Bioenergy Perspectives in the EU Regions: Carbon Neutrality Pathway

Bioenergy plays an important role in the climate neutrality targets of the EU. However, the status of bioenergy implementation varies greatly across the EU. The aim of this paper is to assess the role of bioenergy in different EU countries using EU experts’ opinions of bioenergy implementation in their own country. The paper identifies leading and lagging countries in biomass development by focusing on the current share of bioenergy in the total energy supply. The study shows differences in bioenergy development between Southern and Western EU countries with Northern and Eastern EU countries. The anti-bioenergy movement and continuing political support for the fossil fuel industry are important barriers inhibiting biomass development in many EU countries, especially in Southern Europe and Western Europe. Our analysis finds that the EU needs more factual bioenergy information and improved promotion of bioenergy throughout society, especially in southern and western parts of the EU. Bioenergy development in the EU can be looked at optimistically, especially in Northern and Eastern Europe. The experience of societal acceptance of bioenergy in countries such as Finland and Sweden is applicable to countries that have thus far seen less progress in bioenergy implementation such as Poland and the Netherlands.

Nigerian Biomass for Bioenergy Applications:A Review on the Potential and Challenges

Nigeria,often referred to as“the giant of Africa,”boasts a sizable population,a thriving economy,and abundant energy resources.Nevertheless,Nigeria has yet to fully harness its renewable energy potential,despite its enormous capacity in this field.The goal of this review paper is to thoroughly examine the difficulties and untapped opportunities in utilizing biomass for bioenergy production in Nigeria.Notably,Nigeria generates substantial volumes of biomass annually,primarily in the form of agricultural waste,which is often either discarded or burned inefficiently,resulting in significant ecological and environmental damage.Therefore,an efficient approach to reducing pollution and transforming waste into wealth involves converting these biomass resources into energy.This work critically examines the status of biomass utilization for energy applications in Nigeria and highlights the bottlenecks that impede its widespread adoption.The review emphasizes the economic and ecological advantages of biomass utilization over traditional waste treatment methods.Additionally,it underscores the appeal of biomass as an industrial fuel source,particularly considering the current high cost of fossil fuels in contemporary Nigeria.Relevant literature on biomass,energy,agricultural waste,fossil fuel,and calorific value in the context of Nigeria was reviewed by utilizing a thorough search technique in key scientific databases.The analysis did not include any non-English publications.The findings of this research provide valuable insights into the challenges faced in maximizing Nigeria’s biomass potential and offer strategic recommendations to promote the use of biomass for bioenergy development.This review paper will assist a wide range of local and international readers,as well as industries interested in green and bioenergy,in making informed decisions regarding the most suitable types of biomass for biofuel production.

采伐限额对大兴安岭盘古林场森林碳汇强度的长期影响

【目的】探明采伐限额对林场尺度森林碳汇强度及其持续时间的影响规律和机制,量化不同采伐限额对林场尺度森林多目标经营决策的影响,为全面提升森林质量和碳汇功能提供理论基础。【方法】以大兴安岭塔河林业局盘古林场为例,模拟退火为优化算法,考虑活立木、枯死木、枯落物、木材产品、采伐/加工以及替代效应的碳库,建立以木材生产、生物质能源和碳汇综合收益最大化为目标的经营规划模型,并量化不同采伐限额(情景1:每分期0 m^(3);情景2:每分期19000 m^(3);情景3:每分期38000 m^(3);情景4:每分期56000 m^(3))对100年规划期(10个分期,每分期10年)内经济收益、木材产量、生物质能源产量、碳汇量以及经营措施的综合影响。【结果】当仅考虑碳汇收益时,规划期内盘古林场的总经济收益为15416.19×10^(4)yuan;随着采伐限额的增加,规划期内总经济收益呈明显增加趋势,情景2,3和4分别较情景1增加19.74%、39.14%和58.81%;各分期净碳汇量随着规划分期的增加呈明显降低趋势,而各分期林地碳储量呈明显增加趋势;整个规划期内平均碳汇量0.16~0.24 t·hm^(-2)a^(-1),规划期末林地碳储量高达77.47~77.90 t·hm^(-2),较规划期初增加约48.07%;规划期内中径材蓄积比例呈增加趋势(从5.80%到36.18%),而小径材比例呈明显下降趋势(从45.74%到16.09%),但短小材比例则相对稳定(平均43.98%);各情景中生物质能源产量与木材产量密切相关,其比值分别为0.2437、0.2497和0.2477,整体以收获树干(45.70%)和树根(36.03%)中的生物质能源为主;情景2~4中,平均每分期采伐面积分别为890、1742和2385 hm2,整体以轻度择伐为主(从75.08%到67.65%),但中度(从17.98%到22.25%)和重度(从6.95%到10.10%)择伐面积比例呈明显增加趋势。【结论】长远来看,适当增加大兴安岭地区的森林采伐限额不仅能够增加森林的碳汇强度,还能够显著延长碳汇的持续时间。

