Wheat Straw Research Articles

Effects of pyrolysis temperature on the photooxidation of water-soluble fraction of wheat straw biochar based on 21 ​T FT-ICR mass spectrometry

Biochar, formed through the pyrolysis or burning of organic wastes, has a complex chemical composition influenced by feedstock, pyrolysis temperature, and reaction conditions. Water-soluble, dissolved black carbon species released from biochar comprise one of the most photoreactive organic matter fractions. Photodegradation of these water-soluble species from wheat straw biochar, produced at different pyrolysis temperatures in laboratory microcosms, resulted in noticeable compositional differences. This study characterized water-soluble transformation products formed through the photodegradation of wheat straw biochar pyrolyzed at 300, 400, 500, or 600°C by electrospray ionization 21 ​T Fourier transform ion cyclotron resonance mass spectrometry (21T FT-ICR MS). We also evaluated global trends in the toxicity of these water-soluble fractions using MicroTox™ to assess the impacts of pyrolysis temperature. Additionally, we examined biochar surface morphology after photodegradation and observed minimal change after irradiation for 48 ​h, though the total yield of water-soluble biochar species varied with pyrolysis temperature. Trends in toxicity observed from MicroTox® analysis reveal that water-soluble photoproducts from biochar produced at 300°C and 900°C are nearly three times as toxic compared to dark controls. The ultrahigh resolving power of 21T FT-ICR MS allows for the separation of tens of thousands of highly oxidized, low-molecular-weight (<1 ​kDa) species, showing that photoproducts span a wider range of H/C and O/C ratios compared to their dark analogs. This study highlights the impacts of photodegradation on the molecular composition of water-soluble biochar species and underscores the influence of pyrolysis temperature on the quantity and composition of dissolved organic species.

Particle size of straw and gelation of pectin influence gastric mixing and emptying in pigs

Physicochemical properties of fibres can strongly impact gastric processes such as emptying and sieving. This study evaluated the influence of particle size of insoluble fibres, and gelation of soluble fibres when added to insoluble fibres, on gastric emptying of digesta phases from the proximal and distal stomach of pigs. Twenty-four boars (51.6 ± 4.90 kg) were assigned to one of four diets, containing either 150 g/kg coarse or finely milled wheat straw (median particle area of 5.4 vs. 0.3 mm2), or 270 g/kg wheat bran without or with the addition of 100 g/kg low-methylated pectin. Tracers were used to quantify the mean retention time (MRT) of digesta liquids (Co-EDTA), fine solids (TiO2), and fibrous particles (Chromium-mordanted fibres). For all diets, digesta pH was lower in the distal stomach than in the proximal stomach (-1.1 to 2.1 units; P < 0.05). In the proximal stomach, particle size reduction of straw tended to decrease digesta pH (-0.8 units; P = 0.072), reduced the MRT of fine solids (-117 min; P = 0.009) and the separation between fine solids and liquids (-88 min; P = 0.030). When particle size of straw was reduced, the MRT of liquids was no longer greater in the proximal stomach compared with the distal stomach (P > 0.10), while in both regions, the MRT of fibrous particles (-213 to 238 min; P < 0.05) and the difference between fibrous particles and fine solids were reduced (-96 to 181 min; P < 0.05). Accordingly, sieving of nutrients, such as starch and non-starch polysaccharides (NSP) was reduced. In the proximal stomach, the greater water holding capacity (WHC) and resistance to deformation conferred by the addition of pectin decreased the MRT of fine solids (-138 min; P = 0.003), and fibrous particles (-227 min; P < 0.001), reducing the difference between fine solids and liquids (-148 min; P < 0.001), and between fibrous particles and fine solids (-89 min; P < 0.001). In the distal stomach, pectin addition reduced the MRT of fibrous particles (-203 min; P = 0.007), and the difference between fibrous particles and fine solids (-154 min; P < 0.001). Concomitantly, sieving of nutrients across stomach regions was reduced. In conclusion, particle size reduction of straw and pectin addition accelerated the emptying of fine and coarse solids, and reduced sieving of digesta phases and nutrients in the proximal and distal stomach of pigs.

