植被恢复的土壤固碳效应：动态与驱动机制

植被恢复是影响土壤有机碳库动态变化的关键过程之一,阐明植被恢复过程中土壤有机碳的固持动态及其驱动机制,是全球变化下碳循环研究的热点和前沿问题。本文综述了近年来国内外关于植被恢复过程中土壤有机碳固定动态及其驱动机制方面的研究,剖析植被恢复中土壤有机碳固持动态及其影响因素,探讨植物碳输入对土壤有机碳动态变化的影响机制,揭示植被恢复中土壤有机碳固定的物理、化学和微生物驱动机制,并对目前研究中存在的问题进行总结,进而提出关于植被恢复的土壤固碳效应研究,亟需在土壤有机碳组分的动态、微生物结构和功能,以及植物—土壤—微生物对土壤有机碳固持的协同作用机制等方面进一步加强。本综述可为植被恢复与土壤固碳稳定机制研究指明未来的方向,进而为促进我国植被恢复的土壤碳循环研究,科学评价生态系统土壤固碳潜力和有效实施生态系统碳汇管理提供科学参考。     

双碳目标下退役农机产品拆解规划与EOL决策集成优化

退役农机产品回收再利用,不仅是对其剩余价值的再利用,也是实现可持续发展和循环经济的客观要求,对实现碳达峰、碳中和目标有重要意义。该研究基于双碳目标要求剖析退役农机产品拆解规划和EOL (end-of-life)决策集成优化问题,考虑拆解再制造过程中碳排放成本,以实现经济环境效益的最优化。首先,构建拆解再制造集成优化模型(disassembly remanufacturing integrated optimization, DRIO);其次,提出一种改进的人工蜂群算法(improved artificial bee colony algorithm, IABC)对构建的数学模型进行迭代求解,引入logistic映射生成初始解,雇佣蜂阶段和守望蜂阶段加入邻域搜索机制,侦察蜂阶段采用了轮盘赌方法,以获得利润高且碳排放成本低的拆解再制造帕累托方案;最后,通过联合收获机电机拆解再制造实例验证所提模型的有效性和改进算法的可行性。结果表明,所提DRIO模型的经济效益相较于DRIO-D和DRIO-R模型分别提高了62.1%和54.8%,碳排放成本比DRIO-D模型减少约50%。IABC算法相比于经典...     

黑土长缓坡地形与横垄对土壤有机碳空间分异的交互作用

横坡垄作对坡耕地土壤有机碳（soil organic carbon,SOC）流失有一定的阻控作用,但黑土区特有长而缓的地形与横垄对坡耕地SOC空间分异会产生交互作用,而这种交互作用引发的SOC流失风险没引起足够的重视。该研究以典型黑土区黑龙江省黑河市北安分局红星农场为研究区域,2022年在横坡垄作与顺坡水线方向上共布设25个采样点,采用地理探测器模型、单因素方差分析（one-way ANOVA）和Pearson相关性分析,探讨土壤有机碳的空间分异及其交互作用。结果表明,横坡垄作方向上垄沟土壤有机碳含量从坡顶到水线呈现逐渐增大的变化趋势;在垄台从坡顶到水线呈现先增大后减小的变化趋势。顺坡水线方向,土壤有机碳含量在垄沟呈现从上坡到下坡增大的变化趋势;在垄台呈现先增大后减小的变化趋势。由于断垄产生水线,顺坡土壤有机碳含量上坡与下坡仍有显著差异（P＜0.05）。Pearson相关性分析表明, 有机碳与可蚀性K因子呈显著负相关（垄沟和垄台相关系数分别为–0.228和–0.238,P＜0.05）,与碳循环相关的β-葡萄糖苷酶和微生物生物量碳在垄沟呈极显著正相关（相关系数为0.398和0.676,P<0.01）。地理探测器分析表明,顺坡水线对土壤有机碳空间分异的影响最大,其对垄沟和垄台SOC的解释力分别达到61%和52%以上;顺坡水线与其他因子的交互作用共同增强了对土壤有机碳的解释力,尤其是顺坡水线与高程的交互作用最为明显。黑土区坡耕地土壤有机碳空间分异主要受顺坡水线与高程的交互作用,横坡垄作虽然能够拦截径流,但由于长缓坡地形影响产生的断垄会加剧土壤侵蚀诱发的有机碳流失。因此,黑土坡耕地治理需要同时考虑横垄与地形的共同影响,从而实现防蚀的优化效果。     