低碳背景下生物能源行业参与碳汇交易面临的挑战

生物能源作为可再生能源的重要组成部分,正逐步成为碳汇交易领域的关键参与者,然而气候变化与全球环境问题为生物能源行业参与碳汇交易带来新的机遇与挑战。基于学者的理论研究,结合相关学术文献、政策文件与行业报告,分析生物能源行业的发展现状及行业参与碳汇交易面临的主要问题,探讨未来生物能源行业参与碳汇交易所面临的挑战,提出通过加强管理体系建设、政策引导、合理补偿、国际合作、强化培训等方式克服这些挑战,在低碳发展的趋势下,推进生物能源行业可持续发展。

温和条件下乙二醇苯醚高效分离回收甘蔗渣组分

使用酸性乙二醇苯醚(EPH)体系对甘蔗渣(SCB)进行预处理,在最优条件下(110℃,0.05 mol/L H2SO4,60 min)实现了90.47%的纤维素保留率,去除了90.33%的木质素和76.70%的半纤维素。回收得到的富含纤维素的残渣最高酶解率为89.71%,是未经处理的甘蔗渣的酶解率(15.93%)的近6倍。用异丙醚从预处理液中回收了74.29%的木质素(纯度为93.53%)。使用SEM、XRD、FTIR对预处理后残渣及原料的组成及结构进行表征,发现甘蔗渣的形貌结构被破坏,结晶度提高,因而酶解率大幅度提高。通过2D HSQC表征发现在预处理过程中乙二醇苯醚和木质素的醚化反应抑制了木质素的缩合。本研究建立了酸性乙二醇苯醚预处理体系,实现了甘蔗渣组分的高效分离,并高效回收高纯木质素与可发酵糖,可为生物质高值化利用提供参考。

裂解多糖单加氧酶的研究进展

多糖类化合物在自然界中广泛存在,但目前针对多糖类底物的酶解效果并不理想。裂解多糖单加氧酶(lytic polysaccharide monooxygenase,LPMO)是一种新型的多糖降解酶,其能够以氧化方式打开纤维素中的糖苷键使其出现更多的酶解位点,从而在降解纤维素等多糖类物质中发挥着巨大优势。该文从LPMO的分类、结构、活性测定方法、异源表达及其在食品、饲料等领域的应用等方面进行了介绍,以期为该酶的推广应用提供帮助。

废旧棉织物的资源能源化利用研究进展

废旧棉织物蕴含丰富的纤维素和高含碳量,是低成本的资源能源化利用原材料,其产生量占废旧纺织品总量的24%。因此,废旧棉织物的回收再利用可避免填埋或焚烧处理造成的资源浪费,对纺织行业降低碳排放、助力实现“碳达峰、碳中和”目标具有重要意义。本文在分析国内外废旧纺织品回收利用现状的基础上,提出了废旧棉织物回收利用的必要性和意义。重点阐述了废旧棉织物回收利用制成再生棉纤维/纱线、制备碳材料(如炭微球、再生纤维膜、棉纤维基活性炭和活性炭纤维等),生产微晶纤维素,以及生产甲烷、乙醇和丁醇等生物能源的利用途径,指出了废旧棉织物资源能源化利用面临的挑战及未来的研究重点。

