Grafting is a technique commonly used in horticulture to minimize damage from soil-borne diseases and bolster plants' ability to withstand stress, ultimately resulting in increased plant productivity. Cucurbit plants are frequently grafted for these purposes, and their seeds are widely used as nuts, food additives, and for medicinal properties worldwide. However, no information is available on the impact of grafting on the seed and oil yield and properties of medicinal pumpkins. This study is the first to investigate the effect of grafting on medicinal pumpkin (Cucurbita pepo var. styriaca) seeds' yield and oil properties. Commercial medicinal pumpkins were grafted onto five different rootstocks (C. pepo hybrids) including: 'code 11', 'code 36', 'code 45', 'code 42' and 'code 21') using three different grafting methods (Side grafting, Hole insertion grafting and cleft grafting). The results showed that the type of rootstock and grafting method significantly affected fruit yield, seed yield, oil yield, and oil qualities. The research revealed that there were no issues with graft incompatibility between the rootstock and medicinal pumpkins. Side-grafting was identified as the most successful method, and these plants were utilized in farm experiments. Furthermore, the rootstocks had a notably positive impact on the success rate, with code 42, code 45, and code 21 rootstocks demonstrating the highest percentage of successful grafts. Medicinal pumpkin (Cucurbita pepo var styriaca) plants grafted through the side grafting technique on code 45 hybrids have demonstrated the highest yield and optimal oil properties. Thus, these grafted plants are highly recommended for the commercial production of medicinal pumpkins.

Eco-friendly silk fibroin/poly(D,L-lactide-co-glycolide) (SF/PLGA) materials were successfully fabricated using a facile strategy. The materials were characterized by scanning electron micrograph (SEM), X-ray diffraction (XRD) and infrared spectra (IR). Systematic investigations were completed to examine the degradation rates in natural soil, cytocompatibility and thermostability of the materials. It is interesting to find that after SF was hybridized by PLGA, the thermostability and degradation rate increased. Meanwhile, the materials show good cytocompatibility. SEM, IR and XRD results reveal that there is hardly any interaction between SF and PLGA in the SF/PLGA material, and SF is physically mixed with PLGA. This study opens up a new horizon in the design and preparation of SF-based materials for promising applications in medical and biodegradable material fields.

Zinc-ion capacitors (ZICs) are viewed as a promising energy storage solution for portable electronics and biocompatible devices. Nevertheless, current ZICs technology faces challenges such as restricted specific capacitance, suboptimal cycling performance, and ongoing validation efforts regarding their biocompatibility. Herein, hierarchical porous carbon materials were prepared through a two-step carbonization-activation method using kapok fiber biomass as the precursor. The kapok fibers-based cathodes contain abundant micropores and mesopores, which provide abundant active sites for Zn2+ storage and optimize reaction kinetics. The ZICs demonstrate an ultra-high cycling life exceeding 240,000 cycles. Meanwhile, theoretical calculations verify that large micropores exhibit a reduced diffusion energy barrier for [Zn(H2O)6]2+, which accelerates [Zn(H2O)6]2+ adsorption/desorption and increases the available reversible capacitance. Furthermore, the ZICs exhibit excellent biodegradability in soil, simulated human body fluids and real seawater, and low cytotoxicity to human cells and minimal tissue damage in animal. This research presents a potential pathway for the advancement and verification of biocompatible ZICs, thereby contributing to their prospective practical utilization in biomedical and environmental field.

Plant-based macromolecules such as lignocellulosic fibers are one of the promising bio-resources to be utilized as reinforcement for developing sustainable composites. However, due to their hydrophilic nature and weak interfacial bonding with polymer matrices, these fibers are mostly incompatible with biopolymers. The current research endeavor explores the novel eco-friendly oxalic acid (C2H2O4. 2H2O) treatment of sisal fibers (SF) with different concentrations (2, 5, and 8 % (w:v)) and exposure duration (4, 8, and 12 h). Optimum treatment conditions were achieved through the single fiber strength testing of SFs. The tensile strength of the treated fiber with 8 % concentration and 12 h exposure duration (TSF/8/12) increased by approximately 60 % compared to untreated SF. Fourier transform infrared spectroscopy (FTIR), morphological observation, X-ray diffraction (XRD), and thermogravimetric analysis (TGA) of untreated and treated fibers confirmed that TSF/8/12 has better mechanical and crystallinity behavior than its counterparts. The thermal stability and maximum degradation temperature of the TSF/8/12 are 232 degrees C and 357 degrees C. Sustainable composites were fabricated by introducing the treated SFs (30 wt%) as reinforcement in a bio-based poly (butylene succinate) (bio PBS) matrix. The experimental evaluation of mechanical properties, thermal degradation behavior, and water absorption established that treated fiber-reinforced biocomposites (bio PBS/TSF/8/12) have strong interfacial bonding between constituents that resulted in better thermal stability and decreased water uptake than untreated sisal fiber (USF)based composites (bio PBS/USF). The results of the soil degradation confirmed that SFs expedite the rate of degradation of composites due to the increased availability of hydroxyl groups.