Thermal insulation materials based on eucalyptus bark fibres

The civil construction industry significantly contributes to global energy consumption, prompting a shift towards sustainable practices to mitigate environmental impacts throughout the building lifecycle. Traditional thermal insulation materials, such as polyurethane foam and mineral wool, are cost-effective but fail to meet environmental safety standards. In this context, plant-based materials have emerged as an eco-friendly alternative for thermal insulation, with agroforestry waste offering a sustainable raw material source. This waste is abundant and often improperly disposed of, thus utilizing it can reduce the environmental footprint of the agroforestry sector. This study focuses on developing thermal insulation plates using eucalyptus bark fibres, with some samples incorporating wheat straw. Various methods were employed: sodium silicate as a binder in some samples, while others used a binder-free method involving pulping bark in lye, and some included carbonised eucalyptus bark. The primary goal was to evaluate properties like thermal conductivity and moisture sorption. The electron microscope analysis provided insights into the microstructure of the fibres, explaining their insulation mechanisms. The thermal conductivity of the plates ranged from 0.036 to 0.059 W/(m·K) at a density of 80–220 kg/m3, influenced by the preparation processes (mechanical grinding, lye pulping, carbonization) and binder use. Eucalyptus bark fibre samples demonstrated low moisture sorption for plant-based materials, with 9.4–14.5 % at 60 % relative humidity and 21.6–38.5 % at 97 % relative humidity. Additionally, the samples showed high resistance to fungal growth when wet, suggesting good durability for thermal insulation applications. Overall, the study's results indicate that eucalyptus bark fibres hold significant promise as a sustainable raw material for producing thermal insulation, offering an environmentally friendly alternative to traditional materials while enhancing the durability and effectiveness of insulation in construction.

Fat composition in milk replacer modulates plasma cholesterol of dairy calves

This study evaluated the effect of feeding milk replacers (MR) formulated with alternative fat sources and containing different fat compositions on plasma cholesterol of dairy calves. Forty-five individually housed male Holstein calves (2.3 ± 0.82 d; mean ± SD) were blocked by arrival day and age. Within each block, calves were randomly assigned to one of 3 treatments: 1) an MR containing a fat blend with 65% rapeseed and 35% coconut fats (RC), 2) an MR containing 65% palm and 35% coconut fat (PC), and 3) an MR containing 65% lard and 35% dairy cream (LD). All MR were isoenergetic with 30% fat, 25% protein, and 36% lactose (DM basis). Calves were fed 6.0 L/d from d 1 to 5, 7.0 L/d from d 6 to 9, and 8.0 L/d from d 10 to 35 at 13.5% solids. Water and chopped wheat straw were available ad libitum from arrival onwards. Milk, water, and straw intakes were recorded daily. Blood was sampled and BW was measured at arrival and weekly thereafter at 1300 h. Fecal scores were recorded daily after the morning meal. Growth and intakes did not differ among treatments. Plasma total cholesterol, high-density lipoprotein (HDL)-cholesterol, and low-density lipoprotein (LDL)-cholesterol concentrations were higher in calves fed RC than PC and LD, and higher in calves fed PC than LD. Additionally, plasma TG was greater in calves fed PC than LD at wk 2 after arrival, while calves fed RC did not differ from the other treatments. The proportion of abnormal fecal scores were reduced in calves fed RC in wk 2. Including palm and rapeseed fats in the MR did not affect growth but increased plasma total cholesterol.

Design and experimental study of solar-driven biomass gasification based on direct irradiation solar thermochemical reactor

Solar-driven biomass steam gasification is a promising technology to produce H2-rich syngas, meanwhile achieve flexible storage of renewable energy. However, the solar gasification application also faces numerous challenges, due to its involved complex chemical reaction characteristics and the inherent the multi-physics energy conversion processes. This work designs a novel direct irradiation solar gasification reactor, with the improved optical acceptance structure and reasonable test module, and the wheat straw particle is selected as experimental sample. Employing a 9 kWe high flux solar simulator, the maximum temperature of reaction bed in this prototype reactor reaches to 1260 °C, with the average solar flux of 1171.3 kW/m2. With adjustable radiation flux as experiment factor, under the highest total radiation of 3.35 kW, the molar fraction of H2 in the produced syngas is 47.1 % with the energy upgrade factor of 1.15, and the cellulose component completes decomposition. Increasing the mass flow rate of steam reduces the syngas output while raising the H2/CO ratio of the syngas. In addition, smaller biomass particle size facilitates the reaction, thereby improving the conversion efficiency of direct irradiation gasification. The investigation results provide a meaningful reference for the efficient utilization of abundant solar and biomass energy.

