A sustainable process to 100%bio-based nylons integrated chemical and biological conversion of lignocellulose

Considerable progress has been made in recent years to the development of sustainable polymers from bio-based feedstocks.In this study,100%bio-based nylons were prepared via an integrated chemical and biological process from lignocellulose.These novel nylons were obtained by the melt polymerization of 3-propyladipic acid derived from lignin and 1,5-pentenediamine/1,4-butanediamine derived from carbohydrate sugar.Central to the concept is a three-step noble metal free catalytic chemical funnelling sequence(Raney Ni mediated reductive catalytic fractionation-reductive funnelling-oxidative funnelling),which allowed for obtaining a single component 3-propyladipic acid from lignin with high efficiency.The structural and thermodynamic properties of the obtained nylons have been systematically investigated,and thus obtained transparent bio-based nylons exhibited higher Mw(>32,000)and excellent thermal stability(Td5%>265℃).Considering their moderate Tg and good melt strength,these transparent bio-based nylons could serve as promising functional additives or temperature-responsive materials.

Recyclable bio-based epoxy resin thermoset polymer from wood for circular economy

Due to their extraordinary durability and thermal stability,Epoxy Resin Thermosets(ERTs)are essential in various industries.However,their poor recyclability leads to unacceptable environmental pollution.In this study,Wu et al.successfully synthesized a completely bio-based ERT using lignocellulose-derived building blocks which exhibit outstanding thermal and mechanical properties.Remarkably,these bio-materials degrade via methanolysis without the need of any catalyst,presenting a smart and cost-effective recycling strategy.Furthermore,this approach could be employed for fabricating reusable composites comprising glass fiber and plant fiber,thereby expanding its applications in sustainable transportation,coatings,paints or biomedical devices.

Bio-based rejuvenators in asphalt pavements:A comprehensive review and analytical study

The pressing demand for sustainable advancements in road infrastructure has catalyzed extensive research into environmentally conscious alternatives for the maintenance and restoration of asphalt concrete pavements.This paper offers a comprehensive review and analysis of bio-based rejuvenators as a promising avenue for enhancing the longevity and sustainability of asphalt.Through a multifaceted exploration,it delves into various aspects of this innovative approach.Providing a thorough overview of bio-based rejuvenators,the study highlights their renewable and environmentally friendly characteristics.It conducts an in-depth examination of a wide spectrum of bio-derived materials,including vegetable oils,waste-derived bio-products,and biopolymers,through a comprehensive survey.The paper evaluates how bio-based rejuvenators enhance aged asphalt binders and mixes,effectively mitigating the adverse impacts of aging.Furthermore,it investigates how these rejuvenators address environmental concerns by identifying compatibility issues,assessing long-term performance,and evaluating economic feasibility.Finally,the paper outlines potential advancements and research pathways aimed at optimizing the utilization of bio-based rejuvenators in asphalt concrete,thereby contributing to the sustainable evolution of road infrastructure.

Aqueous-phase reforming of hydroxyacetone solution to bio-based H_(2)over supported Pt catalysts

Aqueous-phase reforming(APR)is an attractive process to produce bio-based hydrogen from waste biomass streams,during which the catalyst stability is often challenged due to the harsh reaction conditions.In this work,three Pt-based catalysts supported on C,AlO(OH),and ZrO_(2)were investigated for the APR of hydroxyacetone solution in afixed bed reactor at 225℃and 35 bar.Among them,the Pt/C catalyst showed the highest turnover frequency for H_(2)production(TOF of 8.9 molH_(2)molPt^(-1)min^(-1))and the longest catalyst stability.Over the AlO(OH)and ZrO_(2)supported Pt catalysts,the side reactions consuming H_(2),formation of coke,and Pt sintering result in a low H_(2)production and the fast catalyst deactivation.The proposed reaction pathways suggest that a promising APR catalyst should reform all oxygenates in the aqueous phase,minimize the hydrogenation of the oxygenates,maximize the WGS reaction,and inhibit the condensation and coking reactions for maximizing the hydrogen yield and a stable catalytic performance.