高岭土-尿素改性玉米秸秆生物炭去除污水中COD研究

以固体废弃物资源玉米秸秆为原料,并使用尿素与高岭土对其进行化学改性,通过管式炉高温制备改性玉米秸秆生物炭(NKBC),该材料制备工艺简便,成本低,对环境友好。研究了NKBC对污水中化学需氧量(COD)的吸附性能,包括吸附等温线、吸附动力学等。结果表明:NKBC对COD的吸附平衡投料量为0.50g/L,去除率为68%~70%,吸附平衡时间为1h,且pH对NKBC去除COD影响较小。通过分析可知,此吸附拟合模型遵循Langmuir模型与Freundlich模型以及准二级动力学模型,说明NKBC的吸附过程既涉及单层吸附,又涉及多层吸附。循环使用5次后,NKBC对COD的去除率依然保持在较高水平。实验证明,NKBC具有出色的去除和循环性能。

电化学-膜生物反应器强化污废水处理的研究进展

电化学耦合膜生物反应器(EMBR)是新兴的污废水处理技术,除了能够高效去除常规污染物,EMBR在去除微污染物和病原微生物、缓解抗生素抗性基因增殖、控制膜污染和回收生物能源与资源等方面也具有显著的优势。综述了EMBR工艺的原理及特点、污废水处理效能、能源与资源回收效果、膜污染控制和技术挑战。为了推动EMBR的工程应用,未来仍需开发具有高导电性、生物相容性的电极材料,优化反应器构型和操作条件,以持续提升对污废水的处理效能。

中美CCUS技术发展与政策体系对比

碳捕集、利用与封存(CCUS)技术是指能够将二氧化碳从能源利用、工业生产等排放源或生物质利用尾气、空气中等不同碳源捕集分离,并输送到适宜的场地加以利用或封存,最终实现二氧化碳减排的技术组合,是各国实现气候目标所不可或缺的重要技术支撑。碳达峰碳中和目标提出后,中国已初步建立碳达峰碳中和相关政策体系,积极推进各行业深度技术创新和系统性变革。CCUS技术既是可以实现化石能源的大规模低碳利用的重要技术选择,又是推进钢铁、水泥等难减排工业行业深度脱碳的可行技术方案,更是未来抵消剩余温室气体排放的托底技术手段。为实现中美两国气候目标,两国最终需要通过CCUS技术实现每年数十亿吨的二氧化碳减排量。美国是全球CCUS技术的先行者之一,在政策法规制定、基础设施建设、大规模工程运营方面具有相对优势。为支撑净零排放目标,美国通过一系列卓有成效的财税激励机制加快了CCUS项目大规模部署进展,相关经验值得借鉴。文章通过比较中美两国在CCUS技术领域的潜力需求、政策法规、研发示范等情况,为我国CCUS技术及配套政策环境发展提供参考,并提出中美在CCUS技术领域开展合作的潜在方向。

Synthesis of waterborne polyurethane-humic acid cross-linked biomass porous materials for the adsorption of methylene blue