天津市产业碳排放的影响因素及贡献

[目的] 综合考虑“水—土—能—碳”相互关系,研究产业碳排放的影响因素及贡献,为天津市减排决策制定提供一定依据。[方法] 对天津市产业碳排放进行测算,将水土资源因素引入Kaya恒等式,运用LMDI模型计算产业碳排放各影响因素的贡献。[结果] 2004—2018年天津市各产业碳排放均呈现上升趋势;整体来看,水资源经济产出、人口数量促进天津市各产业碳排放,且前者为主要促进因素,水土资源因素抑制各产业碳排放,碳排放强度促进农业碳排放,而抑制其他产业碳排放,人均用地面积抑制农业碳排放,而促进其他产业碳排放;水土资源因素对各产业碳排放影响的变化与水土资源匹配度变化有较好的一致性,单位用地面积用水量越多,其对碳排放的促进作用越大。[结论] 为实现节能减排,应发展节水产业,优化城市水土资源开发利用,发挥水土资源因素对碳排放的抑制作用。     

基于GIS与分区Kriging的采煤沉陷区土壤有机碳含量空间预测

中国煤炭产量占世界煤炭总产量的46.9%,年塌陷的耕地面积约为200 km~2,对农田土壤有机碳库扰动十分剧烈。由于农田的土壤有机碳库是减少陆地生态系统碳排放的最大潜在因素,中国以及世界上的其他煤炭开采大国必须更好地对煤炭开采区的土壤有机碳库进行科学管理,这也是煤炭低碳开采的重要途径。而预测精度好的煤炭开采沉陷区土壤有机碳含量空间预测方法是科学管理煤炭开采沉陷区土壤有机碳库的前提。该文以徐州九里煤炭开采沉陷区作为研究区,通过普通Kriging插值法和以结合沉陷积水情况为辅助变量的分区Kriging插值法这2种方法来对研究区的土壤有机碳含量进行了空间预测,并通过比较验证样点的预测值与实测值来对比2种方法的预测精度,确定每种方法的可行性。研究发现,结合区域内部积水情况来进行的分区Kriging插值法求得到的预测值与实测值的相关系数为0.7564,远高于直接进行Kriging插值得到的预测值与实测值的相关系数0.5086,并且两者的均方根误差分别为0.35和0.55,说明前者的预测精度更高。因此结合沉陷积水情况的分区Kriging插值模式是更适宜煤炭开采沉陷区土壤有机碳含量的空间预测模型。     

滇中本地和外来植物群落对紫色土理化性质的影响

在同一"气候-母质"条件下,本文研究了滇中飒马场流域4种处于不同演替阶段的本地植被群落和1种外来植被群落对酸性紫色土理化性质的影响。结果表明:随着灌草丛、云南松、针阔混交林到次生常绿阔叶林的本地植物群落演替过程,土壤的容重、pH、水溶性盐阳离子含量明显降低,而土壤粘粒、水解性酸、活性铝、有机碳、全氮含量显著增加,同时表层土壤有机碳和全氮占其剖面总含量的比例有降低的趋势。次生常绿阔叶林土壤0~150 cm土层的有机碳、全氮贮存量比灌草丛土壤的分别高出35 Mg hm-2和1.2 Mg hm-2,而其pH则比灌草丛土壤的低0.33。这反映出酸性紫色土的富铝化过程、生物富集过程和粘化过程随着植被演进而加强。桉树林土壤有机碳、全氮贮量和pH分别为93.04 mg hm-2、2.45 mg hm-2和4.49,与针阔混交林土壤的有机碳、全氮贮量和pH没有显著差异,但是其水解性酸度和活性铝含量均显著高于针阔混交林土壤的,表明长期种植桉树有加速土壤酸化的可能。     

Effects of wood char and activated carbon on the hydrolysis of cellobiose by β-glucosidase from Aspergillus niger

Biochar amendments to soils have been suggested as a strategy to sequester carbon and therefore mitigate global climate change. The enrichment of soils with charred materials also increases their fertility. This fertilising effect of biochar may be caused by various mechanisms; an acceleration of nutrient cycling has been suggested as one such mechanism. The rate-limiting step in nutrient cycling is thought to be the extracellular enzymatic attack on biological macromolecules. In this study, therefore, the effects of chestnut wood char (specific surface area 2.0 m² g⁻¹) and of activated carbon (specific surface area approximately 900 m² g⁻¹) on an extracellular enzymatic reaction involved in the degradation of cellulose (i.e., hydrolysis of cellobiose by β-glucosidase from Aspergillus niger) were investigated. Cellobiose was not adsorbed by chestnut wood char, whereas activated carbon absorbed more than 97% of it. Both charred materials adsorbed more than 99% of β-glucosidase. For chestnut wood char, adsorption of the enzyme caused a decrease of approximately 30% in the reaction rate, whereas for activated carbon, the nearly complete absorption of both substrate and enzyme entirely inhibited the reaction. These results show that β-glucosidase from A. niger retains most of its activity when adsorbed to chestnut wood char and that the reaction it catalyses in nature is only slightly affected by this charred material. On the other hand, a material characterised by a high specific surface area and high porosity, such as activated carbon, can make even a highly soluble substrate unavailable for soil enzymes and therefore completely inhibit the reaction. Thus, charred materials may affect nutrient cycling mainly by regulating the availability of substrates: the degradation of highly soluble substrates may be accelerated by materials with low specific surface area, which maintain an active and protected enzyme pool, whereas materials with high specific surface and high porosity may slow down the degradation by making substrates unavailable.     