基于绿色EVA视角的化工企业业绩评价研究

随着十四五规划的推进、“双碳”政策的实施,绿色化工及碳中和将是未来中国重要的经济增长动力之一,化工产业的可持续发展备受关注。本文以中国基础化工行业为研究样本,搜集整理了2020年和2021年相关数据,将绿色EVA值引入化工企业业绩评价体系。首先采用因子分析法分别提取各年化工行业业绩表现的主要影响因子,计算因子综合得分;再结合聚类分析对2021年和2020年化工行业业绩表现进行横向分类、纵向对比。以更全面地评价在疫情影响的经济动荡期内化工企业业绩现状、剖析原因并结合化工行业的特点提出相应发展建议。

光伏组件封装EVA的湿热老化分析

本文针对光伏组件封装材料——乙烯醋酸乙烯(EVA)的湿热老化性能进行深入研究,旨在提高光伏组件的可靠性。文章首先介绍了EVA材料的组成及交联度对其性能的影响,然后通过湿热老化实验模拟了光伏组件在实际应用中的环境条件,最后分析了不同交联度EVA在湿热老化过程中的性能变化,为优化光伏组件封装材料提供理论依据。

EVA对CB/EVA/PA6复合材料性能的影响

以导电炭黑(CB)为导电填料,乙烯–醋酸乙烯酯(EVA)为增韧剂,通过双螺杆挤出机和注射成型机制备了CB/EVA/聚酰胺6(PA6)复合材料,并探讨了EVA质量分数对 CB/EVA/PA6复合材料力学性能、电性能、热稳定性和形貌的影响。研究表明,基体中的EVA热塑性弹性体颗粒吸收部分能量参与整个形变过程,添加EVA使EVA/PA6复合材料的冲击强度、断裂伸长率和电性能增加,但导致拉伸强度和热稳定性明显降低。添加质量分数30%的EVA可提高CB/EVA/PA6复合材料的冲击强度和电性能。CB/EVA/PA6复合材料冲击强度和电性能的提高源于第三相(EVA)的存在改善了CB的分散性和分布状态,熔融共混中CB更趋于选择分散在PA6相和PA6相与EVA相交界处,同时产生尺寸排空效应,有利于复合材料形成导电网络。

基于EVA模型的宁德时代公司估值分析

近年来,为了实现2030年碳达峰与2060年碳中和目标,新能源行业得到快速发展。宁德时代作为新能源行业的领先者,广受投资者的关注。首先,对公司面临的宏微观环境进行分析;其次,选取EVA模型,调整相关会计科目,对宁德时代2020—2022年的经济增加值进行计算,结合宏观环境以及宁德时代公司财务状况,分析宁德时代公司价值;最后,根据估值结果提出合理利用财务杠杆、提高企业创新能力、深化供应链管理体系等发展建议,也为进行投资活动的投资者提供一份参考。

EVA动量下归核化战略对企业价值的影响——以杉杉股份为例

归核化战略是很多企业聚焦主业、实现企业价值最大化的战略选择,而对于企业价值的衡量与评价有很多传统的指标。其中,在我国央企中推行的经济增加值(EVA)受到广泛认可。但是EVA更像是时点指标,要想获得企业价值的长期增长,则需要EVA动量来衡量价值变动趋势和价值变动的效率。文章以杉杉股份为例,阐明通过EVA动量研究归核化战略对企业价值影响的适用性,从EVA动量的价值驱动因素剖析归核化战略对企业价值的作用路径,并对其影响企业价值的效果进行评价。

M集团价值创造路径与结果分析——基于战略性财务报表分析与EVA

进行价值创造是各个企业的目标。本文通过分析M集团价值创造路径,并使用竞争力、盈利质量与EVA分析其价值创造结果,发现M集团主要通过对外投资进行价值创造(价值整合),并形成了完整的“制造—物流—销售”业务链。通过分析M集团价值创造结果可知,M集团在行业中拥有较高的产品竞争力,虽然净利率和EVA值有所下降,但综合来看,其价值创造的结果仍然较好。M集团需进一步加强盈利质量并降低资本成本,以实现更好的发展。

探索以EVA为理论基础建立的评价指标在企业考核中的运用

随着现代企业管理体系的不断发展,经济增加值(EVA)作为一种评估企业实际创造财富能力的关键指标,正逐渐获得更多的关注。本文立足于EVA理论,深入探讨了这一方法在构建企业评价体系中的具体应用。文章首先解析了EVA的基本概念,并通过实证案例分析,考察了EVA在提升企业绩效评估准确性、促进资源合理配置及支持企业长期健康发展方面的作用。研究表明,采用基于EVA的评价标准能够有效地将公司的长远战略规划与日常运营活动相连接,通过加强资本成本意识和价值创造过程的协同性,为组织带来了明显的管理效益。

