珠江三角洲森林的生物量和生产力研究

利用森林资源清查资料和经过实地校正的相关森林生物量和生产力估算方程,对珠江三角洲森林植被的生物量和生产力进行了研究。结果表明,珠江三角洲森林的生物量为132 404 963 t,总净生产量为26 273 769 t.a-1。区域森林生物量主要分布在珠江三角洲的外围,其中,马尾松林和常绿阔叶林的生物量占区域森林总生物量的52.18%;生态公益林的生物量只到达用材林的48.68%;中幼龄林生物量所占比例很大,总体质量不高,但如果现有森林得到更好地保护和管理,珠江三角洲地区的森林会有较大的发展潜力,并在维护区域生态环境上起着主导作用。     

三江平原典型小叶章种群地上生物量的空间结构分形特征

2005年5月至10月,应用分形几何学的原理和方法对三江平原典型小叶章种群地上生物量与株高的空间结构分形关系进行了研究。结果表明,典型草甸小叶章和沼泽化草甸小叶章的地上生物量与株高存在良好的静态分形关系,其分形维数(D)是对地上生物量在各器官中积累规律的表征;二者地上生物量与株高的对数值线性相关,相关系数分别介于0.579～0.919和0.655～0.914之间(P<0.01,D值介于1.778～3.414和2.238～3.924之间,各时期地上生物量均以株高的幂函数形式积累;二者地上生物量与株高静态分形关系D值的季节动态基本一致,其变化均符合抛物线模型(P<0.05),而局部波动又与地上生物量的变化有关;生长季内,二者地上生物量与株高动态分形关系的D值分别为2.749和2.738,说明地上生物量的积累具有自相似性,符合幂函数增长的分形生长过程。研究还表明,仅用D值来刻画不同植物地上生物量的空间积累与展布存在一定的局限性,它只能用于测度和描述一种植物体生物量的空间积累及其对空间的占据,而一般不能用于植物间相应指标的类比;导致不同植物D值差异的原因可能与植物生长所处生境、外在因素以及模型参数(C)有关。     

Bioenergy to mitigate for climate change and meet the needs of society,the economy and the environment

Changes towards environmental improvementsare becoming more politically acceptableglobally, especially in developedcountries. Society is slowly moving towardsseeking more sustainable productionmethods, waste minimisation, reduced airpollution from vehicles, distributed energygeneration, conservation of native forests,and reduction of greenhouse gas (GHG)emissions. Modern biomass, when used tosupply useful bioenergy services, has arole to play in each one of theseenvironmental drivers at both the large andsmall scales.This paper describes recent developments inbiomass supply and the technologies for itsconversion to bioenergy including biofuelsfor transport. It examines the economic,environmental and social benefits andidentifies barriers to bioenergy projectimplementation. Future opportunities forbiomass as a carbon (C) sink, a C offsetand a potential source of renewablehydrogen are discussed.Whether or not a bioenergy project iseconomically viable, as well as being trulyrenewable, sustainable and environmentallysound, is determined mainly by the sourceof biomass. The social benefits from usingbiomass are also valuable, though they areoften not clearly presented when proposingnew bioenergy projects or conductinganalyses of existing plants. Employmentrates per MWh or per GJ exceed those whenusing fossil fuel supplies to provide thesame energy service. `Ownership' bystakeholders and local communities at anearly stage in the development process isthe key to successful project developmentin order to share the benefits. Bioenergyhas a significant global role to play inthe mitigation of atmospheric GHG concentrations.     

Origins of black carbon from anthropogenic emissions and open biomass burning transported to Xishuangbanna, Southwest China

