大气CO_(2)浓度升高对黑土有机碳稳定性的影响

【目的】阐明大气CO_(2)浓度升高对黑土有机碳稳定性的影响,为黑土碳中和应对气候变化提供理论依据。【方法】以黑土为研究对象,依托中国科学院海伦农业生态试验站长期定位模拟气候变化开顶箱(OTC)试验平台,设2个处理,分别为对照处理(CK,CO_(2)浓度400μmol/mol)和CO_(2)浓度升高处理(eCO_(2),CO_(2)浓度700μmol/mol),采用13C同位素示踪法,研究大气CO_(2)浓度升高对黑土及不同粒级团聚体有机碳稳定性的影响,并对土壤有机碳含量与更新率和半衰期进行相关分析。【结果】与CK相比,eCO_(2)处理使>0.25 mm粒级团聚体含量显著增加11.09%(P<0.05,下同),0.25~0.053 mm粒级团聚体含量显著减少23.85%,提升团聚体的平均重量直径(MWD)和几何平均直径(GMD);大气CO_(2)浓度升高使>0.25 mm粒级团聚体有机碳显著增加11.61%,0.25~0.053 mm粒级团聚体有机碳含量显著减少8.72%,全土及<0.053 mm粒级团聚体有机碳含量无显著变化(P>0.05,下同)。13C丰度随着粒级减小而依次增大,且CO_(2)浓度升高使全土及各个粒级团聚体的13C丰度均显著降低,全土、>0.25 mm粒级及0.25~0.053 mm粒级团聚体的更新率分别显著增加34.62%、21.60%和57.22%,半衰期依次显著降低34.61%、19.63%和36.84%,<0.053 mm粒级团聚体更新率和半衰期未发生显著变化;更新率与全土和>0.25 mm团聚体有机碳含量呈显著正相关,半衰期与全土和>0.25 mm团聚体有机碳含量呈显著负相关。【结论】大气CO_(2)浓度升高对黑土有机碳含量影响不显著,但使大团聚体结构稳定性和有机碳含量增加,加快全土和大团聚体有机碳更新周转,有利于提升黑土肥力。

聚乙烯混配料管材与非混配料管材的性能对比研究

分别以聚乙烯混配料(以下简称混配料)、聚乙烯本色料加黑色母料(以下简称白加黑)、聚乙烯本色料加外部回用料为原料经熔融挤出成型制备了聚乙烯管材,按照最新版标准GB/T 15558.2—2023分别对其进行炭黑分散、炭黑含量、灰分含量、氧化诱导时间、断裂伸长率及微量金属元素含量等测试,对比研究性能差异。结果表明,聚乙烯混配料制成的管材的炭黑分散、炭黑含量、灰分、微量金属元素含量等性能均符合标准;但采用白加黑所生产的PE管材,其炭黑含量分散度增大,达到2.6%以上或者0.7%以下,不能满足标准要求;炭黑分散等级为A3级~D级,且呈现不稳定性,炭黑分散等级明显低于混配料(A1);采用白料+外部回用料或混配料+外部回收料的聚乙烯管道制品灰分合格率为35%;添加了外部回收料的管材制品中,铁、钙等微量元素的含量明显增加;在混配料加20%外部回用料中,铁元素含量高达18.4 mg/kg,钙元素含量高达862 mg/kg,且微量金属元素含量分布不均匀。

基于沉积理论的碳黑痕迹数值方法

将颗粒沉积理论中的经验公式法应用到烟气颗粒的沉积计算中,推导建立了壁面单位面积上沉积的碳黑颗粒质量与时间等因素关系的数学模型.将该模型嵌入FDS软件,实现烟气流过壁面时形成的可视化痕迹的数值模拟.在数值模拟环境中,设定测点,记录任意时刻壁面单位面积颗粒的沉积总量,对碳黑痕迹进行定量分析.与实际火灾事故进行模拟比对,验证了数值模拟结果与实际火灾情况具有较高的吻合度.该方法可以根据不同的火灾场景、壁面粗糙情况、火源位置等现场情况计算研究壁面碳黑痕迹的形成规律,对火灾调查具有理论指导意义和实用价值.

Geochemical Signatures of Early Paleogene Source Rocks in the Sanshui Basin, South China

The Honggang member of the early Paleogene Buxin Formation is the main source rock in the Sanshui Basin, characterized by organic-rich black shales with the cyclic recurrence of organic- poor sediments. The geochemical characteristics of the Honggang member have been documented to determine the organic matter types and depositional environments in this paper. The organic matter of the black shales mainly consists of a mixture of land plant-derived and phytoplankton-derived organic matter. Total organic carbon content （TOC）-sulfur-iron （Fe） relationships suggest that the organicrich black shales were deposited under dysoxic-to-euxinic water conditions. The time that iron minerals remained in contact with H2S in anoxic waters possibly influenced the formation of syngenetic pyrite, and organic carbon controlled the formation of diagenetic pyrite. Organic-poor intervals usually show pyrite sulfur enrichment and higher degree of pyritization values relative to low organic carbon contents. This resulted from HS- diffusing downward from overlying organic-rich sediments and formed Fe sulfides through reactions with sufficient Fe. Trace elements generally exhibit low concentrations and little TOC dependence, suggesting some degree of depletion in these elements in the early Paleogene sediments of the Sanshui Basin. This probably resulted from cyclic recurrences of oxic benthic conditions, which promoted the remobilization of trace elements and caused the low concentration of trace elements.