基于财务协同效应的企业EVA价值管理研究——以蒙牛收购妙可蓝多为例

目前EVA价值管理体系在国有企业中已经推广并不断发展完善,在国内其他企业中也将逐步推广。本文对蒙牛乳业并购妙可蓝多前后五年的绩效分析与EVA研究,使我国企业从实践层面了解到EVA价值管理体系的构建和实施,推动财务协同效应,促进EVA价值管理体系在企业应用中的不断完善,为企业发展提供参考性建议。

纳米硅溶胶−EVA−粉煤灰水泥基复合浆材配比正交优化及对其物性的影响

针对传统水泥基浆材不能满足煤矿大变形巷道注浆加固实际需求的难题,通过添加纳米硅溶胶、乙烯−醋酸乙烯共聚物(EVA)和粉煤灰对普通硅酸盐水泥进行改性获得高性能复合浆材。采用正交试验和极差分析法系统研究复合浆材物理力学性能的变化规律,确定最优配比,并进一步分析最优配比复合浆材与纯水泥的物性差异,构建复合浆材的水化反应机理模型,阐明其加固破碎岩石的力学特性。研究结果表明,复合浆材最优配比为:水灰比0.7,粉煤灰掺量15%,硅溶胶掺量2%,EVA掺量7.5%;相较于纯水泥,复合浆材流变性略有下降,但浆液稳定性、力学性能等均有显著提升,初凝时间缩短了38.9%,终凝时间缩短了53.8%,析水率降低了60%,结石率提高了3.3%,单轴抗压强度提高了39.1%,抗拉强度提高了97.2%,拉压比提高了41.7%;硅溶胶和粉煤灰在不同时期与Ca(OH)2发生火山灰反应生成更多水化硅酸钙(C-S-H)和水化铝酸钙(CA-H),促进复合浆材的水化反应,并加速EVA成膜,使结石体更加致密;复合浆材注入量和胶结体单轴抗压强度均随注浆压力的增大而增加,随Talbot指数的增加,抗压强度先增大后减小,破坏形式多呈鼓状,剪胀变形明显;当注浆压力大于2 MPa,Talbot指数为0.5时,胶结体强度较大,破坏较小。本研究为水泥基复合浆材早期强度、增韧改性提供了可行途径。

基于EVA的物流企业并购动因及绩效分析——以S公司并购J公司为例

近年来,国内互联网经济稳步增长,网络购物平台的崛起,带动了物流行业的迅猛发展。市场也对物流企业提出了更高的要求,物流企业为抢占更多市场份额,纷纷选择并购。并购已成为物流企业发展的重要手段。文章以S公司跨国并购J公司为例,分析物流行业并购动因及其对绩效的影响,通过计算S公司近几年的EVA数据,分析企业并购对绩效产生的影响并针对企业的现状提出发展建议,从行业角度出发,助力物流企业实现突破式增长,并为其他物流企业并购提供参考。

基于EVA的理想汽车财务绩效案例分析

随着环保意识的提高和石油资源的日益紧张,新能源汽车被广泛认为是未来汽车发展的方向。理想汽车在国内中高端新能源汽车市场攻城略地,但其财报数据却连年亏损,这一反常现象引起了笔者的关注。本文以理想汽车为研究对象,运用EVA(经济增加值)对其财务绩效进行综合评价,并通过与传统财务绩效指标的对比分析,探讨运用EVA对以理想汽车为代表的新能源汽车企业进行财务绩效评价的合理性,发掘企业价值提高的驱动因素,以期为企业的决策提供参考。

基于EVA模型的企业价值评估研究——以煌上煌为例

当前,我国经济已进入高质量发展阶段,对构建高质量的社会主义市场经济体制提出了新要求,市场对企业价值评估的重视程度与日俱增。近年来,卤制品市场规模逐年上升,本文选取卤制品代表性企业煌上煌为例,采用EVA模型对其企业价值进行评估,并与评估基准日的市值进行对比,从而对投资者做出决策起到一定的参考作用。

Bio-Based Hyperbranched Toughener From Tannic Acid and Its Enhanced Solvent-Free Epoxy Resin with High Performance