Adding graphene microflakes with excellent mechanical properties to asphalt materials can promote the development of sustainable transportation infrastructure. Recently, graphene oxide-modified asphalt has gained popularity due to its enhanced storage stability, ease of construction, and high-temperature stability. However, the modification mechanism of graphene oxide and polymer modifiers within asphalt remains unclear. This study aims to investigate the mechanism of action of aminated graphene oxide and styrene-butadiene-styrene (SBS) within asphalt and elucidate their influence on the properties of composite-modified asphalt. This research utilized X-ray diffraction (XRD), Fourier transform infrared spectroscopy (FTIR), dynamic shear rheometer (DSR), multiple stress creep recovery (MSCR), bending beam rheometer (BBR), and thermogravimetry analysis (TGA) to explore the performance of composite-modified asphalt and the modification mechanism of modifiers. X-ray diffraction and Fourier transform infrared spectroscopy showed that the modification effect was better, the surface wrinkles of modified graphene oxide increased, and the interlayer spacing expanded, which was favorable to its compatibility with asphalt. Conventional test and Brookfield viscosity revealed that composite-modified asphalt possessed favorable high-temperature resistance and plasticity compared to the original asphalt. Additionally, dynamic shear rheological and storage stability tests indicated that the addition of aminated graphene oxide not only improved the viscoelastic properties of asphalt but also enhanced the compatibility between various substances. Multiple stress creep recovery and bending beam rheometer tests measurements confirm that the composite-modified asphalt exhibits superior high-temperature rutting resistance and low-temperature crack resistance. Fluorescence microscopy analysis demonstrated the uniform distribution of the modifier and SBS within the asphalt, while thermogravimetry analysis revealed that composite-modified asphalt exhibited higher thermal stability compared to SBS-modified asphalt. This study holds significant importance in advancing the development and practical application of road modification materials.

The protein from black soldier fly larvae was used as a functional ingredient of a novel green nanofiber. Larvae protein powder (LP) was blended with biodegradable poly(epsilon-caprolactone) (PCL) and processed in an electrospinning machine using a coaxial feeding/mixing method to produce nanofibers approximately 100-350 nm in diameter. To improve the dispersion and interface bonding of various PCL/LP nanofiber components, a homemade compatibilizer, maleic anhydridegrafted poly(epsilon-caprolactone) (MPCL), was added to form MPCL/LP nanofibers. The structure, morphology, mechanical properties, water absorption, cytocompatibility, wound healing, and biodegradability of PCL/LP and MPCL/LP nanofiber mats were investigated. The results showed enhanced adhesion in the MPCL/LP nanofiber mats compared to PCL/LP nanofiber mats; additionally, the MPCL/LP nanofibers exhibited increases of approximately 0.7-2.2 MPa in breaking strength and 9.0-22.8 MPa in Young's modulus. Decomposition tests using a simulated body fluid revealed that the addition of LP enhanced the decomposition rate of both PCL/LP and MPCL/LP nanofiber mats and in vitro protein release. Cell proliferation and migration analysis indicated that PCL, MPCL, and their composites were biocompatible for fibroblast (FB) growth. Biodegradability was tested in a 30 day soil test. When the LP content was 20 wt%, the degradation rate exceeded 50%.

Planting concrete (PC) is a type of sustainable concrete. It remains challenging to prepare and design a PC by considering complex factors such as voidage and alkalinity. In this paper, preparation and mix design methods of PC are reviewed and compared, with particular emphasis on the influence of various factors on permeability, mechanical properties, durability, and plant compatibility. Alkali reduction measures, vegetation testing, and plant compatibility cannot be ignored in the design of PC. 25 similar to 30% voidage and 8-10 pH can ensure the durability of vegetation concrete, physiological characteristics of plants and fertilizer retention performance. In addition, the paper summarizes the application of PC in water purification, slope protection and green roof establishment. The cost and applicable conditions of different slope protection methods are further compared and analyzed. Finally, several essential areas that require further research efforts are suggested based on the current research results, including research direction and challenges of PC.

The railway transport system is a key factor supporting industrialization in all aspects of human activity. However, in order not to lose its importance, it must meet the challenge of modern civilization. The safety, reliability, and efficiency of railway transport, to a large degree, depend on using highly integrated electronics, which are very sensitive to various disturbances generated in the electric traction system and train or coming from the environment. One of the sources of electromagnetic disturbances are high-voltage (HV) power lines running close to the railway infrastructure. The purpose was to assess the electromagnetic impact of overhead HV transmission lines on buried signaling cables of the railway traffic control system crossbreeding with them. The levels of voltage induced in the cable under steady state and the earth fault in the HV line at various soil resistivity were estimated. A software tool based on a hybrid numerical method that combines circuit theory and electromagnetic field theory was used for computations. It was found that very high voltages may be induced in the signaling cables during earth faults in the HV lines, which may lead to serious interference or damage to the equipment. The results provide useful knowledge for implementing modern railway traffic control systems and protection measures.

This study investigates the potential of utilizing green chemically treated spent coffee grounds (SCGs) as micro biofiller reinforcement in Poly-3-hydroxybutyrate- co -3-hydroxyvalerate (PHBV) biopolymer composites. The aim is to assess the impact of varying SCG concentrations (1 %, 3 %, 5 %, and 7 %) on the functional, thermal, mechanical properties and biodegradability of the resulting composites with a PHBV matrix. The samples were produced through melt compounding using a twin-screw extruder and compression molding. The findings indicate successful dispersion and distribution of SCGs microfiller into PHBV. Chemical treatment of SCG microfiller enhanced the interfacial bonding between the SCG and PHBV, evidenced by higher water contact angles of the biopolymer composites. Field Emission Scanning Electron Microscopy (FE-SEM) confirmed the successful interaction of treated SCG microfiller, contributing to enhanced mechanical characteristics. A two-way ANOVA was conducted for statistical analysis. Mass losses observed after burying the materials in natural soil indicated that the composites degraded faster than the pure PHBV polymer suggesting that both composites are biodegradable, particularly at high levels of spent coffee grounds (SCG). Despite the possibility of agglomeration at higher concentrations, SCG incorporation resulted in improved functional properties, positioning the green biopolymer composite as a promising material for sustainable packaging and diverse applications.