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Keywords = non-stoichiometric

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17 pages, 9337 KB  
Article
Soil C:N:P:K Stoichiometric Imbalance Regulates the Effects of Karst Rocky Desertification Gradients on Rosa roxburghii Fruit Quality
by Mingfeng Du and Mingjun Li
Forests 2026, 17(7), 746; https://doi.org/10.3390/f17070746 - 26 Jun 2026
Viewed by 131
Abstract
Karst rocky desertification (KRD) is a critical abiotic stressor that compromises Rosa roxburghii Tratt fruit quality, yet its underlying physiological and ecological pathways remain poorly understood. This study aims to bridge this knowledge gap by elucidating how KRD-driven soil C:N:P:K stoichiometric shifts indirectly [...] Read more.
Karst rocky desertification (KRD) is a critical abiotic stressor that compromises Rosa roxburghii Tratt fruit quality, yet its underlying physiological and ecological pathways remain poorly understood. This study aims to bridge this knowledge gap by elucidating how KRD-driven soil C:N:P:K stoichiometric shifts indirectly affect fruit quality (vitamin C and fructose) by disrupting fruit internal elemental balance. We characterized soil nutrient dynamics and evaluated fruit quality along the natural rocky desertification gradient (RDG) in Guizhou, China. Mantel tests and structural equation modeling (SEM) were applied to identify primary predictors and quantify integrated pathways. With increasing desertification, total organic carbon (TOC), total nitrogen (TN), and soil C:P ratio (C:P) increased monotonically, while total phosphorus (TP) remained at a low concentration without significant change. Available phosphorus (AP) and available potassium (AK) followed a U-shaped trend, reaching their minimum under moderate desertification, whereas total potassium (TK) peaked at this stage before declining. Correspondingly, fruit vitamin C (FVC) and fruit fructose (FF) exhibited a non-linear pattern, first increasing under light stress, then decreasing under moderate stress, and finally rebounding under severe desertification, which is consistent with the nonlinear response pattern of fruit C:P ratio (FC:FP) reported for the same desertification stages. The SEM revealed a dual-pathway mechanism: KRD directly enhanced FVC (β = 0.69, p < 0.001), while KRD and soil properties enhanced FF (β = 0.39 and 0.64, respectively, p < 0.01). KRD also indirectly lowered FVC and FF through a sequential nutrient cascade that promoted soil nutrients (Soil, β = 0.81–0.82, p < 0.001), which triggered negative effects particularly via soil stoichiometry (SS, |β| = 0.76–0.91, p < 0.001), with a modest additional contribution from fruit stoichiometry (FS, |β| ≈ 0.27, p < 0.05). This suggests that KRD influences fruit quality via a soil–plant network mediated by soil P-limitation and K-dynamics. Balanced P and K management may, therefore, be critical for maintaining fruit quality and ecological restoration in karst ecosystems. Full article
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18 pages, 12787 KB  
Article
Experimental Study of NH3-Simulated LPG Combustion Characteristics in a Crossflow Slot Burner
by Thanyalak Sudjan and Amornrat Kaewpradap
Energies 2026, 19(13), 2975; https://doi.org/10.3390/en19132975 - 24 Jun 2026
Viewed by 139
Abstract
Among pathways toward carbon neutrality, substituting hydrocarbons with hydrogen-carrier fuels such as ammonia presents significant potential for carbon emission reduction. This study examines the combustion characteristics of ammonia (NH3) and simulated LPG consisting of 70% propane (C3H8) [...] Read more.
