Soil-Available Phosphorus, and Total Phosphorus Leaching Caused by Phosphorus Fertilization: A Meta-Analysis

Author

Yuwen Jin, Naiyu Zhang, Yanhua Chen, Qiong Wang, Zhenhan Qin, Zhimei Sun, and Shuxiang Zhang

Subjects
P leaching, P transformation, P application, inorganic-organic combination fertilizer, cropping system types, fertilization, Agriculture
Abstract

Phosphorus (P) leaching from excessive P application is the primary pathway of P losses in agricultural soils. Different P fertilizer practices have mixed effects on P leaching. We conducted a meta-analysis of the relevant literature regarding the response of crop yields, soil-available P (AP), and total P (TP) leaching to reduced P input (RP) and an inorganic-organic combination fertilizer (NPKM) for different agricultural land-use types. Compared to conventional P application (CP), RP (10~90% reduction) did not reduce crop yields in vegetable fields (experiments were 1~4 years) but significantly reduced cereal yields by 4.57%. Compared to chemical fertilizer (NPK), NPKM significantly increased cereal yields by 12.73%. Compared to CP, RP significantly reduced AP at 0~60 cm in vegetable and cereal fields. The greatest reduction occurred at 20~40 cm in vegetable fields (40.29%) and 0~20 cm in cereal fields (34.45%). Compared to NPK, NPKM significantly increased the AP at 0~60 cm in vegetable fields, with the greatest increase (52.44%) at 20~40 cm. The AP at 0~40 cm in cereal fields significantly increased under the NPKM treatment, with the greatest increase at 0~20 cm (76.72%). Compared to CP, RP significantly decreased TP leaching by 16.02% and 31.50% in vegetable and cereal fields, respectively. Compared to NPK, NPKM significantly increased TP leaching in vegetable fields (30.43%); no significant difference in leaching occurred in cereal fields. P leaching, in response to RP, was influenced by the P amounts applied (34.49%); soil organic matter (14.49%); and TP (12.12%). P leaching in response to NPKM was influenced by multiple factors: rainfall (16.05%); soil organic matter (12.37%); soil bulk density (12.07%); TP (11.65%); pH (11.41%). NPKM was more beneficial for improving yields in cereal fields with low soil fertility and lower P-leaching risks.

Published
2023
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10. Hexagonal MBenes-Supported Single Atom as Electrocatalysts for the Nitrogen Reduction Reaction

Author

Ya Gao, Erpeng Wang, Yazhuo Zheng, Jian Zhou, and Zhimei Sun

Subjects
Materials of engineering and construction. Mechanics of materials, TA401-492, Renewable energy sources, TJ807-830
Abstract

The electrocatalytic nitrogen reduction reaction (NRR) is currently constrained by sluggish reaction kinetics and poor selectivity because of the difficulties in activating inert N≡N triple bonds and the existence of competing hydrogen evolution reaction (HER). Therefore, electrocatalysts with high activity, selectivity, and stability are highly desired. Herein, by means of first-principles calculations, we investigated the electrocatalytic NRR performance of a series of transition metal atoms (e.g., 3d, 4d, and 5d) embedded in defective hexagonal MBene nanosheets [h-Zr(Hf)2B2O2] and identified that h-Zr(Hf)2B2O2 could be an excellent platform for electrocatalytic NRR. On the basis of our proposed screening criteria, 16 candidates are efficiently selected out from 50 systems, among which, Zr2B2O2-Cr stands out with high selectivity to NRR against HER and the ultralow limiting potential (−0.10 V). The value is much lower than that of the well-established stepped Ru(0001) surface (−0.43 V). The origin of the high activity toward NRR is attributed to the synergistic effect of the single atom (SA) and the M atoms in the substrate. More impressively, a composition descriptor is further proposed on the basis of the inherent characteristics of the catalysts [number of valence electrons of SA and electronegativity of the SA and Zr(Hf) atoms], which helps to better predict the catalytic performance. Our work not only contributes to the development of highly efficient NRR electrocatalysts but also extend the application of h-MBenes in electrocatalysis.