Black carbon (BC) has importance regarding aerosol composition, radiative balance, and human exposure. This study adopted a backward-trajectory approach to quantify the origins of BC from anthropogenic emissions ($\mathrm{B}{\mathrm{C}}_{\text{An}}$) and open biomass burning ($\mathrm{B}{\mathrm{C}}_{\text{BB}}$) transported to Xishuangbanna in 2017. Haze months, between haze and clean months, and clean months in Xishuangbanna were defined according to daily PM_2.5 concentrations of >75, 35–75, and <35 µg/m³, respectively. Results showed that the transport efficiency density (TED) of BC transported to Xishuangbanna was controlled by the prevailing winds in different seasons. The yearly contributions to the effective emission intensity of $\mathrm{B}{\mathrm{C}}_{\text{An}}$ and $\mathrm{B}{\mathrm{C}}_{\text{BB}}$ transported to Xishuangbanna were 52% and 48%, respectively. However, when haze occurred in Xishuangbanna, the average $\mathrm{B}{\mathrm{C}}_{\text{An}}$ and $\mathrm{B}{\mathrm{C}}_{\text{BB}}$ contributions were 23% and 77%, respectively. This suggests that open biomass burning (BB) becomes the dominant source in haze months. Myanmar, India, and Laos were the dominant source regions of BC transported to Xishuangbanna during haze months, accounting for 59%, 18%, and 13% of the total, respectively. Furthermore, India was identified as the most important source regions of $\mathrm{B}{\mathrm{C}}_{\text{An}}$ transported to Xishuangbanna in haze months, accounting for 14%. The two countries making the greatest contributions to $\mathrm{B}{\mathrm{C}}_{\text{BB}}$ transported to Xishuangbanna were Myanmar and Laos in haze months, accounting for 55% and 13%, respectively. BC emissions from Xishuangbanna had minimal effects on the results of the present study. It is suggested that open BB in Myanmar and Laos, and anthropogenic emissions in India were responsible for poor air quality in Xishuangbanna.     

生物质转化利用技术研究进展

综述了当前国内外生物质转化利用技术的原理和特点，分析了生物质转化利用技术的研究现状以及存在的问题，展望了生物质利用的发展前景。     

生物质分类表征温度对蔬菜废物好氧降解过程的影响

通过对不同温度下蔬菜废物的好氧降解试验,研究了温度对蔬菜废物好氧降解过程的影响.结果表明,温度对易降解蔬菜废物的降解有促进作用,50℃时叶菜皮第14 d有机物降解率高达60.2%,比其在37℃时第18 d降解率高9.9%;糖类降解率差异是其差距的主要来源,这主要是由于高温刺激了降解过程细菌的增殖.对于难降解蔬菜废物茭白壳,37℃时第18 d降解率为46.1%,比其在50℃时降解至第14 d时高9%;纤维素降解率差异是其差距的主要来源,这主要是因为中温有利于嗜温放线菌数量的增加.研究结果揭示了根据蔬菜废物生物质组成特征控制堆肥化过程温度,有利于改善蔬菜废物好氧降解程度.     

Global Biomass Energy Potential

The intensive use of renewable energy is one of the options to stabilize CO₂atmospheric concentration at levels of 350 to 550ppm. A recent evaluation of the global potential of primary renewable energy carried out by Intergovernmental Panel on Climate Change (IPCC) sets a value of at least 2800EJ/yr, which is more than the most energy-intensive SRES scenario forecast for the world energy requirement up to the year 2100. Nevertheless, what is really important to quantify is the amount of final energy since the use of renewable sources may involve conversion efficiencies, from primary to final energy, different from the ones of conventional energy sources. In reality, IPCC does not provide a complete account of the final energy from renewables, but the text claims that using several available options to mitigate climate change, and renewables is only one of them, it is possible to stabilize atmospheric carbon dioxide (CO₂) concentration at a low level. In this paper, we evaluate in detail biomass primary and final energy using sugarcane crop as a proxy, since it is one of the highest energy density forms of biomass, and through afforestation/reforestation using a model presented in IPCC Second Assessment Report (SAR). The conclusion is that the primary-energy potential for biomass has been under-evaluated by many authors and by IPCC, and this under-evaluation is even larger for final energy since sugarcane allows co-production of electricity and liquid fuel. Regarding forests we reproduce IPCC results for primary energy and calculate final energy. Sugarcane is a tropical crop and cannot be grown in all the land area forecasted for biomass energy plantation in the IPCC/TAR evaluation (i.e. 1280Mha). Nevertheless, there are large expanses of unexploited land, mainly in Latin America and Africa that are subject to warm weather and convenient rainfall. With the use of 143Mha of these lands it is possible to produce 164EJ/yr (1147GJ/hayr or 3.6W/m²on average) of primary energy and 90EJ/yr of final energy in the form of liquid fuel (alcohol) and electricity, using agricultural productivities near the best ones already achievable and biomass gasification technology. More remarkable is that these results can be obtained with the operation of 4,000 production units with unitary capacity similar to the largest currently in operation. These units should be spread over the tropical land area yielding a plantation density similar to the one presently observed in the state of São Paulo, Brazil, where alcohol and electricity have been commercialized in a cost-effective way for several years. Such an amount of final energy would be sufficiently large to fulfill all the expected global increase in oil demand, as well as in electricity consumption by 2030, assuming the energy demand of such sources continues to grow at the same pace observed over the last two decades. When sugarcane crops are combined with afforestation/reforestation it is possible to show that carbon emissions decline for some IPCC SRES scenarios by 2030, 2040 and 2050. Such energy alternatives significantly reduce CO₂emissions by displacing fossil fuels and promote sustainable development through the creation of millions of direct and indirect jobs. Also, it opens an opportunity for negative CO₂emissions when coupled with carbon dioxide capture and storage.     