Among pathways toward carbon neutrality, substituting hydrocarbons with hydrogen-carrier fuels such as ammonia presents significant potential for carbon emission reduction. This study examines the combustion characteristics of ammonia (NH3) and simulated LPG consisting of 70% propane (C3H8) and 30% butane (C4H10) by volume blends under non-premixed conditions using a crossflow slot burner. Flame appearance, OH* chemiluminescence, flame temperature, and CO and NOx emissions were evaluated at equivalence ratios (Φ) of 0.4, 0.7, and 1.0, with ammonia fractions ranging from 0% to 70%. Increasing ammonia content decreased OH* chemiluminescence intensity, indicating a reduced radical pool and lower reaction intensity, particularly under lean conditions. Nevertheless, stable combustion was achieved at Φ = 1.0 due to improved mixing and heat recirculation. Flame temperature declined by only 9.3%, even at 70% ammonia, confirming good thermal stability. NOx emissions exhibited non-monotonic behavior, increasing at moderate ammonia fractions due to fuel-bound nitrogen and thermal mechanisms, and then decreasing at higher ammonia levels as flame temperature and radical activity diminished, while CO emissions remained low up to 50% ammonia near stoichiometric conditions but increased under ultra-lean operation because of limited oxidation kinetics. These results highlight the feasibility of simulated LPG–NH3 blends as transitional low-carbon fuels in practical combustion systems. Full article
(This article belongs to the Section B2: Clean Energy)
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16 pages, 4222 KB  
Review
Review: Enteric Methane Emissions Across Physiological Stages and Dietary NDF/NFC Ratios in Holstein Dairy Cattle—Implications for China’s Carbon Mitigation
by Peng Jia, Yan Tu, Naifeng Zhang, Naisheng Lu, Hulong Lei, Xueyuan Jiang and Qiyu Diao
Animals 2026, 16(11), 1684; https://doi.org/10.3390/ani16111684 - 30 May 2026
Viewed by 625
Abstract
Dairy cattle are a substantial contributor to global agricultural greenhouse gas emissions, primarily producing enteric methane through the ruminal anaerobic fermentation of dietary fiber. As China formally pledges to achieve carbon neutrality before 2060, accurately quantifying these emissions and developing localized mitigation strategies [...] Read more.
Dairy cattle are a substantial contributor to global agricultural greenhouse gas emissions, primarily producing enteric methane through the ruminal anaerobic fermentation of dietary fiber. As China formally pledges to achieve carbon neutrality before 2060, accurately quantifying these emissions and developing localized mitigation strategies within the livestock sector has become a critical priority. Enteric methane emissions in dairy cattle are not a static physiological baseline; rather, they represent a highly dynamic phenotype profoundly influenced by an intricate network of physiological and environmental parameters. These include the animal’s age, anatomical and ruminal development, parity, lactation stage, and the precise stoichiometric balance of dietary carbohydrates. This review synthesizes extensive experimental data to construct a robust, scientifically logical framework elucidating the profound physiological mechanisms that govern apparent methane emission parameters. Accordingly, this paper reviews our recent research on methane emissions from Holstein dairy cattle across various ages and lactation stages, including heifers, lactating cows, and dry cows. Furthermore, it extensively evaluates the modulation of methanogenesis under diets with varying neutral detergent fiber to non-fibrous carbohydrate (NDF/NFC) ratios, demonstrating that an increased NDF/NFC ratio is positively correlated with higher enteric methane production, yield, and intensity due to the promotion of acetate-type ruminal fermentation. Ultimately, this review aims to provide robust theoretical support for the accurate quantification of enteric methane emissions and the formulation of precision mitigation strategies tailored to specific physiological states. Full article
(This article belongs to the Special Issue Optimizing Rumen Functions for Digestive Efficiency)
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20 pages, 2223 KB  
Article
Integrated Organic–Inorganic Fertilization Enhances Microbial Stoichiometric Homeostasis but Triggers Seasonal Metabolic Trade-Offs in an Alpine Sandy Ecosystem
by Kai Yang, Fuchun Huang, Wensheng Yang, Xupeng Lu, Zhengtao Zhu, Jianqiang Zhu, Qixia Wu and Xiaohong Xu
Microorganisms 2026, 14(6), 1186; https://doi.org/10.3390/microorganisms14061186 - 25 May 2026
Viewed by 370
Abstract
The ecological restoration of degraded sandy land in the Yarlung Zangbo River Valley is constrained by the metabolic functions of soil microorganisms. This study investigates the dynamic mechanisms of microbial elemental use efficiency in walnut plantations, with a focus on seasonal variations in [...] Read more.