Published
2023
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11. Melatonin Increases Drought Resistance through Regulating the Fine Root and Root Hair Morphology of Wheat Revealed with RhizoPot

Author

Zhihui Zhang, Li Guo, Hongchun Sun, Jinhua Wu, Liantao Liu, Jianwei Wang, Biao Wang, Qianyi Wang, Zhimei Sun, and Dongxiao Li

Subjects
melatonin, root phenotype, wheat, drought stress response, antioxidant, Agriculture
Abstract

Melatonin application has obvious improving effects on alleviating the drought-induced inhibition of plant growth. However, the root phenotypic dynamics in wheat treated with melatonin remain unknown. This study was conducted using RhizoPot, a novel and improvised in situ root observation device, with three treatments, including normal water condition (CK), drought condition (Ds, relative water content 45–50%), and 100 µM melatonin treatment under drought condition (MT). Results showed that MT application effectively improves root morphological indicators, including root (specific root) length, surface area, and volume; root length density; and the average root diameter of wheat plants. Also, the inhibitory effect of drought on shoot morphology, including plant height, dry weight, net photosynthesis, and stomatal aperture of leaves, were improved significantly through MT under drought condition. Life span and percent survival of fine root, lateral root, and root hair at different segments were also effectively improved under MT treatment. Compared with those shown under CK and Ds, the melatonin contents in leaves and roots were increased, and the expression levels of melatonin-synthesis-related genes (TaCOMT and TaTDC) were upregulated significantly under MT treatment. The findings of this study may clarify the drought resistance mechanism of wheat treated with melatonin under drought stress.

Published
2023
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12. Reasonable Design of MXene-Supported Dual-Atom Catalysts with High Catalytic Activity for Hydrogen Evolution and Oxygen Evolution Reaction: A First-Principles Investigation

Author

Erpeng Wang, Miaoqi Guo, Jian Zhou, and Zhimei Sun

Subjects
first-principles calculation, dual-atom catalysts (DACs), hydrogen evolution reaction, oxygen evolution reaction, electrocatalyist, Technology, Electrical engineering. Electronics. Nuclear engineering, TK1-9971, Engineering (General). Civil engineering (General), TA1-2040, Microscopy, QH201-278.5, Descriptive and experimental mechanics, QC120-168.85
Abstract

MXene-supported single-atom catalysts (SACs) for water splitting has attracted extensive attention. However, the easy aggregation of individual metal atoms used as catalytic active centers usually leads to the relatively low loading of synthetic SACs, which limits the development and application of SACs. Herein, by performing first-principles calculations for Pt and 3d transition metal single atoms immobilized on a two-dimensional (2D) Mo2TiC2O2 MXene surface, we systematically studied the performance of heterogeneous dual-atom catalysts (h-DACs) in hydrogen evolution reaction (HER) and oxygen evolution reaction (OER). Significantly, h-DACs exhibit higher metal atom loading and more flexible active sites compared to SACs. Benefiting from these features, we found that Pt/Cu@Mo2TiC2O2 heterogeneous DACs exhibits excellent HER activity with ultra-low overpotential |ΔGH∗| (0.04 eV), lower than the corresponding Pt@Mo2TiC2O2 (0.14 eV) and Cu@Mo2TiC2O2 (0.33 eV) SACs, and even lower than that of Pt (0.09 eV). Meanwhile, Pt/Ni@Mo2TiC2O2 exhibits superior OER activity with ultra-low overpotential ηOER (0.38 V), lower than that of Pt@Mo2TiC2O2 (1.11 V) and Ni@Mo2TiC2O2 (0.57 V) SACs, and even lower than that of RuO2 (0.42 V) and IrO2 (0.56 V). Our finding paves the way for the rational design of h-DACs for HER and OER with excellent activity, which provides guidance for other catalytic reactions.

Published
2023
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13. Improving the Extraction Process of Mehlich 3 Method for Calcareous Soil Nutrients

Author

Changqing Li, Shuo Wang, Mengyu Sun, Dongxiao Li, Huasen Xu, Liangyu Zhang, Cheng Xue, Wenqi Ma, and Zhimei Sun

Subjects
improved testing method for soil nutrients, extractant, testing precision, testing time, testing cost, calcareous soil, Agriculture
Abstract