采伐与人工更新对红壤丘陵区森林面积和地上生物量的影响模拟——以会同县磨哨林场为例

我国人工林生态系统正面临着结构退化、功能降低等问题,迫切需要通过合理的森林管理方案实施有效的管理措施加以改善。本文以湖南省会同县磨哨林场为研究区,应用生态系统过程模型PnET-II和森林景观模型LANDIS-II,采用情景模拟的方式研究未来100年低、中、高强度的采伐措施以及人工更新对森林面积和地上生物量的影响。结果表明：（1）随着采伐强度增加,人工针叶林面积持续减少、森林AGB下降幅度加大;（2）人工更新措施能够使人工针叶林面积保持稳定,促进其AGB积累,有利于人工林更新与生长;（3）对人工林采取中等强度采伐且实施伐后人工更新的管理方案有利于我国南方以杉木（Cunninghamia lanceolata）、马尾松（Pinus massoniana）为主要树种的人工林地区实现森林可持续经营。     

长江三角洲2010~2018年生物质燃烧中等挥发性有机物(IVOCs)排放清单

中等挥发性有机物（IVOCs）是一类重要的二次有机气溶胶（SOA）的前体物.其中,生物质燃烧是IVOCs的重要来源之一,但目前尚未包括在传统的排放清单中.本研究基于卫星火点排放清单（FINN）以及IVOCs/POA比例法对长三角地区2010至2018年生物质燃烧IVOCs的排放量进行估算,构建长三角地区2010～2018年基于卫星火点的生物质燃烧IVOCs排放清单,并分析其不确定性,为后续模拟长三角地区SOA的来源提供重要的基础数据.结果表明,在2010～2018年期间,长三角地区火点数整体呈现下降趋势,在过去3年（2016～2018年）火点数维持在6000次左右,较2016年之前下降了约60%.从火点数的月分布来看,火点发生最多的月份是5～8月,其次在10月有个小高峰.基于IVOCs/POA比例系数法的计算结果表明,由不同的POA/OC以及IVOCs/POA比例得到的长三角地区生物质燃烧IVOCs排放总量结果差别巨大,平均值为73.4万t（10.5～305.7万t）.基于蒙特卡罗的不确定性模拟,长三角地区生物质燃烧IVOCs排放量的不确定范围在-99%～68%之间.     

复合污染下丛枝菌根真菌对苎麻吸收重金属的影响

利用室内盆栽试验研究Cu、Zn、As、Cd、Sb五种重金属复合胁迫下接种丛枝菌根真菌(arbuscular mycorrhizal fungi,AM真菌)对苎麻侵染率、生物量、地上部磷含量、重金属浓度及转运系数、抗氧化酶系统的影响。研究结果表明:在复合重金属胁迫条件下,AM真菌能够与苎麻形成良好共生关系,显著促进苎麻地上部对磷的吸收,增加苎麻生物量,改变苎麻抗氧化酶系统,同时调节苎麻对重金属的吸收与分配。具体来说,AM真菌对苎麻的侵染率为33.7%。与非接种组相比,接种组苎麻地上部Zn和Cd含量分别增加了50.3%和100.0%,地下部Cu和Sb的含量分别增加了30.4%和114.3%,地上部和地下部As的含量分别降低了121.6%和416.4%。与非接种组相比,接种组苎麻中Zn、As和Cd的转运系数分别增加了58.6%、148.1%和49.8%,Sb的转运系数降低了64.1%。接种AM真菌促进苎麻地上部对磷的吸收,磷含量增加了50.4%。接种组苎麻地上部与地下部生物量也较非接种组分别增加了22.2%和24.0%。同时接种AM真菌提高了苎麻体内超氧化物歧化酶(SOD)、过氧化氢酶(CAT)、过氧化物酶(POD)活性,分别提高了17.47%、31.75%、6.75%。