The ecological restoration of degraded sandy land in the Yarlung Zangbo River Valley is constrained by the metabolic functions of soil microorganisms. This study investigates the dynamic mechanisms of microbial elemental use efficiency in walnut plantations, with a focus on seasonal variations in soil chemical stoichiometry, extracellular enzyme activity, and microbial nutrient efficiency in rhizosphere and bulk soils. This paper explores the effects of conventional organic fertilizer (CF) and organic–inorganic compound fertilizer (OIF) on microbial nutrient use strategies and their seasonal dynamics. The results showed significant seasonal fluctuations in soil active nutrients and microbial biomass, while the total nutrient content remained stable. OIF enhanced microbial chemical stoichiometric homeostasis but simultaneously triggered a “carbon–phosphorus metabolic trade-off”, leading to a restraint of microbial carbon use efficiency (CUE) during the growing season. Microbial elemental use efficiency (EUE) exhibited clear seasonal differentiation: CUE was higher in summer, promoting biomass accumulation, whereas NUE and PUE increased in winter and spring, reflecting a nutrient conservation strategy. The EUE pathways were decoupled between rhizosphere and non-rhizosphere microenvironments. The rhizosphere was more directly driven by soil chemical stoichiometry and microbial biomass, while the non-rhizosphere was influenced by nutrient limitation states, represented by vector characteristics. This study provides insights into the seasonal adaptability and microenvironmental heterogeneity of microbial metabolism during the restoration of cold sandy land. It is suggested that future ecological management should focus on N-P balanced fertilization and consider the differential responses between rhizosphere and non-rhizosphere zones to enhance ecosystem productivity and soil carbon, nitrogen, and phosphorus sequestration potential. Full article
(This article belongs to the Section Environmental Microbiology)
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14 pages, 21880 KB  
Article
Morphology-Dependent Antibacterial Activity of Cu2-xS Nanostructures: Nanoplates Versus Superparticles
by Hui Zhu, Mengzhe Zhao, Yang Chao, Jun Yao, Qin Yu and Na Sun
Nanomaterials 2026, 16(10), 636; https://doi.org/10.3390/nano16100636 - 20 May 2026
Viewed by 394
Abstract
Non-stoichiometric copper sulfide (Cu2-xS) nanomaterials are promising antibacterial agents, but the role of morphology in regulating their bactericidal performance remains poorly understood. Herein, we rationally design two types of Cu2-xS nanostructures, namely nanoplates (NPs) and superparticles (SPs). Both materials [...] Read more.
Non-stoichiometric copper sulfide (Cu2-xS) nanomaterials are promising antibacterial agents, but the role of morphology in regulating their bactericidal performance remains poorly understood. Herein, we rationally design two types of Cu2-xS nanostructures, namely nanoplates (NPs) and superparticles (SPs). Both materials were prepared via a ligand-directed synthesis method with the comparable sizes, surface ligands, and crystal phase. The antibacterial behaviors of Cu2-xS NPs and Cu2-xS SPs against Escherichia coli (E. coli) and Staphylococcus aureus (S. aureus) were investigated under dark and 808 nm near-infrared (NIR) light irradiation. The results showed that under NIR light irradiation, Cu2-xS SPs exhibit a markedly higher bactericidal efficiency against both E. coli and S. aureus than Cu2-xS NPs, leading to almost complete eradication of bacterial colonies. Notably, S. aureus shows more sensitive than E. coli, and significant growth inhibition is observed even in the absence of laser irradiation. Mechanistic investigations reveal that hierarchical assembly of primary nanoparticles in SPs can promote multiple internal light scatterings, thereby significantly enhancing light harvesting efficiency and further improving the photothermal conversion efficiency. In addition, the SPs exhibited higher peroxidase-like activity, resulting in enhanced reactive oxygen species (ROS) generation and aggravated oxidative damage, and the accelerated Cu2+ release kinetics strengthens ionic toxicity. Full article
(This article belongs to the Section Synthesis, Interfaces and Nanostructures)
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23 pages, 2057 KB  
Article
Defect Thermodynamics and the Intrinsic Stability Window of Mg3Sb2
by Madhuri Birare, Adam Dębski, Władysław Gąsior and Wojciech Gierlotka
Metals 2026, 16(5), 558; https://doi.org/10.3390/met16050558 - 20 May 2026
Viewed by 389
Abstract
Magnesium antimonide (Mg3Sb2) has emerged as a promising high-performance thermoelectric material, yet its efficiency is fundamentally determined by intrinsic point defects. In this study, we present a comprehensive investigation of defects in the intermetallic compound Mg3Sb2 [...] Read more.