Soil nutrient testing is an effective way to uncover soil nutrient status. However, the conventional testing method (CT method) and Mehlich 3 method (M3 method) demand long-time consumption, tedious testing steps, high testing cost, dangerous chemicals contained in extractant, etc. Therefore, it is important to develop a new rapid test method or improve the existing rapid test method of soil available nutrients. In this study, an improved Mehlich3 method (IM3 method) with the new combined extractant were developed and evaluated on the testing feasibility, precision, efficiency, and cost. The results showed that: (1) IM3 method avoided the usage of two hazardous chemicals, i.e., ammonium nitrate and nitric acid, which were difficult in purchase and storage but contained in the combined extractant of M3 method. (2) The correlation coefficients of available P, K, Fe, Mn, Cu and Zn in calcareous soil between M3 and CT, and between IM3 and CT methods all reached highly significant level. The correlation coefficient of available Zn between IM3 and CT method was significantly higher than that between M3 and CT method, and those of the other elements had not obviously changed. (3) The variation coefficients of available P, K, Fe and Cu determined by M3 and IM3 methods were all lower than those determined by CT method. The variation coefficients of available Mn and Zn determined by IM3 were 3.67% and 6.43%, which were slightly higher than those determined by CT method with 2.72% and 5.29%, but were lower than those determined by M3 method. (4) Under the premise of ensuring testing precision, IM3 method took only 6.3 min/piece for determining six elements, reducing testing time by 70.7% and 3.08% compared with CT (21.5 min/piece) and M3 (6.5 min/piece) methods, respectively. The testing cost of IM3 method was reduced by 26% and 61.2% compared with M3 and CT methods, respectively. In conclusion, IM3 method is an ideal rapid measurement method for the simultaneous determination of available soil nutrients in calcareous soil.

Published
2022
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14. Effect of Different Long-Term Potassium Dosages on Crop Yield and Potassium Use Efficiency in the Maize–Wheat Rotation System

Author

Bing He, Cheng Xue, Zhimei Sun, Qingkai Ji, Jing Wei, and Wenqi Ma

Subjects
potassium application, crop yield, potassium use efficiency, potassium fate, Agriculture
Abstract

Potassium (K) is the second most important plant nutritional element and is used for numerous physiological processes. We established an eight-year experiment comparing the effects of five K fertilization treatments (0, 48, 84, 120 and 156 kg K ha−1) on crop yield, K use efficiency and soil apparent K balance under the maize–wheat rotation system in the North China Plain. The highest maize and wheat yields were achieved in the K120 treatment, increasing by up to 16.7% and 25.1%, respectively. The increase in grain yield and K agronomic efficiency (AEK) with K application was greater in wheat than in maize. The K recovery efficiency (REK) and K accumulative recovery efficiency (ARE) significantly decreased with the increase in K fertilization in the maize and wheat seasons. However, the soil apparent K balance and soil available K content increased; the former was deficiency (−24.3 kg ha−1 yr−1) in the K0 treatment, but the latter did not decrease significantly compared with that in the initial year of the experiment. The soil available K content increased by 10.9 mg kg−1 per 100 kg ha−1. In conclusion, the yield response to K fertilization was greater in wheat than in maize and alleviated soil K depletion, but the K fertilizer efficiency was lower. We believed that K fertilizer can be increased moderately in the wheat season and decreased in the maize season.

Published
2022
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15. Comprehensive Assessment of Plant and Water Productivity Responses in Negative Pressure Irrigation Technology: A Meta-Analysis

Author

Yuwen Jin, Xiang Gao, Renlian Zhang, Xueping Wu, Huaiyu Long, Zhimei Sun, and Shuxiang Zhang

Subjects
negative pressure irrigation, yield, quality of plant, water use efficiency, fertilization, Agriculture
Abstract

Negative pressure irrigation (NPI) is an important water management strategy that can improve crop yields and water use efficiency (WUE). However, because NPI is affected by vital factors, such as negative pressure values, soil properties, and fertilization dosages, there is a lack of systematic analyses of the application effects of NPI on various crops. Hence, this study collected the results of 44 published studies and established the validity of 142 crop yields, 121 WUEs, 138 crop qualities, and 138 crop nutrient statuses in a database for NPI systems. The meta-analysis method was used to analyze NPI in comparison to conventional irrigation (CI) conditions. The results showed that the NPI yields and WUEs significantly improved by 17% and 63% compared to those of CI, respectively. Meanwhile, the negative pressure values were −2~−5 kPa; the improvement effects on yields were the best; and the WUEs exhibited the highest performance with negative pressure values of −6~−10 kPa. NPI promoted crop quality and plant nutrient uptakes under the appropriate NPI conditions. The synergistic impacts for sandy loam, alkalescent soils, and leafy vegetables were greater than for clay loam, neutral soils, and fruit vegetables under NPI conditions. Simultaneously, it was shown that the soil available phosphorus content and application of P fertilizer have a greater impact on NPI and CI crop yields. Therefore, the meta-analysis demonstrated the impacts of NPI on crop yields, WUEs, quality, and nutrient absorption, and quantified the effects of NPI on crop growth under various conditions, which provides an important water-saving technology for greenhouse production.