Enhancing oyster mushroom cultivation by chickpea and wheat straw substrate for sustainable agriculture

This study aimed to explore the potential utilization of agro-lignocellulosic waste materials for oyster mushroom cultivation, addressing the challenge of managing waste associated with these materials. Various combinations of Chickpea Straw (CS) and Wheat Straw (WS) at different ratios-100% CS, 75% CS + 25% WS, 50% CS + 50% WS, 25% CS + 75% WS, and 100% WS-were investigated as substrates for mushroom cultivation. The experiment followed a ccompletely rrandomised design with four replications, monitoring developmental phases, yield, and biological efficiency (BE). Results indicated that using 100% WS as a substrate resulted in the fastest mycelium growth (spawn run), completing in an average of 14.50 days, 17.20 days from spawning to pinhead formation, and 20.60 days to first harvest, with the highest number of fruiting bodies produced. Chickpea straw contributed to the highest stipe width (1.52 cm), while WS 100% had the highest average yield (997.28 g) and BE (99.73%). A mixture of 75% CS and 25% WS showed promising results in terms of fruiting bodies, yield, and BE after 100% WS. Consequently, the study recommends the use of these substrates to optimize Pleurotus ostreatus cultivation yield.

Effect of Humic Acids Extracted From Different Organic Sources and Inoculation of Bacillus Subtilis or Aspergillus Niger in Alkaline Phosphatase Activity in Calcareous Soil

Humic acids have received a large attention of researching and development as amendments for poor fertility conditions and deteriorating physical properties, since the process of extracting is an easy common process to implement, as well as dilution of these acids with water enables to be used at economically acceptable levels over large areas. It is necessary to notice that the properties of these acids depending on the organic source and the concentration added to the soil.A laboratory experiment was conducted at the department of soil Sciences and water resources, collage of Agriculture ,University of Basrah ,Iraq to demonstrate the effect of humic acids extracted from different sources and inoculation with Bacillus subtilis or Aspergillus niger on alkaline phosphatase activity in calcareous soil calcareous, southern Iraq. Humic acids extracted from wheat straw, alfalfa leaves, goat manure, and poultry manure which composted previously . Humic acid levels were 0, 25 and 50 L ha-1 .The soil also inoculated with Bacillus subtilis or Aspergillus niger, then samples were incubated at 28±2°C. After 7 or 30 days of incubation the activity of alkaline phosphatase was estimated . Enzyme phosphatase activity was increased in soils treated with humic acid as compared to control with highest activity at Poultry manure (391.54 µg p-nitrophenol gm-1 soil.1h-1).The results also indicated that increasing the level of humic acid significantly increased enzyme activity. For soil treated with Bacillus subtilis and Aspergillus niger , phosphatase activity increased-as compared to control with a higher activity at Bacilluas subtilis (373.1 µg p-nitrophenol gm-1 soil.1h-1).

Влияние предварительной биоконверсии пшеничной соломы в модельной природоподобной системе на продуктивность растений

Studies focused on maintaining high productivity and stability of artificial ecosystems that reproduce the processes of natural cenoses are relevant and interesting. It seems to be effective to include decomposers, detritivores and vegetative waste in model systems aimed at obtaining products. The use of earthworms as detritivores is promising because they utilize the organic matter as well as enrich the substrates with microflora including those with antagonistic and growth-stimulating activities. The aim of this study was to assess the prospects of preliminary bioconversion of wheat straw by basidiomycetes (Lentinus tigrinus and Pleurotus ostreatus) to increase the productivity of lettuce plants. The work was carried out in laboratory conditions with model systems consisting of a substrate (peat, cattle manure and wheat straw with and without bioconversion), earthworms (Eisenia fetida) and lettuce (Lactuca sativa var. crispa cultivar Credo). The leaf area, the weight of each plant (wet and dry), the productivity of lettuce plants, and the content of the main biogenic elements in the plant tissue and substrate were evaluated. The number and weight of adult worms at the beginning and at the end of the experiment, and the number of juvenile worms at the end of the experiment, the number of cocoons, as well as coprolite weight and yield were considered. A significant phytotoxic effect when straw was added into the substrate was found. The addition of straw processed by basidiomycetes (10%) in the substrate had a favorable effect on the earthworm population. Growing lettuce on substrates with bioconverted straw and with the earthworm introduction increases the content of major macronutrients (nitrogen, phosphorus, potassium) in plants. The introduction of earthworms contributed to a significant decrease in the phytotoxicity of substrates. Thus, it is possible to recommend the inclusion of fungiculture wastes (such as substrates after fruiting bodies obtaining) in green crop production systems together with the introduction of earthworms into substrates.