Magnesium antimonide (Mg3Sb2) has emerged as a promising high-performance thermoelectric material, yet its efficiency is fundamentally determined by intrinsic point defects. In this study, we present a comprehensive investigation of defects in the intermetallic compound Mg3Sb2 using first laws of thermodynamics and density functional theory (DFT) within the generalized gradient approximation (GGA). By calculating the energy of defect formation and the charge transition energy between energy levels, it was determined how the change in chemical potential associated with phase synthesis affects the phase stability and carrier concentrations. Calculations show that donor defects dominate in Mg-rich alloys, primarily antimony vacancies and magnesium atoms in interstitial positions. This means that in a phase with a slight magnesium excess, e.g., Mg3.01Sb1.99 at 1400 K, n-type conductivity dominates. In the opposite case, i.e., in an Sb-rich alloy, magnesium vacancies spontaneously form in the Wyckoff 1a position. These ionized acceptors induce strong self-compensation, blocking the Fermi level about 0.38 eV above the valence band maximum. As a result of this process, the Mg3Sb2 phase, at elevated temperatures, becomes the non-stoichiometric Mg2.99Sb2.01 phase, which causes the material to retain p-type conductivity and actively block doping-induced n-type conductivity. The conducted studies demonstrate that the homogeneity range of the Mg-Sb system, although traditionally considered narrow, has a significant impact on the semiconducting properties of the material. Furthermore, they also point to the need for continued research on high temperature in the area of synthetic defect engineering, interface engineering, and optimization of the thermoelectric properties of materials based on Mg-Sb alloys. Full article
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22 pages, 2450 KB  
Review
Tantalum Pentoxide Optical Coatings for High-Power Photonics: A Review of Deposition, Defect Control, Nonlinear Response, and Laser Damage Reliability
by Changtong Li, Hsin-Han Peng, Chih-Yu Wang, Hsiang-Chen Chui, Chao-Kuei Lee and Xiaoming Chen
Coatings 2026, 16(5), 596; https://doi.org/10.3390/coatings16050596 - 14 May 2026
Viewed by 443
Abstract
Tantalum pentoxide (Ta2O5) has emerged as a versatile material at the intersection of optical coatings and integrated photonics because it combines a high refractive index, a wide bandgap, low optical loss, and compatibility with multiple thin-film deposition routes. Over [...] Read more.
Tantalum pentoxide (Ta2O5) has emerged as a versatile material at the intersection of optical coatings and integrated photonics because it combines a high refractive index, a wide bandgap, low optical loss, and compatibility with multiple thin-film deposition routes. Over the past decade, the literature has expanded from conventional dielectric coating studies to low-loss waveguides, micro-ring resonators, wavelength conversion, and broadband supercontinuum generation, while more recent work has increasingly emphasized defect engineering, nonlinear absorption, and laser damage reliability under strong optical fields. The objective of this review is to establish a process–structure–composition–property–function–reliability framework for understanding Ta2O5 and non-stoichiometric Ta2O5−x optical coatings in high-power photonics. Unlike previous reviews that mainly emphasized dielectric properties, deposition methods, or general thin-film applications, this review highlights how deposition-induced composition changes, oxygen vacancy-related defects, nonlinear optical response, and laser damage reliability jointly determine the operational limits of tantalum oxide photonic materials. Particular attention is given to ion-assisted and ion gun-assisted processes, which have repeatedly been associated with higher film density, smoother morphology, reduced oxygen vacancy-related loss, and more stable high-field behavior. By linking coating-level process control to device-level functions such as four-wave mixing, self-phase modulation, wavelength conversion, and supercontinuum generation, this review highlights how thin-film engineering governs both optical performance and operational limits. It also identifies several persistent gaps, including the need for standardized reporting of nonlinear absorption, unified damage metrics across film and device geometries, and stronger correlations among microstructure, composition, defects, and long-term optical stability. Overall, this review provides a composition-aware and coating-informed framework for interpreting Ta2O5 photonics and a practical roadmap for developing durable high-power photonic components. Full article
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11 pages, 2976 KB  
Article
The Effects of Electron-Beam-Radiation-Induced Damage on Single-Crystal Silicon Devices with SiO2 Surface Passivation in a Nitrogen Atmosphere
by Yuqing Yang, Yisong Lei, Xinxi Li, Wenzeng Bing, Hongbo Li, Yongjun Xiang and Shuming Peng
Materials 2026, 19(10), 1964; https://doi.org/10.3390/ma19101964 - 10 May 2026
Viewed by 949
Abstract
In energy conversion semiconductor devices, radiation damage is directly related to the long-term stability of β-voltaic batteries. In this study, single-crystalline silicon P+NN+ devices and P+-silicon materials with SiO2 surface passivation were irradiated using a ~70 keV [...] Read more.
