Utilization Of Waste Resources Research Articles

Selective recovery of lithium from used lithium-ion batteries spent via grain boundary reconstruction reaction

The demand for lithium resources on the market has increased significantly as a result of the emergence and advancement of the new energy industry. However, improper handling leads to the generation of large amounts of hazardous waste, including spent lithium batteries. The recovery of lithium from these batteries has dual importance in protecting the environment and effectively recycling secondary resources. Herein, a green process for selective extraction of lithium from discarded lithium batteries was proposed. Sodium thiosulfate mixed with waste lithium battery powder was calcined at 600 °C for 90 min, when the molar ratio of sodium thiosulfate to lithium in the raw material was 0.5, and over 99 % lithium can be selectively preferentially extracted. During the roasting process, lithium in the raw materials was converted into water-soluble LiNaSO4, and transition metal oxides after calcination existed as water-insoluble oxides or sulfides, and the goal of preferential lithium extraction can be achieved by simple immersion in water. Lithium-containing leachate was purified by cerium carbonate and NaOH. After removing a small amount of Ni, Co, Mn, Al, Ca, and F impurities, the prepared lithium carbonate had a purity greater than 99.50 %, which met the standard of battery-grade lithium carbonate. This study introduces an approach to the selective extraction of lithium from lithium-containing solid waste, which effectively simplifies the recycling separation procedure and provides support for resource utilization of lithium-containing solid waste.

Hybrid XGB model for predicting unconfined compressive strength of solid waste-cement-stabilized cohesive soil

The utilization of cement has been found to have negative environmental impacts. In order to reduce the quantity of cement used and improve the mechanical properties of solid waste-cement-stabilized cohesive soil, the incorporation of solid waste as additives has been investigated. Unconfined compressive strength is a crucial parameter in geotechnical engineering. However, existing empirical formulas have limited accuracy and applicability when it comes to the unconfined compressive strength of solid waste-cement-stabilized cohesive soil. The machine learning model can be used to provide accurate and comprehensive predictions by considering the nonlinear relationships between independent and dependent variables. This study aims to propose a machine learning model tuned by optimization algorithms with high generalization performance in accurately predicting the unconfined compressive strength. Firstly, a database containing 474 specimens was developed. Secondly, eight machine learning models were established, composed five single models and three hybrid models, to train and test the database. Six performance indicators were employed to evaluate the generalization ability of these models. Finally, the optimal model was selected for analysis of the importance of the feature variables using shapley additive explanations, which were compared with those of the existing empirical model. The research findings indicated that, the extreme gradient boosting model tuned with tree-structured parzen estimators exhibited the highest predictive accuracy and generalization ability. The curing age, cement content, plastic limit, and water content were identified as the most critical factors influencing the unconfined compressive strength. Among the chemical components in solid waste, the aluminum oxide content and silicon dioxide content were found to significantly influence the unconfined compressive strength, while the impact of calcium oxide content was relatively minor. Furthermore, the optimal solid waste content was found to be around 10 %. This study made a significant contribution to the effective utilization of waste resources in the context of sustainable construction practices.

Oyster shell facilitates the green production of nitrogen-doped porous biochar from macroalgae: a case study for removing atrazine from water

Low-cost and green preparation of efficient sorbents is critical to the removal of organic contaminants during water treatment. In this study, the co-pyrolysis of macroalgae and oyster shell was designed to synthesize nitrogen-doped porous biochars for sorption removal of atrazine from water. Oyster shell played a significant role in opening pores in macroalgae-derived biochars, resulting in the surface area of the macroalgae (Enteromorpha prolifera and Ulva lactuca) and oyster shell co-pyrolyzed carbonaceous as high as 1501.80 m2 g−1 and 1067.18 m2 g−1, the pore volume reached 1.04 cm3 g−1 and 0.93 cm3 g−1, and O/C decreased to 0.09 and 0.08, respectively. The sorption capacity of atrazine to nitrogen-doped porous biochars (the Enteromorpha prolifera, Ulva lactuca and oyster shell co-pyrolyzed carbonaceous) reached 312.06 mg g−1 and 340.52 mg g−1. Pore-filling, hydrogen bonding, π-π or p-π stacking and electrostatic interaction dominated the multilayer sorption process. Moreover, the nitrogen-doped porous biochars showed great performance in cyclic reusability, and the Enteromorpha prolifera, Ulva lactuca and oyster shell co-pyrolyzed carbonaceous sorption capacity still reached 246.13 mg g−1 and 255.97 mg g−1, respectively. Thus, this study suggested that it is feasible and efficient to remove organic contaminants with the nitrogen-doped porous biochars co-pyrolyzed from macroalgae and oyster shell, providing a potential green resource utilization of aquatic wastes for environmental remediation.Graphical