A series of adsorbent materials(WPU-HAx-y)with a three-dimensional porous structure,green sustainability,and excellent performance were prepared and evaluated for the removal of methylene blue using nontoxic and environmentally friendly waterborne polyurethane as the matrix material and humic acid,a biomass material,as the functional material.The newly synthesized adsorbents were characterized by infrared spectroscopy,scanning electron microscopy,specific surface area,and thermogravimetric.The effects of contact time(0-8 h),starting concentration(10-100 mg·L^(-1)),pH(3-11),solution temperature(30-60℃),and coexisting ions(Ca2+,Na+,K+,Mg2+)on the performance were investigated.Pseudo-first-order,pseudo-second-order,elovich,and intra-particle diffusion models were used to analyze the adsorption kinetics;the Langmuir,Freundlich,Temkin,and Dubin-Radushkovich adsorption isotherms were evaluated;and the adsorption behavior of the adsorbent materials was found to be more appropriate for the pseudo-second-order model for chemical pollutant removal than the Langmuir model,which depends on monolayer adsorption.WPU-HA2-3 stood out with a maximum adsorption capacity of 813.0081 mg·g^(-1) fitted to the pseudo-second-order and 309.2832 mg·g^(-1) fitted to the Langmuir model,showing superior adsorption performance and regenerability.

Photoinduced transposed Paternò-Büchi reaction for effective synthesis of high-performance jet fuel

High-energy-density fuels are important for volume-limited aerospace vehicles,but the increase in fuel energy density always leads to poor cryogenic performance.Herein,we investigated the transposed Paternò-Büchi reaction of biomass cyclic ketone and cyclic alkene to synthesize a new kind of alkyl-substituted polycyclic hydrocarbon fuel with high energy density and good cryogenic performance.The triplet-energy-quenching results and phosphorescent emission spectra reveal the sensitization mechanism of the reaction,including photosensitizer excitation,triplettriplet energy transfer,cyclization,and relaxation,and the possible reaction path was revealed by the density functional theory(DFT)calculations.The reaction conditions of photosensitizer type and addition,molar ratio of substrates,reaction temperature,and incident light intensity were optimized,with the target product yield achieving 65.5%.Moreover,the reaction dynamics of the reaction rate versus the light intensity are established.After the hydrogenation-deoxygenation reaction,three fuels with a high density of 0.864-0.938 g·ml^(-1) and a low freezing point of<-55℃ are obtained.This work provides a benign and effective approach to synthesize high-performance fuels.

生物能源生产安全性评估与管理——以纤维素乙醇为例

随着全球能源需求的增长和环境保护意识的提升,生物能源作为一种可再生能源,受到了广泛关注。生物质纤维素乙醇燃料来源广泛且对环境友好,有希望成为未来能源的重要替代品。本文聚焦于纤维素乙醇生产过程中的安全性评估与管理,旨在提供一个全面的安全性评估框架,以确保生产过程的安全和效率。通过分析生产过程中的潜在风险,如化学物质泄漏、设备故障和操作失误等,提出实施严格的安全管理措施和持续的风险监控等对策。

Switchgrass as a bioenergy crop in the Loess Plateau, China：Potential lignocellulosic feedstock production and environmental conservation

A large portion of the Loess Plateau of China is characterized as “marginal” with serious land degradation and desertification problems. Consequently, two policies, Grain for Green and Western Development Action were established by the Chinese government in response to the demand for ecological protection and economic development in the Loess Plateau. These policies are designed to increase forest cover, expand farmlands, and enhance soil and water conservation, while creating sustainable vegetation restoration. Perennial grasses have gained attention as bioenergy feedstocks due to their high biomass yields, low inputs, and greater ecosystem services compared to annual crops. Moreover, perennial grasses limit nutrient runoff and reduce greenhouse gas emissions and soil losses while sequestering carbon. Additionally, perennial grasses can generate economic returns for local farmers through producing bioenergy feedstock or forage on marginal lands. Here, we suggest a United States model energy crop, switchgrass（Panicum virgatum L.） as a model crop to minimize land degradation and desertification and to generate biomass for energy on the Loess Plateau.