In energy conversion semiconductor devices, radiation damage is directly related to the long-term stability of β-voltaic batteries. In this study, single-crystalline silicon P+NN+ devices and P+-silicon materials with SiO2 surface passivation were irradiated using a ~70 keV accelerator electron beam in a nitrogen atmosphere for 2 min, 10 min, 1 h, 6 h, and 12 h. The tritium-voltaic output decreased rapidly within the first 2 min of electron beam irradiation and then decayed slowly. After 1 h of irradiation, both the output short-circuit current (Isc) and open-circuit voltage (Voc) remained stable. The effects of the damage were analyzed using typical samples irradiated for 1 h. Neutron reflectometry (NR) was employed as the primary characterization method, while X-ray photoelectron spectroscopy (XPS)—combined with Ar+ etching—and secondary ion mass spectrometry (SIMS) were used to verify radiation-induced structural changes at the SiO2 surface and SiO2/Si interface. It was found that nitrogen atoms from the atmosphere penetrated the SiO2 layer to a depth of approximately 5–10 nm, forming a non-stoichiometric SiON structure, without further diffusion into deeper layers. Irradiation significantly increased the thickness of the SiO2/Si interface transition layer to about 14–18.5 nm, and the SiO2 structure within this layer became relatively loose. It can be inferred that tritium-voltaic batteries using SiO2-surface-passivated single-crystalline silicon P+NN+ devices as energy-conversion units and packaged in a nitrogen atmosphere can stably provide power for 10 years, with an Isc reduction of no more than 12% and a Voc reduction of no more than 6%, excluding the spontaneous decay of tritium. Full article
(This article belongs to the Topic New Research on Thin Films and Nanostructures)
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13 pages, 7112 KB  
Article
Synthesis, Microstructure and Properties of Non-Stoichiometric High-Entropy Carbide (Nb0.2Ta0.2Ti0.2W0.2Zr0.2)Cx Powder
by Tong He, Shihao Zhu, Zhiyu Zhang, Zhongshan Ma, Bin He, Chao He and Wanxiu Hai
J. Compos. Sci. 2026, 10(5), 258; https://doi.org/10.3390/jcs10050258 - 10 May 2026
Viewed by 1114
Abstract
Non-stoichiometric high-entropy carbides (Nb0.2Ta0.2Ti0.2W0.2Zr0.2)Cx (x = 0.71–0.85) nanoscale powders were prepared using oxides and carbon as raw materials via carbothermal reduction. The (Nb0.2Ta0.2Ti0.2W0.2Zr0.2 [...] Read more.
Non-stoichiometric high-entropy carbides (Nb0.2Ta0.2Ti0.2W0.2Zr0.2)Cx (x = 0.71–0.85) nanoscale powders were prepared using oxides and carbon as raw materials via carbothermal reduction. The (Nb0.2Ta0.2Ti0.2W0.2Zr0.2)C0.73 synthesized at 1700 °C exhibited a grain size of approximately 400 nm, an oxygen content of 0.3 wt.%, and uniform nanoscale distribution of the five metal elements. After ball milling, (Nb0.2Ta0.2Ti0.2W0.2Zr0.2)C0.73 powder was sintered by spark plasma sintering to produce high-entropy ceramics with a relative density of 98.1% and an average particle size of about 5.3 μm. The Vickers hardness, nano-hardness, Young’s modulus, and fracture toughness were 17.6 GPa, 29.1 GPa, 514 GPa, and 5.3 MPa·m1/2, respectively. The thermal conductivity of the ceramic at room-temperature was as low as 8.5 W/m·K. Full article
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22 pages, 7023 KB  
Review
Self-Propagating High-Temperature Synthesis as an Enabling Route for High-Entropy MAX Phases
by Ali Haider Bhalli, Sofiya Aydinyan, Roman Ivanov and Irina Hussainova
Materials 2026, 19(9), 1829; https://doi.org/10.3390/ma19091829 - 29 Apr 2026
Viewed by 971
Abstract
High-entropy MAX (HE-MAX) phases represent a new class of layered ceramics that combine the multi-principal-element chemistry of high-entropy materials with intrinsic damage tolerance, electrical conductivity, and multifunctionality of conventional MAX phases. Despite their promise, the synthesis of HE-MAX phases remains fundamentally constrained by [...] Read more.