It is essential to design economic and efficient tougheners to prepare high-performance epoxy resin;however,this has remained a huge challenge.Herein,an eco-friendly,low-cost,and facile-fabricated bio-based hyperbranched toughener,carboxylic acid-functionalized tannic acid(CATA),was successfully prepared and applicated to the preparation of solvent-free epoxy resins.The mechanical performance,morphology,structural characterization,and thermal characterization of toughened epoxy resin system were studied.The toughened epoxy resin system with only 1.0wt%CATA reached the highest impact strength,111%higher than the neat epoxy resin system.Notably,the tensile strength and elongation at break of toughened epoxy resin systems increased moderately with increasing CATA loading.Nonphase-separated hybrids with significant toughening effect were obtained.Additionally,the thermal stabilities of toughened epoxy resin systems decreased with increasing CATA loading.This study provides an eco-friendly,cost-effective,and facile approach for the preparation of high-performance,solvent-free epoxy resins with potential for practical applications in sealing integrated circuits and electrical devices fields.

Spinning from Nature:Engineered Preparation and Application of High-Performance Bio-Based Fibers

Many natural fibers are lightweight and display remarkable strength and toughness.These properties originate from the fibers’hierarchical structures,assembled from the molecular to macroscopic scale.The natural spinning systems that produce such fibers are highly energy efficient,inspiring researchers to mimic these processes to realize robust artificial spinning.Significant developments have been achieved in recent years toward the preparation of high-performance bio-based fibers.Beyond excellent mechanical properties,bio-based fibers can be functionalized with a series of new features,thus expanding their sophisticated applications in smart textiles,electronic sensors,and biomedical engineering.Here,recent progress in the construction of bio-based fibers is outlined.Various bioinspired spinning methods,strengthening strategies for mechanically strong fibers,and the diverse applications of these fibers are discussed.Moreover,challenges in reproducing the mechanical performance of natural systems and understanding their dynamic spinning process are presented.Finally,a perspective on the development of biological fibers is given.

Preparation and Properties of Bio-Based Flame Retardant Polyvinyl Alcohol

Polyvinyl alcohol (PVA) has been widely used in the fields of medical, food and packaging due to its excellentbiocompatibility, good fiber-forming and film-forming properties. However, the high flammability of PVA hasgreatly limited its wider applications. The flame-retardant PVA was prepared by melt blending of a bio-basedflame retardant (prepared from lignin, phosphoric acid and carbamide) with thermoplastic PVA (TPVA). Thechemical structure, morphology, thermal properties, mechanical properties, fire property and fluidity of thisflame retardant PVA were investigated by Fourier transform infrared spectrometer(FTIR), field emission scanning electron microscope(SEM), thermogravimetric analyzer(TGA), impact tester, universal testing machine,horizontal-vertical burning tester, limiting oxygen indexer(LOI) and melt flow rate meter(MFR). The resultsshowed that the prepared flame retardant had good compatibility with the PVA substrate;The impact strength,melt flow rate, fire property and char residue of this PVA material increased with the content of bio-based flameretardant. When the content of flame retardant was of 20%, the five indices including impact strength, meltflow rate, UL-94 level, LOI and char residual were 11.3 KJ/m^(2), 21.2 g/10 min, V-0 UL-94 level, 33.1%, and19.2%, respectively. This research can promote the high-value utilization of lignin and the application ofPVA in the fields of fire protection.

Elastic Bio-based Polyurethane Nanofibrous Membrane with Robust Waterproof and Breathable Properties

Elastic bio-based waterproof and breathable membranes(EBWBMs) allow the passage of water vapor effectively and resist the penetration of liquid water,making it ideal for use under extreme conditions.In this study,we used a facile strategy to design the bio-based polyurethane(PU) nanofibrous membranes with the nanoscale porous structure to provide the membranes with high waterproof and breathable performances.The optimization of nanofibrous membrane formation was accomplished by controlling the relative ambient humidity to modulate the cooperating effects of charge dissipation and non-solvent-induced phase separation.The obtained EBWBMs showed multiple functional properties,with a hydrostatic pressure of 86.41 kPa and a water vapor transmission(WVT) rate of 10.1 kg·m^(-2)·d^(-1).After 1 000 cycles of stretching at 40% strain,the EBWBMs retained over 59% of the original maximum stress and exhibited an ideal elasticity recovery ratio of 85%.Besides,even after 80% deformation,the EBWBMs still maintained a hydrostatic pressure of 30.65 kPa and a WVT rate of 13.6 kg·m^(-2)·d^(-1),suggesting that bio-based PU nanofibrous membranes could be used for protection under extreme conditions.