Exploring the biochemical and productivity implications of incorporating mustard cake in Hypsizygus ulmarius (Bull.) cultivation

The study aimed to evaluate the biological efficiency and nutritional composition of Hypsizygus ulmarius (Bull.), an edible and medicinal mushroom species often overlooked by Indian farmers. The mushrooms were cultivated on wheat husk as the control substrate from October to February. The substrate was enriched with mustard cake (M) at concentrations of 10 % (M500), 20 % (M1000) and 30 % (M1500) by dry weight to assess the impact on yield. The growth parameters, including the size and weight of fruiting bodies from each type of substrate were recorded. The control substrate, consisting of wheat straw alone, required the shortest period for mycelium growth at 33.125 ± 0.99 days, while wheat straw supplemented with 30 % mustard cake (M1500) took the longest time at 46.6 ± 1.5 days. However, the M1000 substrate (20 % mustard cake) had the shortest time span for pin head formation, taking 46 ± 1.41days and for maturation to fully grown fruiting bodies, requiring 50.25 ± 2.12 days. The M1000 substrate also produced the highest yield of 5533.2 kg with the greatest biological efficiency of 92.2 %, but comparatively least values were obtained in M1500, with a yield of 2088.28 kg and a biological efficiency of 51.28 %. The highest total carbohydrate content was found in M500 (10 % mustard cake), at 71.91 %, along with a fiber content of 13.19 %. The highest protein (38.06 %) and fats (2.73 %) contents were observed in M1500. The results of this study suggest that mustard cake can be used as an effective supplement to enhance the nutritional content, biological efficiency and productivity of Hypsizygus ulmarius.

Structure and Magnetic Properties of Fe&lt;sub&gt;3&lt;/sub&gt;O&lt;sub&gt;4&lt;/sub&gt;/C Composites Synthesized from Wheat Straw

The porous structure and magnetic properties of nanostructured Fe3O4/C composites based on wheat straw were investigated in this work. The synthesis was carried out by a one- and two-step method using FeCl3 and ZnCl2 as activating agents. X-ray diffraction methods have shown the presence of an additional phase of magnetite Fe3O4 in both synthesized composites, along with the amorphous carbon phase. Magnetic measurements have shown that the composite synthesized in one step has better magnetic properties, in particular, a higher specific saturation magnetisation. However, the samples of the composite synthesized in two steps are characterised by a higher content of micropores and mesopores, which causes an increase in the specific surface area to 884 m2/g compared to 405 m2/g for the samples synthesized in one step. Based on the dependence of the coercive force on the particle diameter in Fe3O4 dispersions, it was found that the average size of the magnetite particles is ~25 nm for both synthesized magnetoresponsive composites.

Exploring Water Absorption Behaviors on Mechanical Properties of Wheat Straw-Glass Fiber Hybrid Composites for Sustainable Engineering Solutions

The study explores the enhancement of epoxy composite performance by adding glass fiber and wheat straw, revealing improved tensile strength and hardness compared to unreinforced epoxy. Using a hand-layup procedure, glass fibers and wheat straw are incorporated unidirectionally into an epoxy resin matrix. This study aims to explore how different fiber volume fractions and moisture absorption over two months affect the tensile strength and hardness of hybrid composites. The tensile strength and hardness of weathered specimens are found to be lower values than those of raw samples because of the degradation of the structural integrity of the fibers during water absorption. After being exposed to water, the tensile strength was 20 wt. % fiber composite sample was reduced by roughly 32.43 %. A marginal decline in hardness of 5.63% occurred for 20 wt. % hybrid composite. The morphology of the composites after the tensile test and the interactions between the fibers and the epoxy matrix in the as-cast and weathered samples were investigated using SEM. Perfect fiber-matrix bonding was apparent in as-cast composites. However, fiber swellings and de-bonding in the fiber matrix due to voids and moisture absorption were observed in weathered specimens, which reduced the tensile strength and hardness.