High-entropy MAX (HE-MAX) phases represent a new class of layered ceramics that combine the multi-principal-element chemistry of high-entropy materials with intrinsic damage tolerance, electrical conductivity, and multifunctionality of conventional MAX phases. Despite their promise, the synthesis of HE-MAX phases remains fundamentally constrained by sluggish multicomponent diffusion, narrow thermodynamic stability windows, and strong competition from thermodynamically favored binary and ternary carbides, borides, and nitrides. These challenges are further exacerbated by the volatility of A-site elements under near-equilibrium processing conditions. This review positions self-propagating high-temperature synthesis (SHS) as an energy-efficient, non-equilibrium processing route capable of stabilizing selected entropy-driven MAX chemistries through ultrafast thermal excursions and rapid quenching. A unified thermodynamic–kinetic framework is developed to elucidate the interplay among reaction enthalpy, configurational entropy, combustion wave sustainability, and phase evolution in HE-MAX systems. Predictions of thermochemical adiabatic temperature are systematically correlated with experimental SHS studies to delineate phase stability boundaries, stoichiometric sensitivity, and the roles of diluents and transient liquid formation. Finally, practical design principles for scalable SHS synthesis of HE-MAX phases are outlined, alongside strategies for their selective exfoliation into high-entropy MXenes and a critical assessment of their emerging functional applications. Full article
(This article belongs to the Section Advanced and Functional Ceramics and Glasses)
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15 pages, 10706 KB  
Article
Stabilization of Transport Properties in Thin Nonstoichiometric La1−xSrxMnyO3 Films via Accelerated Aging for Magnetic Field Sensors
by Vakaris Rudokas, Mykola Koliada, Voitech Stankevic, Skirmantas Kersulis, Vilius Vertelis, Sonata Tolvaišienė, Martynas Skapas, Milita Vagner, Valentina Plausinaitiene and Nerija Zurauskiene
Sensors 2026, 26(9), 2711; https://doi.org/10.3390/s26092711 - 28 Apr 2026
Viewed by 620
Abstract
Magnetic sensors based on the colossal magnetoresistance (CMR) effect in manganite thin films are promising for high-field measurements due to their wide operating range, low magnetoresistance anisotropy, and ability to function without full saturation at extremely high magnetic fields. However, the long-term stability [...] Read more.
Magnetic sensors based on the colossal magnetoresistance (CMR) effect in manganite thin films are promising for high-field measurements due to their wide operating range, low magnetoresistance anisotropy, and ability to function without full saturation at extremely high magnetic fields. However, the long-term stability of their transport properties remains a key challenge for practical sensor applications. In this work, accelerated aging of nanostructured La1−xSrxMnyO3 thin films was investigated for two manganese compositions: nominally stoichiometric (y = 1.05) and Mn-excess (y = 1.15). The electrical resistivity and magnetoresistive properties strongly depended on the manganese content and substrate type. Accelerated aging was induced by annealing at 100 °C in an argon atmosphere, and the evolution of the transport properties was analyzed using a stretched-exponential relaxation model. The analysis of the extracted parameters indicated defect-related mechanisms governing transport stability. It was found that despite the increase in resistivity during thermal treatment, the magnetoresistance changes were insignificant. The results provide insights into the aging behavior of nonstoichiometric manganite films and offer guidance for optimizing stabilization procedures in CMR-based magnetic field sensors. Full article
(This article belongs to the Special Issue Recent Trends and Advances in Magnetic Sensors)
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7 pages, 927 KB  
Proceeding Paper
Smart Design of an Innovative Generation of Structural Resins Loaded with Carbon Nanostructured Forms
by Liberata Guadagno, Marialuigia Raimondo, Francesca Aliberti, Raffaele Longo, Michelina Catauro and Luigi Vertuccio
Eng. Proc. 2026, 133(1), 39; https://doi.org/10.3390/engproc2026133039 - 23 Apr 2026
Viewed by 286
Abstract
This study introduces advanced epoxy formulations incorporating carbon-based nanofillers, carbon nanotubes, nanofibers, and functionalized graphene. The epoxy matrix was optimized to lower moisture absorption and enhance multifunctional properties. A non-stoichiometric epoxy/hardener ratio reduced equilibrium water concentration (Ceq) by up to 30% [...] Read more.