Mechanical properties and microscopic mechanism of solid waste based binder solidified stone waste

The stone waste generated by stone industry occupy land resources, cause safety hazards and need to be efficiently resourcefully utilized. In this study, the CGF solid waste based binder (abbreviated as CGF) with calcium carbide residue (CCR), ground granulated blast furnace slag (GGBS), and fly ash (FA) as components was developed to solidify the stone waste. Through “treating waste with waste”, the resource utilization of solid waste was realized. The mechanical properties and reaction mechanism of CGF solidified stone waste were investigated through unconfined compressive strength (UCS), XRD, and SEM–EDS tests. The results show that CGF has the better solidify effect on stone waste, and its strength meets the requirements of the road base material standards. Compared to cement, the CGF solidified stone waste existed higher UCS at both 7 and 28 d of curing. The UCS of CGF solidified stone waste reaches 2.93 and 4.42 MPa under curing of 7 and 28 d at 5% binder content, which is 1.61 and 1.37 times higher that of P.O. 42.5 cement. Furthermore, the primary mineral-based stone wastes will not react with the binder, and the CGF generates gelling products such as C-S–H C-A-H, and C-A-S–H through alkali-activated reactions between the components of CGF. These gelling products enhance the UCS of solidified stone wastes through cementing and filling effects. The findings provide a feasible approach with low-carbon emission and low-cost for resourceful utilization of stone wastes.

The Role of Precision Agriculture, Climate-Smart Farming, and Sustainable Supply Chain Management in Boosting Agricultural Productivity in 2024

This study explores the role of precision agriculture, climate-smart farming, and sustainable supply chain management in boosting agricultural productivity in 2024. The primary objective is to qualitatively analyze the literature to understand how these innovative practices contribute to enhancing agricultural productivity and sustainability. The research employs a qualitative literature review methodology, synthesizing findings from academic articles, industry reports, case studies, and empirical studies to provide a comprehensive overview of the current state of knowledge in this field. The literature review methodology involves systematically collecting and analyzing scholarly sources that discuss various aspects of precision agriculture, climate-smart farming, and sustainable supply chain management. The study categorizes the literature into key themes, such as the technological advancements in precision agriculture, the principles and practices of climate-smart farming, and the impact of sustainable supply chain management on agricultural productivity and sustainability. Thematic analysis is used to identify patterns and trends in how these practices interact to influence agricultural outcomes. The findings indicate that precision agriculture, through the use of advanced technologies like GPS, IoT, and AI, enables farmers to optimize field-level management regarding crop farming. This leads to increased yield, reduced waste, and better resource utilization. Climate-smart farming practices, including crop diversification, improved irrigation techniques, and soil health management, are essential for adapting to climate change and mitigating its impacts on agriculture. Sustainable supply chain management ensures that agricultural products are produced, processed, and distributed in ways that minimize environmental impact and enhance economic viability.

Study on impact resistance performance of MSWIFA-based low-carbon fiber-reinforced concrete

The accumulation of carbide slag (CS), red mud (RM), and municipal solid waste incineration fly ash (MSWIFA) has led to significant environmental pollution issues, necessitating urgent resource utilization. Building upon the previously developed CS-MSWIFA synergistic activation RM-slag cementitious system, this study aims to further incorporate iron tailings sand and polypropylene fibers to prepare fiber-reinforced concrete. The systematic investigation focuses on the influence of cementitious material types, aggregate types, fiber shapes, lengths, and dosages on the impact resistance of concrete. Furthermore, an impact damage evolution equation and life prediction model were developed based on the two-parameter Weibull distribution. Results indicate that the type of cementitious material and aggregate has minimal influence on the impact resistance of concrete, while the addition of fibers significantly enhances its impact resistance, shifting the failure mode from brittle to ductile. Mesh polypropylene fibers with a length of 12 mm and a volume dosage of 1.0 % demonstrate excellent impact resistance, with initial and final crack numbers reaching 78 and 105, respectively. This represents an increase of 136.4 % and 200.0 % compared to the control concrete without fibers. The findings of this study offer new avenues for the resource utilization of solid waste and provide theoretical foundations and technical support for the potential application of solid waste based fiber-reinforced concrete in structural engineering.