Effect of biochars on the concentration of plant-available elements in the soil

To solve environmental problems and reduce economic costs, it is necessary to improve mineral fertilizer application systems by developing and introducing new technologies, including the use of biochars. Due to the lack of effective monitoring of soil changes, it is difficult to adjust fertilizer application rates. This determines the importance of information on the elemental composition of biochar ameliorants used to reduce the mobility of heavy metals in the soil. The use of biochar for remediation of contaminated soils is based on its ability to immobilize heavy metals and organic pollutants. In this work biochars were used, obtained by slow pyrolysis of organic materials of different types: pine sawdust, cattle manure, wheat straw, pine nut shells and brewer's grains. The effect of biochars (biochar application at a dose of 10 t ha−1) on the concentration of 13 elements (C, N, K, P, Mg, Ca, Fe, Mn, Pb, Ni, Cr, Cd, Co) in the soil was analyzed. The data collected after growing of spring wheat (Triticum aestivum L.) on the sod-podzolic soils were analyzed. It has been established that the heavy metals concentrations in the studied soils reclaimed with biochars are significantly lower than the maximum allowable concentrations for soils (MAC). The content of lead (Pb) in soils treated with biochars is 9 or more times lower than the MAC level, and biochar, produced from manure, significantly reduces the concentration of this metal in the soil.

Development of a CFD-DEM Model for a 1 MWth Chemical Looping Gasification Pilot Plant Using Biogenic Residues as Feedstock.

Chemical looping gasification (CLG) is a novel dual fluidized bed gasification process that enables the conversion of solid feedstocks to a nitrogen-free syngas through in situ air separation, avoiding a costly air separation unit. While there have been recent advances in experimental studies, modeling of CLG is almost exclusively restricted to lab-scale units or 1D models. In this study, a 3D CFD-DEM model of a 1 MWth fuel reactor for the conversion of solid biomass was developed. Due to the high computational demand of the DEM method, a coarse-grained approach was used in combination with a simplified reaction network. The hydrodynamics were modeled with an EMMS drag model. Simulations were conducted for two woody biomasses and wheat straw based on experimental data of a 1 MWth CLG reactor. The model was able to predict the pressure profile over the reactor accurately, with a mean error below 10%. Carbon conversion and oxygen carrier oxidation were in good agreement with the experimental data with mean deviations below 5%, while reasonable values below 8 mol % mean error were achieved for the gas composition. Discrepancies in the gas composition as well as temperature profile indicate that further work is needed in the pyrolysis step of the model.

Microbial Community and Functions Depending on Tillage and Straw Returning Management: Consequences for Soil Health and Ecosystem Services

ABSTRACTTillage and straw returning are promising practices to improve soil quality, especially because of the unclear controlling effects on microbial communities and functions. A 5‐year field experiment in a winter wheat‐summer maize cropping system was implemented in the North China Plain to address this research gap. Management practices were deep tillage, rotary tillage, and no‐tillage, each with either wheat only or both wheat and maize straw returning. Shotgun metagenomic sequencing was performed to investigate the microbial community, diversity, co‐occurrence network, and function in the topsoil (0–20 cm). The associations between soil physiochemical properties and microbial community characteristics were also evaluated. Rotary tillage with only wheat straw returning (RTS) significantly increased Shannon's diversity index by 0.24%–1.71% compared to other treatments. No‐tillage with only wheat straw returning (NTS) showed the most stable microbial network with the highest betweenness centrality (199.09), average path distance (2.31), and modularity (0.50). NTS had the highest relative abundance of microbial carbon (C), nitrogen (N) metabolisms, and C fixation pathways. Among deep tillage practices, both wheat and maize straw returning (DTD) were more beneficial to the stability of microbial networks than only wheat straw returning (DTS), yet without improvement in microbial diversity and function. In conclusion, microbial community and function are practical predictors of variations in soil nutrient availability, and pH value in response to different tillage and residue management practices. In particular, our study provides a basis for the development of a sustainable crop residue management system.