Short term soil priming effects and the mineralisation of biochar following its incorporation to soils of different pH

The aim of this work was to determine the magnitude of the priming effect, i.e. short-term changes in the rate (negative or positive) of mineralisation of native soil organic carbon (C), following addition of biochars. The biochars were made from Miscanthus giganteus, a C4 plant, naturally enriched with ¹³C. The biochars were produced at 350 °C (biochar350) and 700 °C (biochar700) and applied with and without ryegrass as a substrate to a clay-loam soil at pH 3.7 and 7.6. A secondary aim was to determine the effect of ryegrass addition on the mineralisation of the two biochars.After 87 days, biochar350 addition caused priming effects equivalent to 250 and 319 μg CO₂-C g⁻¹ soil, in the low and high pH soil, respectively. The largest priming effects occurred at the start of the incubations. The size of the priming effect was decreased at higher biochar pyrolysis temperatures, which may be a way of controlling priming effects following biochar incorporation to soil, if desired. The priming effect was probably induced by the water soluble components of the biochar. At 87 days of incubation, 0.14% and 0.18% of biochar700 and 0.61% and 0.84% of biochar350 were mineralized in the low and high pH soil, respectively. Ryegrass addition gave an increased biochar350 mineralisation of 33% and 40%, and increased biochar700 at 137% and 70%, in the low and high pH soils, respectively. Certainly, on the basis of our results, if biochar is used to sequester carbon a priming effect may occur, increasing CO₂-C evolved from soil and decreasing soil organic C. However, this will be more than compensated for by the increased soil C caused by biochar incorporation. A similar conclusion holds for accelerated mineralisation of biochar due to incorporation of fresh labile substrates. We consider that our results are the first to unequivocally demonstrate the initiation, progress and termination of a true positive priming effect by biochar on native soil organic C.     

小麦–玉米轮作体系长期施肥对塿土微生物量碳、氮及酶活性的影响

以20年塿土小麦玉米轮作体系长期肥料定位试验为平台,探讨不同施肥模式下土壤化学肥力要素、微生物量碳氮及酶活性的响应。试验包括不施肥（CK）、单施氮肥（N）、氮磷（NP）、磷钾（PK）、氮磷钾（NPK）、NPK+秸秆（SNPK）以及不同量有机肥+NPK（M1NPK、M2NPK）等8种施肥模式。结果表明,与CK相比,长期施用NP提高土壤有机碳含量达34.0%、全氮34.0%、全磷58.5%、速效磷608.9%、微生物量碳23.3%、微生物量氮54.0%、蔗糖酶53.9%、脲酶132.6%、碱性磷酸酶29.9%以及脱氢酶40.9%。长期施用NPK与NP效果相似,钾素效果甚微。作物秸秆还田配合氮磷钾化肥与氮磷钾相比没有明显影响土壤有机碳、氮和磷水平,但是显著提高微生物量碳的含量（29.5%）、碱性磷酸酶（23.0%）和脱氢酶（26.9%）的活性。有机肥配合氮磷钾与其它施肥处理相比,显著提升土壤化学肥力要素、微生物量碳氮和酶活性,特别是引起了磷素的大量富集（速效磷含量大于150 mg/kg）。因此,塿土不施有机物情况下,氮磷配合可以提高土壤化学和生物肥力,作物秸秆还田配合氮磷钾化肥的培肥效果优于氮磷钾化肥配合,而合理的有机无机肥配合是塿土提升化学肥力和保证生物健康的最佳施肥模式。     

广西喀斯特次生林地表碳库和养分库特征及季节动态

以自然保护区原生林为对照,调查了广西喀斯特区处于同一次生演替序列中的灌丛、藤刺灌丛、乔灌丛3个群落的地表凋落物存量,同时对凋落物层和土壤表层(0-5 cm)的有机碳,全氮、磷、钾等养分元素的含量、贮量状态及其雨季前后的变化进行了研究.结果表明:地表凋落物存量及有机碳、全氮贮量随演替阶段上升均呈增高趋势;除全磷外,土壤的有机碳和养分元素含量与凋落物层贮量相关性显著(p<0.05);雨季期间,凋落物迅速分解,地表凋落物的分解量要大于当季凋落量,并且次生林的凋落物分解与养分释放量显著高于原生林;雨季后,各群落有机碳和养分的凋落物层贮量以及土壤含量均有所降低.其中凋落物层贮量下降显著的是藤刺灌丛与乔灌丛.土壤养分含量则在灌丛与原生林阶段下降更为明显.在从灌丛向顶级群落演替的进程中,森林的自养能力可能存在一个先增高再降低的过程.