Optimizing tomato waste hydrolysate for enhanced fucoxanthin biosynthesis in mixotrophic cultivation of Isochrysis galbana

Vegetable waste, rich in bioactive compounds, offers a promising resource for producing value-added products. This study explored the use of tomato waste, containing glucose (40 mg/g), lycopene (95.12 μg/g), and β-carotene (24.31 μg/g), for cultivating fucoxanthin-rich Isochrysis galbana. Water-soluble lycopene (2.0 μg/mL) and β-carotene (0.4 μg/mL) effectively upregulated key carotenoid synthesis genes and boosted cell growth and fucoxanthin production (3.64 and 3.60 pg/cell, respectively) within 10 days in a mixotrophic culture. Optimized tomato waste hydrolysate achieved a high cell density of 1.21 × 107 cells/mL, 2.13 g/L biomass, and 21.02 mg/g fucoxanthin. This study highlights the potential of combining tomato waste with microalgae for a novel and innovative approach towards waste management and resource utilization.

Stepwise dechlorination and co-pyrolysis of poplar wood with dechlorinated polyvinyl chloride: Synergistic effect and products distribution

With the combination of stepwise dechlorination and co-pyrolysis techniques, this study conducted polyvinyl chloride (PVC) dechlorination experiments and co-pyrolysis experiments of poplar wood (PW) with dechlorinated polyvinyl chloride (DPVC) by thermogravimetric analysis and a fixed bed reactor. Stepwise pyrolysis effectively removed Cl from PVC with a dechlorination efficiency of 99.84 % at 360 °C for 30 min. Thermogravimetric tests and thermokinetic variables were employed to describe the co-pyrolysis process's thermodynamic behavior, where co-pyrolysis significantly diminished the activation energy of the initial pyrolysis stage (9.65–21.62 kJ/mol) and increased the reaction rate (0.02–0.09 %/°C). The synergistic effect of co-pyrolysis enhanced the yield and quality of liquid oil and reduced the solid residue rate, with the maximum change in solid residue rate (−2.36 wt%) occurring at PW:DPVC = 3:7. The optimal conditions for the synergistic effect are a raw material ratio of 3:7 at 500 °C. Co-pyrolysis efficiently reduced the content of oxygen-containing compounds of phenols, ketones, and acids in oil, and elevated the selectivity of aromatics. The research methods avoid the drawbacks of bio-oil and plastic oil and improve the quality of pyrolysis oil in a concise and efficient manner, which provides some new ideas for the resource and clean utilization of municipal waste.

Interstitial Boron Atoms in Pd Aerogel Selectively Switch the Pathway for Glycolic Acid Synthesis from Waste Plastics.

Electro-reforming of poly(ethylene terephthalate) (PET) into valuable chemicals is garnering significant attention as it opens a mild avenue for waste resource utilization. However, achieving high activity and selectivity for valuable C2 products during ethylene glycol (EG) oxidation in PET hydrolysate on Pd electrocatalysts remains challenging. The strong interaction between Pd and carbonyl (*CO) intermediates leads to undesirable over-oxidation and poisoning of Pd sites, which hinders the highly efficient C2 products production. Herein, a nonmetallic alloying strategy is employed to fabricate a Pd-boron alloy aerogel (PdB), wherein B atoms are induced to regulate the electron structure and surface oxophilicity. This approach allows a remarkable mass activity of 6.71 A mgPd -1, glycolic acid (GA) Faradaic efficiency (FE) of 93.8%, and stable 100 h cyclic electrolysis. In situ experiments and density functional theory calculations reveal the contributions of B inserted in Pd lattice on highly effective EG-to-GA conversion. Interestingly, the heightened surface oxophilicity and regulated electronic structure by B incorporation weakened *CO intermediates adsorption and enhanced hydroxyl species affinity to accelerate oxidative *OH adspecies formation, thereby synergistically avoiding over-oxidation and boosting GA synthesis. This work provides valuable insights for the rational design of high-performance electrocatalysts for GA synthesis via an oxophilic B motifs incorporation strategy.

