北京市冬季大气化石源CO<sub>2</sub>典型日变化的<sup>14</sup>C示踪研究

牛振川<sup>1; 2</sup>; 周卫健<sup>1; 2; 3</sup>; 程 鹏<sup>1; 2</sup>; 吴书刚<sup>1; 2</sup>; 卢雪峰<sup>1; 2</sup>; 杜 花<sup>1; 2</sup>; 付云翀<sup>1; 2</sup>; 熊晓虎<sup>1; 2</sup>

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引用本文:	牛振川，周卫健，程鹏，吴书刚，卢雪峰，杜花，付云翀，熊晓虎.2016.北京市冬季大气化石源CO₂典型日变化的¹⁴C示踪研究[J].地球环境学报,(5):487-493
	NIU Zhenchuan, ZHOU Weijian, CHENG Peng, WU Shugang, LU Xuefeng, DU Hua, FU Yunchong, XIONG Xiaohu.2016.Tracing a typical diurnal variations in atmospheric fossil fuel CO₂ using radiocarbon during wintertime at an urban site in Beijing[J].Journal of Earth Environment,(5):487-493

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北京市冬季大气化石源CO₂典型日变化的¹⁴C示踪研究
牛振川，周卫健，程鹏，吴书刚，卢雪峰，杜花，付云翀，熊晓虎^1,2,3
1. 中国科学院地球环境研究所黄土与第四纪地质国家重点实验室，陕西省加速器质谱技术及应用重点实验室，西安 710061;2. 西安加速器质谱中心，西安 710061;3. 北京师范大学，北京 100875

摘要:

城市作为化石源CO₂（CO_2ff）排放的热点区域，获得其大气CO_2ff浓度的日变化特征对于深刻理解城市地区CO_2ff的时空变化规律，进而制定合理的节能减排政策至关重要。本研究通过AMS-¹⁴C技术，示踪了北京市冬季一个典型日变化事件中大气CO_2ff的变化过程，并探讨了其影响因素。本次日变化事件中大气δ¹³CO₂的值为（−13.9 ± 0.8）‰（−14.8‰ — −12.7‰），Δ¹⁴CO₂的值为（−151.6 ± 51.3）‰（（−214.2 ± 2.9）‰ — （−82.3 ± 3.0）‰），浓度为104.4 ± 44.0 µL ∙L ⁻¹（168.6 ± 2.7 — 52.1 ± 3.2 µL ∙ L⁻¹）。CO_2ff浓度具有较大的日变化，夜晚CO_2ff浓度明显高于白天，主要是由于夜间大气混合层高度较低、供暖消耗更多的化石燃料以及在东南风条件下因北京不利的扩散条件而使CO_2ff聚积。此外，在早晚高峰期间，观察到由于交通流量增加引起的较高CO_2ff浓度。同期PM_2.5浓度相似的日变化过程进一步验证了本次CO_2ff观测结果的可靠性。

关键词: 化石源CO₂ ¹⁴C示踪北京日变化冬季

DOI：10.7515/JEE201605005

CSTR：32259.14.JEE201605005

分类号:

基金项目:国家自然科学基金项目（41573136，41303072）；中国科学院西部之光项目（XAB2015A02）；中国科学院青年创新促进会（2016360）；黄土与第四纪地质国家重点实验室自主部署重点课题（LQ1301）；中国科学院地球环境研究所青年人才项目（Y354011480，Y652001480）；陕西省自然科学基金青年项目（2014JQ2-4018）

英文基金项目:National Natural Science Foundation of China (41573136, 41303072); West Light Foundation of Chinese Academy of Sciences?(XAB2015A02); Youth Innovation Promotion Association CAS (2016360); MOST Special?Fund for State Key Laboratory of Loess and Quaternary Geology (LQ1301); Young Scholar Project of Institute of?Earth Environment,?CAS (Y354011480, Y652001480); Natural Science Foundation of Shaanxi Province, China (2014JQ2-4018)

Tracing a typical diurnal variations in atmospheric fossil fuel CO₂ using radiocarbon during wintertime at an urban site in Beijing

NIU Zhenchuan, ZHOU Weijian, CHENG Peng, WU Shugang, LU Xuefeng, DU Hua, FU Yunchong, XIONG Xiaohu^1,2,3

1. State Key Laboratory of Loess and Quaternary Geology, Shaanxi Key Laboratory of Accelerator Mass Spectrometry Technology and Application, Institute of Earth Environment, Chinese Academy of Sciences, Xi’an 710061, China;2. Xi’an AMS Center, Xi’an 710061, China;3. Beijing Normal University, Beijing 100875, China

Abstract:

