School of Civil Engineering and Geosciences, Newcastle University, Newcastle upon Tyne, NE1 7RU, United Kingdom.
Sci Total Environ. 2012 Aug 1;431:166-75. doi: 10.1016/j.scitotenv.2012.05.037. Epub 2012 Jun 7.
This paper investigates the potential for engineered urban soils to capture and store atmospheric carbon (C). Calcium (Ca) and magnesium (Mg) bearing waste silicate minerals within the soil environment can capture and store atmospheric C through the process of weathering and secondary carbonate mineral precipitation. Anthropogenic soils, known to contain substantial quantities of Ca and Mg-rich minerals derived from demolition activity (particularly cement and concrete), were systematically sampled at the surface across a 10 ha brownfield site, Science Central, located in the urban centre of Newcastle upon Tyne, U.K. Subsequent analysis yielded average carbonate contents of 21.8±4.7% wt CaCO(3). Isotopic analysis demonstrated δ(18)O values between -9.4‰ and -13.3‰ and δ(13)C values between -7.4‰ and -13.6‰ (relative to Pee Dee Belemnite), suggesting that up to 39.4±8.8% of the carbonate C has been captured from the atmosphere through hydroxylation of dissolved CO(2) in high pH solutions. The remaining carbonate C is derived from lithogenic sources. 37.4 kg of atmospheric CO(2) has already been captured and stored as carbonate per Mg of soil across the site, representing a carbon dioxide (CO(2)) removal rate of 12.5 kg CO(2) Mg(-1) yr(-1). There is the potential for capture and storage of a further 27.3 kg CO(2) Mg(-1) in residual reactive materials, which may be exploited through increased residence time (additional in situ weathering). Overall, the Science Central site has the potential to capture and store a total of 64,800 Mg CO(2) as carbonate minerals. This study illustrates the potential for managing urban soils as tools of C capture and storage, an important ecosystem service, and demonstrates the importance of studying C storage in engineering urban anthropogenic soils.
本文研究了工程化城市土壤捕获和储存大气碳(C)的潜力。土壤环境中含有钙(Ca)和镁(Mg)的硅酸盐废矿物可以通过风化和次生碳酸盐矿物沉淀的过程来捕获和储存大气 C。人为土壤中含有大量源自拆除活动(特别是水泥和混凝土)的富 Ca 和 Mg 矿物,本研究在英国泰恩河畔纽卡斯尔市中心的 10 公顷棕地现场 Science Central 进行了系统采样,对表层土壤进行了采样。随后的分析得出了平均碳酸盐含量为 21.8±4.7%wt CaCO3。同位素分析表明,δ18O 值在-9.4‰至-13.3‰之间,δ13C 值在-7.4‰至-13.6‰之间(相对于 Pee Dee Belemnite),这表明高达 39.4±8.8%的碳酸盐 C 是通过高 pH 溶液中溶解 CO2 的羟化作用从大气中捕获的。其余的碳酸盐 C 来源于岩石成因来源。该场地每毫克土壤已捕获和储存了 37.4 公斤大气 CO2 作为碳酸盐,代表着 12.5 公斤 CO2 Mg-1 yr-1 的二氧化碳(CO2)去除率。在残留的反应性物质中,还有进一步捕获和储存 27.3 公斤 CO2 Mg-1 的潜力,可以通过增加停留时间(额外的原位风化)来实现。总体而言,Science Central 场地具有捕获和储存总共 64800 Mg CO2 作为碳酸盐矿物的潜力。本研究说明了将城市土壤管理为 C 捕获和储存的工具的潜力,这是一项重要的生态系统服务,并证明了研究工程化城市人为土壤中 C 储存的重要性。