Enhancement of alkaline pretreatment-anaerobically digested sludge dewaterability by chitosan and rice husk powder for land use of biogas slurry

Alkaline pretreatment can improve the methane yields and dewatering performance of anaerobically digested sludge, but it still needs to be coupled with other conditioning methods in the practical dewatering process. This study utilized four different flocculants and a skeleton builder for conditioning of alkaline pretreatment-anaerobically digested sludge. Chitosan was found to be the most effective in dewatering the sludge. Chitosan coupled with rice husk powder further improved the dewatering performance, which reduced normalized capillary suction time, specific resistance to filtration, and moisture content by 98.7%, 82.0%, and 12.1%. For land use of biogas slurry as a fertilizer, chitosan conditioning promoted the growth of corn seedlings, while the other three flocculants diminished the growth of corn seedlings. Chitosan coupled with rice husk powder further promoted the growth of corn seedlings by 103.5%, 65.0%, and 53.7% in fresh weight, dry weight, and root length, respectively. Overall, chitosan coupled with rice husk powder not only enhanced the dewaterability of alkaline pretreatment-anaerobically digested sludge but also realized the resource utilization of agricultural waste.

Reducing moisture content can promote the removal of pathogenic bacteria and viruses from sheep manure compost on the Qinghai-Tibet Plateau

Livestock manure contains a high concentration of pathogenic bacteria, viruses, and other harmful microorganisms. The effective elimination of these pathogens is of great significance to the harmless and resource utilization of livestock and poultry manure. Building upon prior research, this study further explored the removal efficiency of pathogenic bacteria and viruses in sheep manure compost on Qinghai-Tibet Plateau under 45 % (M45) and 60 % (M60) moisture content. The results showed that M45 led to a significant increase in the average composting temperature (P＜0.05), a notable reduction in the levels of Salmonella and Coliforms in the compost products, and facilitated the decline in abundance of various pathogens. As composting progressed, the abundance of viruses declined rapidly. Uroviricota was the most dominant viral phylum, and Siphoviridae, Myoviridae, Herpesviridae, and Podoviridae as the predominant viral families. M45 can significantly reduce the diversity and abundance of compost virus community (P＜0.05). The correlation analysis indicated a negative relationship between pathogens and the average temperature and humus content of the compost. In summary, the reduction of moisture content can enhance the biosafety of sheep manure compost products on the Qinghai-Tibet Plateau. These findings provide theoretical basis and technical support for the harmless and resource utilization of sheep manure waste on the Qinghai-Tibet Plateau.

Electrocatalytic formate synthesis from polyethylene terephthalate and carbon dioxide through sulfide-and-reconstruct engineering of catalyst

The global issue of plastic pollution and carbon emission have significantly impacted the survival of both ecosystems and human beings. Electrochemical coupling of polyethylene terephthalate plastic (PET) and CO2 into fine chemicals provides a potential approach to achieve waste resource utilization and carbon neutrality. Herein, we reported an innovative electrocatalytic system for concurrently upgrading PET hydrolysate and CO2 into value-added formic acid. Through a sulfide-and-reconstruct strategy, Ni3Bi2S2 and Bi2S3 were synthesized as pre-catalysts, which can undergo in situ reconstruction to form NiOOH/Ni3Bi2S2 at the anode and Bi (1.5 S) at the cathode during electrolysis. The exceptional electrocatalytic performance (96 % and 97 % at the anode and cathode, respectively) and stabilities (>30 h) of the anodic NiOOH/Ni3Bi2S2 and cathodic Bi (1.5 S) was attributed to the exposure of the true active site after reconstruction. By coupling PET hydrolysate oxidation reaction (POR) with CO2 reduction reaction (CO2RR), the assembled zero-gap MEA electrolyzer realized a total Faradaic efficiency of 175 % for formate. This study provided a concept for upcycling of PET.

Evolutionary game and simulation analysis of construction waste recycling from the perspective of stakeholders.