Published
2022
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16. The Effects of 3,5-Dimethylpyrazole on Soil Nitrification and Related Enzyme Activities in Brown Soil

Author

Yuanchuang Lu, Dongxiao Li, Changqing Li, Mengyu Sun, Zhijie Wu, and Zhimei Sun

Subjects
3,5-dimethylpyrazole, nitrification inhibition, nitrite reductase activity, nitrate reductase activity, dehydrogenase activity, Agriculture
Abstract

Heterocyclic nitrogen compounds containing two adjacent nitrogen atoms generally have a significant effect on soil nitrification inhibition, and 3,5-dimethylpyrazole (DMP) is a typical representative of this structure. However, the inhibitory effect and the regulatory mechanism of DMP on soil N transformation are unclear. In this study, a microcosm with different concentrations of DMP was carried out in brown soil to detect the dynamic changes of soil NH4+–N, NO3–N and related soil enzyme activities. Results showed that DMP inhibited soil nitrification effectively and decreased soil nitrate reductase activity, while increasing nitrite reductase and dehydrogenase activities. The inhibition effects were dose dependent, and DMP at the rate of 0.025 g kg−1 dry soil showed the strongest inhibitory effect on N transformation in brown soil. The soil dehydrogenase activity was increased with an increasing DMP application rate. The changes in the soil’s chemical and biological properties caused by DMP application provided a new idea for systematically explaining how DMP participated in the soil N transformation process. This study further implied that DMP would play positive roles in alleviating environmental pressure by delaying nitrate-N formation and decreasing the activity of nitrate reductase.

Published
2022
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19. New horizons of MBenes: highly active catalysts for the CO oxidation reaction

Author

Bikun Zhang, Jian Zhou, and Zhimei Sun

Subjects
General Materials Science
Abstract

The search for materials with high intrinsic carbon monoxide oxidation reaction (COOR) catalytic activity is critical for enhancing the efficiency of reducing CO contamination. COOR catalysts, however, have long relied heavily on noble metals and CeO

Published
2023

20. Ultrahigh overall-performance phase-change memory by yttrium dragging

Author

Bin Liu, Kaiqi Li, Jian Zhou, Liangcai Wu, Zhitang Song, Weisheng Zhao, Stephen R. Elliott, and Zhimei Sun

Subjects
Materials Chemistry, General Chemistry
Abstract

Benefiting from the dragging effect of yttrium, an ultrahigh overall-performance phase-change memory is reported, including low resistance drift, high data retention, low power consumption, fast operating speed, and good cycling endurance.

Published
2023

26. Materials Data toward Machine Learning: Advances and Challenges

Author

Linggang Zhu, Jian Zhou, and Zhimei Sun

Subjects
Machine Learning, General Materials Science, Physical and Theoretical Chemistry
Abstract

Machine learning (ML) is believed to have enabled a paradigm shift in materials research, and in practice, ML has demonstrated its power in speeding up the cost-efficient discovery of new materials and autonomizing materials laboratories. In this Perspective, current research progress in materials data which are the backbones of ML are reviewed, focusing on high-throughput data generation, standardized data storage, and data representation. More importantly, the challenging issues in materials data that should be overcome to unlock the full potential of ML in materials research and development, including classic 5V (volume, velocity, variety, veracity, and value) issues, 3M (multicomponent, multiscale, and multistage) challenges, co-mining of experimental and computational data, and materials data toward transferable/explainable ML or causal ML, are discussed.

Published
2022

27. Robust Design of High-Performance Optoelectronic Chalcogenide Crystals from High-Throughput Computation

Author

Yu Gan, Naihua Miao, Penghua Lan, Jian Zhou, Stephen R. Elliott, and Zhimei Sun

Subjects
Colloid and Surface Chemistry, General Chemistry, Biochemistry, Catalysis
Abstract

High-performance functional materials are the cornerstones of the continuous advance of modern science and technology, but the development of new materials is still challenging. Here, we propose a robust design strategy for novel crystalline solids based on group-theory classification and high-throughput computation, as demonstrated by the successful identification of new optoelectronic semiconductors. First, by means of theoretical group analysis and composition engineering, we obtained 78 prototypical crystal structures and built a computational materials database containing 21,060 ternary chalcogenide compounds. Our high-throughput screening of the coordination characteristics, phase stability, and electronic structures provided 97 candidate semiconductors, including 93 completely new compounds. Among them, 22 crystals with excellent dynamical and thermal stability are predicted to show high photovoltaic conversion efficiency (30%), comparable to the currently most efficient single-junction GaAs solar cell, owing to their optimal electronic properties and outstanding optical absorption. This discovery of new chalcogenide crystals offers excellent candidates for optoelectronic applications and suggests that our design strategy is a promising way to search for unknown high-performance functional materials.