This study introduces advanced epoxy formulations incorporating carbon-based nanofillers, carbon nanotubes, nanofibers, and functionalized graphene. The epoxy matrix was optimized to lower moisture absorption and enhance multifunctional properties. A non-stoichiometric epoxy/hardener ratio reduced equilibrium water concentration (Ceq) by up to 30% compared to unmodified epoxy, achieved by minimizing polar groups responsible for water bonding. These improvements benefit the aerospace, marine, and wind energy sectors. All nanofillers form a secondary phase with reduced glass transition temperature (Tg), but functionalized graphene performs best. Its self-assembled sheet architectures trap resin, limit water interaction, and create conductive pathways, improving strength, reducing moisture uptake, and achieving a low electrical percolation threshold (EPT). Full article
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23 pages, 3081 KB  
Article
Effects of Leaf Nutrients, Non-Structural Carbohydrates, and Microanatomical Structure on Biomass of Three Tree Species Under Drought Stress
by Zhaoqun Ma, Xi Zhang, Mengyun Lei, Nan Qin, Wenfang Ma, Lu Han and Haizhen Wang
Biology 2026, 15(8), 629; https://doi.org/10.3390/biology15080629 - 16 Apr 2026
Viewed by 420
Abstract
Drought stress profoundly affects plant growth and survival, but comparisons of integrated adaptive strategies across multiple tree species remain unclear. In this study, seedlings of Elaeagnus angustifolia (E. angustifolia), Populus euphratica (P. euphratica) and Xanthoceras sorbifolium (X. sorbifolium [...] Read more.
Drought stress profoundly affects plant growth and survival, but comparisons of integrated adaptive strategies across multiple tree species remain unclear. In this study, seedlings of Elaeagnus angustifolia (E. angustifolia), Populus euphratica (P. euphratica) and Xanthoceras sorbifolium (X. sorbifolium) were subjected to well-watered (CK), mild (T1), moderate (T2), and severe (T3) drought treatments. Leaf microanatomical traits, non-structural carbohydrates (NSCs), stoichiometric elements, biomass allocation, and key stress indicators were measured. The results showed that P. euphratica seedlings thickened leaves and vascular tissues and accumulated soluble sugars (SSs) and starch (ST) under T1–T2, but under T3, they prioritized root investment (root biomass +26.0%); their antioxidant enzymes were activated only under mild-to-moderate stress and declined under severe stress. E. angustifolia seedlings exhibited moderate leaf structural thickening, sharply increased root biomass (+97.2% under T3) while maintaining stem biomass, continuously elevated activities of superoxide dismutase (SOD) and peroxidase (POD) as well as osmoregulatory substances (soluble protein SP, proline Pro), and showed the lowest malondialdehyde (MDA) content; their leaf carbon (C), nitrogen (N), and phosphorus (P) contents decreased the least, and their stoichiometric ratios remained stable. In contrast, X. sorbifolium seedlings progressively reduced leaf thickness and vascular area, depleted NSC reserves, exhibited unstable antioxidant responses, showed a significant decrease in Pro under severe drought, accumulated the highest MDA, and had the lowest N/P ratio, indicating the strongest nitrogen limitation. These results demonstrate that E. angustifolia combines structural plasticity, efficient nutrient use, robust osmotic adjustment, and sustained antioxidant capacity, conferring the strongest drought tolerance; P. euphratica* shows moderate tolerance through transient structural and carbon investment but suffers under extreme drought; X. sorbifolium has the weakest drought tolerance. Full article
(This article belongs to the Special Issue Adaptation Mechanisms of Forest Trees to Abiotic Stress (2nd Edition))
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21 pages, 3195 KB  
Article
The Effect of Changing Exhaust Nozzle Geometry on Temperature Distribution and Emissions of Methane Diffusion Flame Under Air/Fuel Swirl Flows
by Salim Al Hamdani, Abdullah Al-Janabi, Sulaiman Al-Obidani, Ali Al-Hinaai and Ahmed Elwardany
Energies 2026, 19(8), 1889; https://doi.org/10.3390/en19081889 - 13 Apr 2026
Viewed by 693
Abstract
The performance of diffusion flame (DF) burners strongly depends on how effectively combustion gases mix and retain heat, yet the influence of exhaust nozzle geometry on these processes remains insufficiently characterized. This study examines how varying exhaust nozzle angle affects the thermal behavior [...] Read more.