In current construction waste resource management processes, the effect of government supervision is unclear, and illegal treatment and low-quality reproduction of recycling and reprocessing enterprises by construction units are common. To improve the degree of resource utilization of construction waste and deeply explore the role of its key influencing factors, a tripartite evolutionary game model of construction waste resource treatment in which the government, construction units, and recycling and reprocessing enterprises are the research objects that considers public participation factors to be established. MATLAB is used to simulate the sensitivity of relevant parameters. The results show that: (1) An increase in government fines can regulate the behavior of enterprises; (2) Low government subsidies are conducive to the development of a tripartite stability strategy; and (3) An increase in the cost difference between the two strategies of the enterprise will weaken its willingness to carry out green operations (and after the cost difference exceeds the threshold, the enterprise will refuse to carry out green operations); (4) The reputation value brought by the public and the additional value added by reputation under the contrast effect have an incentive effect on the enterprise and the government; and (5) The peak value of the inverted U-shaped curve of government strategy choice is affected by the degree of public participation. Therefore, the government should propose rectifications in terms of fines and subsidies, and both companies can use technological innovation to reduce costs. At the same time, it is necessary to raise stakeholders' awareness of resource utilization and encourage the public to actively participate in supervision. The research conclusions can provide a decision-making reference for improving the utilization of construction waste resources and the efficient treatment of construction waste resources.

Synergistic effect of Cerium and Niobium enhances the low-temperature NH3-SCR activity of Fe-containing solid waste

To develop environment-friendly low temperature NH3-SCR catalyst and realize the resource utilization of industrial solid waste, this research prepared a series NH3-SCR catalysts by using Fe-containing solid waste loading CeO2 and Nb2O5. It was found that the Ce2Nb1/Fe-Si catalyst exhibited the highest NH3-SCR activity, reaching about 93 % NOx conversion and 99 % N2 selectivity at 300 °C due to the synergistic effect between Ce and Nb species. The characterization results showed that the interaction between Ce and Nb was stronger than that between Nb and Fe species, promoting the NH3 adsorption and redox cycle of Ce4+ + Nb4+ ↔ Ce3+ + Nb5+, Ce3+ + Fe3+ ↔ Fe2+ + Ce4+, which increased the contents of Fe2+ and surface adsorbed oxygen. Moreover, the co-existence of Ce and Nb species would increase the NOx adsorption ability and promote the oxidation of NO to NO2, which was beneficial for “Fast SCR” reaction. Finally, the introduction of CeO2 and Nb2O5 did not changed the reaction mechanism, followed by a Langmuir-Hinshelwood mechanism.

Performance optimization design of high ductility concrete rapid repair material incorporating coal gangue aggregate

In order to solve the problem of efficient and effective repair after brittle cracking of concrete on road and bridge deck pavements, and to consider the resource utilization of coal gangue solid waste, the river sand was replaced by coal gangue and a high ductile concrete rapid repair material (HDCRRM) was prepared through performance optimization design. First, the fluidity and compressive strength of materials mixed with different amounts of sulfoaluminate cement (SAC), fly ash, lithium carbonate, calcium hydroxide, calcium formate, sand-binder ratio, water-binder ratio and polycarboxylate superplasticizer were studied, so as to determine the preferred benchmark mix proportion. Then, the replacement rate of coal gangue was optimized to develop HDCRRM. Test results show that the reduction of SAC cement and the increase of fly ash content can weaken the compressive strength of material. The rational design content of lithium carbonate, calcium hydroxide, calcium formate, sand-binder ratio, water-binder ratio and polycarboxylate superplasticizer all can improve the fluidity and compressive strength of the materials within a certain range. When the replacement rate of coal gangue aggregate increases, the tensile elastic modulus and ultimate tensile strength of HDCRRM material decrease, while the ultimate tensile strain increases. When the replacement rate of coal gangue aggregate is 100 %, the compressive strength of HDCRRM is 40.5 MPa, the ultimate tensile strain is 2.83 %, and the average crack width is 50.27μm. The early compressive strength of HDCRRM is mainly provided by a large amount of ettringite and C-S-H gel.

Study on the removal of Cd from dewatered sludge by combined extraction agents: Peel extract and compound chemical extraction agent

The recycling of fruit peel resources is a current research hotspot. This study screened and configured a composite extractant consisting of peel and chemical extractant through extraction experiments and explored the heavy metals(HMs) release effect. The results showed that citrus reticulata(CR), citrullus lanatus (CL), 0.16 mol·L−1 nitrilotriacetic acid(NTA) with 0.04 mol·L−1 oxalic acid(NO5), and 0.12 mol·L−1NTA with 0.08 mol·L−1tartaric acid(NT4) had the strongest extraction ability. After the cross-combination was optimized, CR-NO5 (1:50, 6 h, 35 °C) and CL-NT4 (1:50, 36 h, 45 °C) had the highest extraction rates for Cd and Zn, which were 92.6 % and 98.4 %, respectively. The CL series increased the nutrient content of sludge (157.75–177.88 g·kg−1). The four combined extractants increased the proportion of soluble components of HMs in sludge (14–36 %). Therefore, the combined leaching agent will provide a valuable reference for the harmless treatment of HMs in sludge and the resource utilization of peel waste.