Sweet sorghum and Miscanthus：Two potential dedicated bioenergy crops in China

Among the potential non-food energy crops,the sugar-rich C4 grass sweet sorghum and the biomass-rich Miscanthus are increasingly considered as two leading candidates.Here,we outline the biological traits of these energy crops for largescale production in China.We also review recent progress on understanding of plant cell wall composition and wall polymer features of both plant species from large populations that affect both biomass enzymatic digestibility and ethanol conversion rates under various pretreatment conditions.We finally propose genetic approaches to enhance biomass production,enzymatic digestibility and sugar-ethanol conversion efficiency of the energy crops.

A Hybrid Biofuel and Triboelectric Nanogenerator for Bioenergy Harvesting

Various types of energy exist everywhere around us,and these energies can be harvested from multiple sources to power micro-/nanoelectronic system and even personal electronic products.In this work,we proposed a hybrid energy-harvesting system(HEHS)for potential in vivo applications.The HEHS consisted of a triboelectric nanogenerator and a glucose fuel cell for simultaneously harvesting biomechanical energy and biochemical energy in simulated body fluid.These two energy-harvesting units can work individually as a single power source or work simultaneously as an integrated system.This design strengthened the flexibility of harvesting multiple energies and enhanced corresponding electric output.Compared with any individual device,the integrated HEHS outputs a superimposed current and has a faster charging rate.Using the harvested energy,HEHS can power a calculator or a green light-emitting diode pattern.Considering the widely existed biomechanical energy and glucose molecules in the body,the developed HEHS can be a promising candidate for building in vivo self-powered healthcare monitoring system.

A technical and socioeconomic approach to estimate forest residues as a feedstock for bioenergy in northern Mexico

Background: Forest residues can be a feasible alternative for converting energy into fuels, electricity, or heat.Compared to other second-generation bioenergy sources, they do not compete for food, are relatively cheap,abundant in forest-rich areas, and more importantly their energy balance is close to zero. Biomass estimations can help design energy strategies to reduce fossil fuels dependency. Because of the land property distribution in Mexico,biomass estimations should consider not only the physical availability, but also the willingness of landowners to extract such raw materials.Methods: This study presents a methodological approach for evaluating the potential use of forest residues as a feedstock to generate bioenergy in northern Mexico. Remote sensing and field forest inventory were used to estimate the quantity and distribution of forest residues. In addition, a discrete choice analysis evaluated landowners’ preferences towards bioenergy development, including the most important factors that influence their willingness to extract their products and the expected price.Results and conclusions: Considering both physical and socio-economic aspects, results showed that about59,000 metric tons per year could be available in the study area. The vast majority of landowners surveyed are willing to extract forest residues, as long as they are presented with extraction plans with the highest income. However, many showed concerns about the environmental impacts this activity can have on soils,plants, and fauna. These results can help evaluate the potential of these resources for bioenergy development.

Life cycle cost and economic assessment of biochar-based bioenergy production and biochar land application in Northwestern Ontario, Canada

Background： Replacement of fossil fuel based energy with biochar-based bioenergy production can help reduce greenhouse gas emissions while mitigating the adverse impacts of climate change and global warming. However, the production of biochar-based bioenergy depends on a sustainable supply of biomass. Although, Northwestern Ontario has a rich and sustainable supply of woody biomass, a comprehensive life cycle cost and economic assessment of biochar-based bioenergy production technology has not been done so far in the region. Methods： In this paper, we conducted a thorough life cycle cost assessment （LCCA） of biochar-based bioenergy production and its land application under four different scenarios： 1） biochar production with low feedstock availability; 2） biochar production with high feedstock availability; 3） biochar production with low feedstock availability and its land application; and 4） biochar production with high feedstock availability and its land applicationusing SimaPro, EIOLCA software and spreadsheet modeling. Based on the LCCA results, we further conducted an economic assessment for the break-even and viability of this technology over the project period. Results： It was found that the economic viability of biochar-based bioenergy production system within the life cycle analysis system boundary based on study assumptions is directly dependent on costs of pyrolysis, feedstock processing （drying, grinding and pelletization） and collection on site and the value of total carbon offset provided by the system. Sensitivity analysis of transportation distance and different values of C offset showed that the system is profitable in case of high biomass availability within 200 km and when the cost of carbon sequestration exceeds CAD S60 per tonne of equivalent carbon （CO2e）. Conclusions： Biochar-based bioenergy system is economically viable when life cycle costs and environmental assumptions are accounted for. This study provides a medium scale slow-pyrolysis plant scenario and we recommend similar experiments with large-scale plants in order to implement the technology at industrial scale.