The performance of diffusion flame (DF) burners strongly depends on how effectively combustion gases mix and retain heat, yet the influence of exhaust nozzle geometry on these processes remains insufficiently characterized. This study examines how varying exhaust nozzle angle affects the thermal behavior and emissions of a methane (CH4) diffusion flame under atmospheric conditions. A laboratory-scale burner with interchangeable exhaust nozzles (0°, 25°, and 50°) was operated at 1.8 kW using a fixed methane flow of 3 L/min and co-swirled air and fuel at 30°, across equivalence ratios (Φ) of 1.0, 0.7, and 0.5. Axial temperature measurements and exhaust gas analyses (Carbon dioxide (CO2) and Carbon monoxide (CO)) were conducted to assess mixing, heat retention, and post-flame oxidation. Results show that exhaust nozzle geometry notably influences flame position and heat distribution, producing non-monotonic temperature trends with equivalence ratio. The 25° nozzle angle yielded the highest near-stoichiometric downstream and flue temperatures, reaching about 204 °C at x = 45 cm and 277 °C in the flue, compared with 72 °C and 177 °C for the 0° nozzle. In contrast, the 50° nozzle produced more uniform downstream temperatures (about 150–160 °C) and the lowest CO emissions, approaching zero near Φ ≈ 1.0. These findings demonstrate that coordinated control of swirl and exhaust nozzle angle can enhance thermal response and CO reduction in diffusion flame burners without significantly changing CO2 levels. Full article
(This article belongs to the Special Issue Towards Cleaner and More Efficient Combustion)
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94 pages, 14084 KB  
Review
Review of Liquid Rocket Engine Injector Design and Technology
by Zhengda Li, Lionel Ganippa and Thanos Megaritis
Aerospace 2026, 13(4), 344; https://doi.org/10.3390/aerospace13040344 - 7 Apr 2026
Viewed by 2204
Abstract
The engine system requirements for different engine cycles significantly influence the design of the mixing head. A literature review of fuel-injection technology for hydrogen and methane is presented. The literature review aimed to answer proposed questions specific to the liquid rocket engine fuel [...] Read more.
The engine system requirements for different engine cycles significantly influence the design of the mixing head. A literature review of fuel-injection technology for hydrogen and methane is presented. The literature review aimed to answer proposed questions specific to the liquid rocket engine fuel injector design. The current review methodology accounts for the engine system effect. Thus, a comprehensive literature review of the working principles of startup-staged-combustion-cycle engines based on original patents is provided. At the end of the review, the research gaps and suggestions for further work are summarised. At high mass flow rate and injection pressure in the supercritical regime (>50 MPa), experience is limited to the staged-combustion cycle developed in Russia and the US. It is necessary to consider a fluid-dynamic heat transfer coupling study for the multi-injection element design in the supercritical state. Cryogenic spray atomisation experiments need to be designed with research significance in mind. It is still needed to study how the similarity of the spray flow field to the combustion performance affects a liquid rocket engine problem. Moreover, scaling stoichiometric mixing theory needs to be expanded to different injector types, such as tricoaxial and pintle injectors, to validate the correlation between the non-reactive mixing length and flame length. Full article
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