In-Depth Study on Synergic Interactions and Thermo-Kinetic Analysis of (Wheat Straw and Woody Sawdust) Biomass Co-Pyrolysis over Mussel Shell-Derived CaO Catalyst Using Coats–Redfern Method

The behavior of wheat straw biomass (WS), woody sawdust biomass (WB), and their blends during catalytic co-pyrolysis are analyzed in the presence of CaO catalyst, which is obtained from the calcination of mussel shells. Synergy analysis of blends and pure materials is measured by studying the difference between theoretical and experimental values of wt.%/min, (RL%), and (WL%), which correspond to maximum weight loss rate, residue left, and weight loss, respectively. The Coats–Redfern method is utilized for evaluating the thermo-kinetic properties. The chemical reaction order model F1 is the best model that describes the Ea of 60.05 kJ/mol and ∆H, ∆G, and ∆S values of 55.03 kJ/mol, 162.26 kJ/mol, and −0.18 kJ/mol.K, respectively, for the optimum blend 80WS−20WB, reducing the thermo-kinetic properties. Model D3 showed better results for the Ea, ∆H, ∆G, and ∆S for the 5% CaO blend, which certified the viability of co-pyrolysis of WS and WB, while DTG indicated that exothermic and endothermic reactions occur together.

Potential of Wheat Straw for Biogas Production by Anaerobic Digestion in South Africa: A Review

Wheat straw (WS) is a promising substrate for biogas production by anaerobic digestion (AD) due to its high carbohydrate content. An estimated 0.603 million t yr−1 of WS are generated from wheat production systems in South Africa. This is equivalent to an energy potential of 11 PJ. Despite this, WS is still undervalued as a bioenergy resource in South Africa due to its structural complexity and low nitrogen content. WS disposal methods, such as use in livestock bedding, burning and burying into the soil, inter alia, are not sustainable and may contribute to global warming and climate change. The commercialization of the AD of WS needs to be further developed and promoted. Pre-treatment (i.e., physical, chemical, biological and hybrid methods) and anaerobic co-digestion (AcoD) are novel strategies that can support the conversion of WS into biogas and other value-added products. Current and future research should focus on optimizing pre-treatment and AcoD conditions towards industrialization of WS into valuable products. This paper focuses on the potential use of WS for biogas production in South Africa. The aim is to create information that will promote research and development, and encourage policy makers and stakeholders to participate and invest in WS biogas technology. Were WS biogas technology fully adopted, we believe that it would alleviate energy insecurity and environmental degradation, and sustain the livelihoods of citizens in South Africa.

Catalytic pyrolysis of wheat straw based on dual catalyst CaO/ZSM-5 with acid washing and torrefaction pretreatment to enhance aromatic yield in bio-oils

In this paper, the catalytic pyrolysis integrating combined pretreatment (acid washing and torrefaction) and dual catalysts was adopted to improve the quality of bio-oil and the selectivity of aromatic hydrocarbons. Combined pretreatment is a highly effective method to improve the quality of biomass feedstock. It was capable of the removal of alkali and alkaline earth metals from wheat straw, with a K removal rate of 97.79 %. Under the combined pretreatment, the aromatic hydrocarbon content in bio-oil increased to 68.8 % using the ZSM-5 catalyst alone. Compared with ZSM-5, CaO could remove part of the oxygenated functional groups and had a better acid removal effect, but the aromatic hydrocarbon yield was low to 7.95 %. After combined pretreatment using simulated aqueous phase bio-oil for acid washing, catalytic pyrolysis using CaO/ZSM-5 dual catalysts greatly enhanced the quality of the bio-oil. The oxygenated compounds content was reduced to 17.58 %, and the total hydrocarbon yield was increased to 82.42 %, especially the aromatic hydrocarbons yield was increased to 79.91 %, of which the monocyclic aromatic hydrocarbons were as high as 68.38 %, and the benzene, toluene, and xylene content reaching 49.39 %. Thus, integrating dual catalysts (CaO/ZSM-5) with combined pretreatment can effectively increase the aromatic yield for producing high-quality bio-oil.