Zn-doped bentonite catalysts for waste engine oil cracking: Thermal treatment offers a cleaner alternative to acid activation

This study investigates the cracking of waste engine oil (WEO) using bentonite clay (BC) activated through acid and thermal methods, as well as with Zn-doped BCs. Acid activation with 1 M HCl and Zn doping did not alter the BC catalyst’s structure. XRD and SAED analyses confirmed the crystallinity, while TEM showed partial destruction of the layered structure. XRF analysis indicated reduced Al and Si content upon Zn-doping due to high cation exchange capacity. Zn-doping decreased surface area and pore volume but increased acidic sites in acid-treated catalysts, although Zn suppressed these sites in calcined BC. Zn-doped catalysts displayed higher thermal stability. Cracking WEO at 450 °C for 45 min, with and without catalysts, yielded high liquid product recovery (72.6 %–82.8 %), primarily carboxylic acids and aromatics. This demonstrates the potential of Zn-doped BC as an effective catalyst for converting WEO into valuable products, aiding waste management and resource utilization.

Activation of peroxymonosulfate by FeOOH modified biochar for the degradation of tetracycline hydrochloride

For preventing environmental pollution and realizing resource utilization of agricultural and forestry wastes, biochar was formed after high temperature pyrolysis of citrus peels under anoxic conditions, and employed as catalyst to activate peroxymonosulfate (PMS) for degrading tetracycline hydrochloride (TC) in wastewater. Furthermore, α-FeOOH modified biochar was fabricated through an alcohol-assisted hydrothemal method for proving the catalytic activity of biochar. The prepared catalysts were characterized by several characterization techniques. Results showed that the catalytic activity of α-FeOOH modified biochar was much better than that of biochar or α-FeOOH, which is attributed to the synergistic effects of biochar and α-FeOOH on the PMS activation. Meanwhile, the effects of PMS concentration, co-existing ions (Cl-, NO3−), and humic acids (HA) on the degradation of TC were investigated through static experiments. More importantly, radical trapping experiment tests suggested that hydroxyl radical (•OH), sulfate radical (SO4•-), and singlet oxygen (1O2) were generated during the process of catalyst activation of PMS, and 1O2 played the main role for TC degradation.

Synthesis of Iron-Tailing-Based porous ceramic granules for the adsorption of phenol-containing wastewater degradation

To achieve the resource utilization of solid waste and the treatment of phenol-containing wastewater in China, a new type of ceramic granule (TBBFSITFA) with the function of degrading phenol wastewater has been prepared from titanium-containing blast furnace slag (TBBFS), iron tailings (IT), and fly ash (FA) as raw materials to achieve the sustainable development of “treating waste with waste.” The adsorption behavior of TBBFSITFA samples on phenol in an aqueous solution was experimentally investigated. Double-beam ultraviolet–visible spectrophotometer (UV–vis), total organic carbon (TOC) test showed that the optimal raw material ratio of TBBFS: IT: FA = 10:70:20, the degradation rate of phenol reached 95.40%, and the removal rate of TOC was as high as 93.29%. In addition, X-ray photoelectron spectroscopy (XPS), energy spectrometry (EDS), and Fourier transform infrared spectrophotometry (FT-IR) demonstrated that the better the synergistic effect produced by having a suitable Fe3+/Fe2+ ratio and raw material ratio in the TBBFSITFA sample, as well as a high specific surface area, porosity and high surface adsorption of oxygen, the higher the mineralization of the phenol solution. This work provides a low-cost, environmentally friendly, and simple technology for phenol-containing wastewater treatment and a new idea for effectively using solid waste resources.

An Empirical Research on the Relationship Between Comprehensive Utilization of Waste Resources and Environmental Governance

An Empirical Research on the Relationship Between Comprehensive Utilization of Waste Resources and Environmental Governance