Row Spacing Affects Biomass Yield and Composition of Kenaf (<i>Hibiscus cannabinus</i>L.) as a Lignocellulosic Feedstock for Bioenergy

Kenaf (Hibiscus cannabinus L.) is a warm-season annual. Kenaf fibers are commonly used for paper pulp and cordage, but it is also a promising lignocellulosic feedstock for bioenergy production, although optimum plant density for biomass production has not been determined for the northern region of the USA. The objective of this study was to determine the best plant density and row spacing of kenaf to maximize biomass yield and chemical composition for biofuel conversion. The experiments were conducted at Fargo and Prosper, ND, in 2010 and 2011. The experiment was a randomized complete block design with a split-plot arrangement where the main plot was tworowspacings (30 and60 cm) and the sub-plot fourplant densities (32, 16, 8, and 4 plants·m-2). Row spacing had a significant effect on both biomass and biofuel yield. Narrower rows had higher biomass and biofuel yield. Maximum biomass and estimated biofuel yield was obtained with the two highest plant densities of 16 and 32 plants·m-2 and fluctuated between 9.45 and 10.22 Mg·ha-1 and 1354 and1464 L·ha-1, respectively. Stem diameter increased with a decrease in plant density. Chemical composition varied with plant density;glucan (27%) and xylan (9.8%) content were lower at the lowest plant density. Ash content was not different among plant densities but it is interesting to mention the very low ash content of kenaf (0.15%). According to the results of this study, it is recommended to plant kenaf at 30-cm rows with a plant density of 16 to 32 plants·m-2 to maximize biomass yield. Kenaf has a tremendous potential as a cellulosic feedstock for biofuel and green chemicals in the Northern Great Plains because of high biomass yield and low ash content.

Analysis on the Growth Rhythm and Cold Tolerance of Five-Year Old <i>Eucalyptus benthamii</i>Plantation for Bioenergy

A research plot of Eucalyptus benthamii was planted to evaluate this species’ ability to supply the emerging bioenergy markets that are developing in the southern U.S. The plot was planted in two different densities to investigate the growth parameters and the cold tolerance. The stand was measured annually through five growing seasons. The results indicated that the growth difference among the young E. benthamii was noticeable. For example, the maximum and minimum value of five-year old trees at diameter breast height (DBH) was 27.9 centimeters and 1.27 centimeters;and the maximum and minimum value of tree height was 22.86 meters and 2.44 meters, respectively. The yearly change in DBH and height of E. benthamii had significant differences. The average annual survival rates of E. benthamii had differences under the two planting densities (1650 trees ha-1 and 1237 trees ha-1). The densities also had effects on the height and DBH growth of E. benthamii. The average DBH and height of 1650 trees ha-1 plantation were 11.18 centimeters and 15.03 meters, and the average DBH and height of 1237 trees ha-1 plantation were 13.46 centimeters and 16.28 meters. The volume per hectare of 1650 trees ha-1 and 1237 trees ha-1 plantation were 111.45 cubic meters and 101.15 cubic meters, respectively. Average diameter growth was almost 2.54 centimeters per year and average height growth was over 3 meters. E. benthamii plantations were considered tolerant to -7.4 degrees Celsius and a cold spell during early 2014 (-11.3 degrees Celsius for two consecutive nights) killed the plantation. The growth of E. benthamii also varied depending on surrounding conditions. The difference in growth of row seven versus row one was a good example. The reason probably was that row seven was adjacent to a loblolly pine plantation and row one was next to an open field.