Background, aim, and scope As the main greenhouse gas, how much of the increased atmospheric CO² derived from the fossil fuel emissions is not only an environmental issue, but also an important scientific question. Traditional statistical methods for estimating the magnitude of CO_2ff emissions incur some uncertainties, especially at regional scale. Radiocarbon (¹⁴C), a unique tracer, can be used to distinguish between atmospheric CO_2ff and CO² from other sources, and have been used to infer the spatio-temporal variations of atmospheric CO_2ff in recent years. Cities as emission hotspots, the diurnal atmospheric ¹⁴CO₂ observation are important to the understanding of temporal atmospheric fossil fuel CO₂ (CO_2ff) variability, thus facilitating the mitigation strategies of CO_2ff emissions in China. In this study, one typical diurnal atmospheric ¹⁴CO₂ observation was carried out at an urban site in Beijing, with the objective to trace the diurnal CO_2ff variations, and to determine the factors influencing them. Materials and methods Beijing, a typical inland city, was selected in this study. It is the most central city in the Beijing-Tianjin-Hebei metropolitan region, with a population of more than 20 million. The city is surrounded by mountains in the west and north and faces the North China Plain to the south. The air sampling site is located on the roof of a building at the Research Center for Eco-Environmental Sciences, Chinese Academy of Sciences, Haidian District. The site is located between the North 4th and 5th Ring roads, surrounded by dense office and commercial areas, residential districts, universities and parks. Air samples were collected in aluminum foil sampling bags every 2 hours from 8:00 am (local time) on 15th to 6:00 am (local time) on 16th in January, 2014. The CO₂ concentrations and δ¹³CO₂ in the air samples were measured using a Picarro G2131-I CO² Isotopic Analyzer (Picarro Inc., USA) with cavity ring down spectroscopy (CRDS). This equipment is highly linear and very stable, with very precise CO² measurements. Each sample was measured for 6 min, and only the average of the data from the last 4 min was used. The air samples in the bags were transferred to a high vacuum system with liquid nitrogen cold trap (−196 ºC) and ethanol-liquid nitrogen cold trap (−90 ºC) to get purified CO₂, and then converted into graphite using the zinc-iron method. The ¹⁴C levels of the air samples were measured using a 3 MV AMS in Xi’an, China, with a precision of 2‰—3‰ for ¹⁴C measurement. The values of ¹⁴C in the air samples were expressed as Δ¹⁴C, i.e., the per mil (‰) deviation from the absolute radiocarbon reference standard corrected by the convention of fractionation and decay. CO_2ff concentrations were calculated according to the mass balance of CO² and ¹⁴C. Results The CO₂ concentration in the diurnal event was 508.0 ± 38.9 µL ∙ L⁻¹, with high values at night. δ¹³CO₂ values were in the range of −14.8‰ — −12.7‰, with an average of (−13.9 ± 0.8)‰. They were lower than background δ¹³CO₂ value, due to the contribution of fossil fuel emissions. The δ¹³CO₂ values (−13.1 ± 0.3)‰ in daytime were significantly ( p < 0.05) higher than those (−14.5 ± 0.3)‰ at night. The average Δ¹⁴CO₂ value in this diurnal event was (−151.6 ± 51.3)‰ ((−214.2 ± 2.9)‰ — (−82.3 ± 3.0)‰), with corresponding CO_2ff concentration of 104.4 ± 44.0 µL ∙ L⁻¹ (168.6 ± 2.7 µL ∙ L⁻¹ — 52.1 ± 3.2 µL ∙ L⁻¹). CO_2ff concentration showed high correlation with CO₂, and contributed most of the offset of CO² compared to background CO². These results indicated that the diurnal CO² variations were mainly resulted from the fossil fuel emissions. CO_2ff concentrations showed distinct diurnal variations, with high values at night and low values in daytime. Small peaks of CO_2ff concentrations were observed during the morning and afternoon rush hours, resulted from the emissions from transportation. Discussion The extremely high concentrations at that night resulted from the more fossil fuel consumption for heating and low vertical mixing height at night. Moreover, CO_2ff was readily accumulated when wind direction turned from north to south at that night, because the city is surrounded by mountains in the west and north. Additionally, it is robust for our CO_2ff record, which is indirectly validated by the similar variation trends for simultaneous PM^2.5 concentrations in Beijing. Conclusions Our data showed that the diurnal variations of atmospheric CO_2ff in Beijing were controlled by a combination of emission sources, height of vertical mixing, wind direction and topography. Recommendations and perspectives This study provides an example to understand the temporal variational characteristics of atmospheric CO_2ff and their influencing factoring in Chinese cities.

Key words: fossil fuel CO₂ radiocarbon tracing Beijing diurnal variation wintertime