Published
2022

28. Breaking scaling relations in nitric oxide reduction by surface functionalization of MXenes

Author

Shihui Zhao, Ying Li, Zhonglu Guo, Chengchun Tang, Baisheng Sa, Naihua Miao, Jian Zhou, and Zhimei Sun

Subjects
Renewable Energy, Sustainability and the Environment, General Materials Science, General Chemistry
Abstract

A design principle was proposed to break the linear scaling relationships of key intermediates in the NORR for promoted reaction thermodynamics via modifying the surface functionalization of MXenes.

Published
2022

29. Computational design of double transition metal MXenes with intrinsic magnetic properties

Author

Yinggan Zhang, Zhou Cui, Baisheng Sa, Naihua Miao, Jian Zhou, and Zhimei Sun

Subjects
General Materials Science
Abstract

Two-dimensional transition metal carbides (MXenes) have great potential to achieve intrinsic magnetism due to their available chemical and structural diversity. In this work, by spin-polarized density functional theory calculations, we designed and comprehensively investigated 50 double transition metal (DTM) MXenes MCr

Published
2022

32. MBenes: progress, challenges and future

Author

Bikun Zhang, Jian Zhou, and Zhimei Sun

Subjects
Renewable Energy, Sustainability and the Environment, General Materials Science, General Chemistry
Abstract

The synthesis methods, properties and applications for energy storage and electrocatalysis of MBenes were summarized. Furthermore, discussions and perspectives on the existing problems, major challenges and future development of MBenes were provided.

Published
2022

33. Giant tunneling magnetoresistance in two-dimensional magnetic tunnel junctions based on double transition metal MXene ScCr2C2F2

Author

Zhou Cui, Yinggan Zhang, Rui Xiong, Cuilian Wen, Jian Zhou, Baisheng Sa, and Zhimei Sun

Subjects
General Engineering, General Materials Science, Bioengineering, General Chemistry, Atomic and Molecular Physics, and Optics
Abstract

Two-dimensional double transition metal MXene ScCr2C2F2-based van der Waals magnetic tunnel junctionss with 2H-MoS2 layers as the tunnel barriers have been proposed to show the maximum tunnel magnetoresistance ratios of 6.95 × 106%.

Published
2022

35. Multi-level phase-change memory with ultralow power consumption and resistance drift

Author

Stephen R. Elliott, Kaiqi Li, Bin Liu, Liangcai Wu, Jian Zhou, Zhimei Sun, Wanliang Liu, and Zhitang Song

Subjects
Antimony telluride, Phase transition, Multidisciplinary, Materials science, business.industry, Chalcogenide, Amorphous solid, Phase-change memory, Condensed Matter::Materials Science, chemistry.chemical_compound, chemistry, Phase (matter), Metastability, Computer data storage, Optoelectronics, business
Abstract

By controlling the amorphous-to-crystalline relative volume, chalcogenide phase-change memory materials can provide multi-level data storage (MLS), which offers great potential for high-density storage-class memory and neuro-inspired computing. However, this type of MLS system suffers from high power consumption and a severe time-dependent resistance increase (“drift”) in the amorphous phase, which limits the number of attainable storage levels. Here, we report a new type of MLS system in yttrium-doped antimony telluride, utilizing reversible multi-level phase transitions between three states, i.e., amorphous, metastable cubic and stable hexagonal crystalline phases, with ultralow power consumption (0.6–4.3 pJ) and ultralow resistance drift for the lower two states (power-law exponent