Multiple Goals for Biomass Residues in Circular Bioeconomies? Assessing Circularities and Carbon Footprints of Residue-Based Products

AbstractBiomass residues are often considered key in a reorientation towards circular bioeconomies, both by returning organic matter and nutrients to soils and by expanding the feedstock base for fossil-free products. Different indicators are available to assess progress towards circularity, but many available indicators and assessments seem to focus on product or material circularity, and lack in coverage of ecological or nutrient circularity. This study therefore applies both material and nutrient circularity indicators to two cases of residual biomass’ valorisation: plastics production from wheat straw, and jet fuel production from animal by-products, in order to better understand the potential of the different types of indicators to assess the circularities of bio-based products.Both the studied production systems achieve approximately 50% material circularity in the base case, but the scores are significantly lower when upstream processes such as cultivation and animal husbandry are included. In the plastics case, the nutrient circularity scores are consistently lower than material circularity scores. The contribution to circularity from composting and recycling of different streams can be interpreted differently following the different types of circularities and, in addition, considering the potential climate impact of different strategies. This study shows that a combination of methods and indicators can shed light on different types of circularities and goals, but also that a wider discussion on what circularity may entail for biomass and biomass residues, and how it can be measured, is needed to develop useful indicators for bio-based circularity and circular bioeconomies.

Green synthesis of zinc oxide nanoparticles for the industrial biofortification of (Pleurotus pulmonarius) mushrooms

Zinc malnutrition is major health problem in children and women of reproductive age (WRA) in developing countries. This study aimed to find nutritionally balanced food at an affordable cost. For this purpose, Pleurotus pulmonarius (Mushroom) is fortified with zinc oxide nano particles (ZnO-NPs) synthesized from Nigella sativa seed extract. ZnO-NPs were characterized using UV visible and FTIR Spectroscopy, SEM-EDX, XRD, PSA and Zeta potentials. ZnO-NPs were sprayed in different concentrations on substrate used for the cultivation of P. pulmonarius. Cultivated mushroom fruiting bodies were dried and powdered. Bio absorption of zinc was calculated using atomic absorption spectroscopy. Zinc absorption increased by enhancing the number of nano particles spraying on lingo-cellulosic substrate. The controlled bag had 2.27 ± 0.00 mg of zinc content per 2 g of mushroom powder. The minimum amount (3.46 ± 0.16 mg/2 g of mushroom) of zinc micronutrient was absorbed by the bag having 50 mg spray of ZnO-NPs per Kg of the wheat straw. Maximum amount of bio accumulation was done by bag having 5000 mg spray of ZnO-NPs (10.46 ± 0.08 mg/2 g of mushrooms powder). Zinc fortification had a significant (p < 0.05) effect on the uptake of zinc by fruiting bodies. ZnO-NPs at the concentration of 200 mg per kilogram of substrate gave optimized value of biological efficiency [B.E] (40.2 % ± 0.25), while B.E decreased with the increase in ZnO-NPs spray due to bio accumulation of zinc with increased concentration of ZnO-NPs spray.

Impact of polyvinyl alcohol application and wheat straw mulching on soil loss and infiltration rate in semi-arid tropics

A study was conducted at Punjab Agricultural University, Ludhiana, Punjab, with the aim of monitoring soil loss and infiltration rate in loamy sand soil. The study focused on the effects of applying polyvinyl alcohol (PVA) and mulch under simulated rainfall conditions. The experimental setup involved testing three levels of PVA (0.5%, 0.75%, and 1.0%), one level of wheat-straw mulch (600 g/m2), and a Control treatment (untreated soil). Each of these treatments was replicated four times. The lowest soil loss (20.9 g/m2) was recorded under the 1.0% PVA treatment, while the highest (120.1 g/m2) was seen under the 0.5% PVA treatment. The 1.0% PVA treatment showed a significant reduction in soil loss compared to the 0.5% PVA, 0.75% PVA, mulch, and Control treatments, with reductions of approximately 82.6%, 45.1%, 81.2%, and 89.6%, respectively. Regarding infiltration rates, the Control treatment exhibited the lowest rate (2.4 cm/h), while the 1.0% PVA treatment displayed the highest rate (9.6 cm/h). Additionally, the use of mulch led to a 44.7% reduction in soil loss compared to the treatment without mulch, likely due to the mitigated impact of raindrops. The infiltration rate was significantly higher (4.8 cm/h) under the mulched treatment compared to the unmulched treatment (2.4 cm/h). Overall, the application of PVA and mulch resulted in a drastic reduction in soil loss, likely attributable to the enhanced stability of soil aggregates, improved infiltration rate, and reduced runoff.