Published
2021

40. List of contributors

Author

M. Basheer Ahamed, Mustafa Farag Ibrahim Aly Rakha, Jamilur R. Ansari, Amir Hossein Behroozi, Ashok Chhetry, Ying-Hui Chin, Chunxiang Dall’Agnese, Yohan Dall’Agnese, Desagani Dayananda, Kalim Deshmukh, George Elsa, Zahra Fakhraai, Alireza Hemmati, Chaudhery Mustansar Hussain, Zeeshan Haider Jaffari, Xin Jin, M. Johnson, Poliraju Kalluru, Tathagata Kar, Mani Karthik, Rüstem Keçili, L. John Kennedy, Mohan Kumar Kesarla, Gyan Raj Koirala, Tomáš Kovářík, Y. Ravi Kumar, Naresh Kuthala, Sze-Mun Lam, Haixiang Li, Xingyou Liang, Hua Lin, Anmin Liu, Tingli Ma, Abdul Rahman Mohamed, M. Mohamed Naseer Ali, Aqib Muzaffar, Kallayi Nabeela, Aamani Nirogi, Dhananjaya Panda, Mayank Pandey, Deependra Parajuli, S.K. Khadheer Pasha, Deepalekshmi Ponnamma, Jothi Ramalingam Rajabathar, Kalagadda Venkateswara Rao, M. Sai Bhargava Reddy, P. Lokanatha Reddy, Kishor Kumar Sadasivuni, Pachagounder Sakthivel, K. Samatha, Ammaiyappan Bharathi Sankar, Kailasa Saraswathi, A.M. Schornack, Ahmad Arabi Shamsabadi, Jin-Chung Sin, Masoud Soroush, N.B. Sumina, Yuliang Sun, Zhimei Sun, Choudhary Arjun Sunilbhai, Suresh Thangudu, Jayaraman Theerthagiri, Raviraj Vankayala, Nachimuthu Venkatesh, Manavalan Vijayakumar, D. Wang, Xiao-Feng Wang, Sadiya Waseem, Lin Yang, Zi-Jun Yong, Yadong Yu, Honghu Zeng, Chao Zhang, Q. Zhang, and Jian Zhou

Published
2022

49. Structural stability and mechanical properties of B2 ordered refractory AlNbTiVZr high entropy alloys

Author

Naihua Naihua, Shi Qiu, Zhimei Sun, Qing-Miao Hu, Jian Zhou, and Chen Shuming

Subjects
Work (thermodynamics), Materials science, Mechanical Engineering, High entropy alloys, Alloy, Metals and Alloys, Thermodynamics, engineering.material, Temperature and pressure, Mechanics of Materials, Structural stability, High pressure, Materials Chemistry, engineering, Refractory (planetary science)
Abstract

Local chemical ordering influences significantly the mechanical properties of refractory high entropy alloys. In this work, the effects of local chemical ordering on the structural stability and mechanical properties of AlNbVTiZr are investigated by using first-principles simulations. It is shown that the Al Zr bond dominates the chemical ordering for ordered configurations. The local ordering enhances the structural stability, elastic property and ideal strength. By taking into account the effects of temperature and pressure, we found that chemical ordering mediates the thermodynamic properties of the AlNbVTiZr alloy, but it has little effect at high pressure.

Published
2021

50. Vacancy-mediated electronic localization and phase transition in cubic Sb2Te3

Author

Kaiqi Li, Jian Zhou, Linggang Zhu, Liyu Peng, and Zhimei Sun

Subjects
Phase transition, Materials science, Condensed matter physics, Mechanical Engineering, Fermi level, Condensed Matter Physics, Amorphous solid, Crystal, Condensed Matter::Materials Science, symbols.namesake, Mechanics of Materials, Ab initio quantum chemistry methods, Vacancy defect, Phase (matter), Metastability, symbols, General Materials Science
Abstract

Sb2Te3 is a very promising phase-change material due to its fast reversible phase transition between the amorphous and crystal phases. Crystalline Sb2Te3 can adopt the cubic (rock-salt) or rhombohedral structure, and for the cubic Sb2Te3 which is metastable, 33.3% vacancies exist in the Sb sublattice. The intrinsic vacancies which normally have significant effects on the fundamental property of the phase-change material need to be thoroughly studied for the practical application of Sb2Te3. In this work, by using ab initio calculations, various configurations of the vacancies with different randomness as well as their effects on the electronic property and phase transition of cubic Sb2Te3 are investigated. We found that the vacancy configurations that have rather small energy difference can exhibit contrast electronic property and different localized states near Fermi level. Furthermore, the migration of Sb atom and the lattice transformation accounting for the phase transition between cubic and rhombohedral Sb2Te3 have smaller energy barrier than those in Ge-Sb-Te compound, which should be responsible for the metastability of cubic Sb2Te3 and its rapid transition to the rhombohedral phase. Our results provide a comprehensive understanding of cubic Sb2Te3 and may offer new insight into the development of phase-change memory based on Sb2Te3.

Published
2021

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