Assessment of WRF-CO2 simulated vertical profiles of CO2 over Delhi region using aircraft and global model data

IF 1.1 Q4 METEOROLOGY & ATMOSPHERIC SCIENCES
Srabanti Ballav, Prabir K. Patra, Manish Naja, Sandipan Mukherjee, Toshinobu Machida
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引用次数: 0

Abstract

High-resolution regional model simulation of CO2 may be more beneficial to reduce the uncertainty in estimation of CO2 source and sink via inverse modeling. However, the study of atmospheric CO2 transport with regional models is rare over India. Here, weather research and forecasting chemistry model adjusted for CO2 (WRF-CO2) is used for simulating vertical profile of CO2 and its assessment is performed over Delhi, India (27.4–28.6° N and 77–96° E) by comparing aircraft observations (CONTRAIL) and a global model (ACTM) data. During August and September, the positive vertical gradient (~ 13.4 ppm) within ~ 2.5 km height is observed due to strong CO2 uptake by newly growing vegetation. A similar pattern (~ 4 ppm) is noticed in February due to photosynthesis by newly growing winter crops. The WRF-CO2 does not show such steep increasing slope (capture up to 5%) during August and September but same for February is estimated ~ 1.7 ppm. Generally, CO2 is quite well mixed between ~ 2.5 and ~ 8 km height above ground which is well simulated by the WRF-CO2 model. During stubble burning period of 2010, the highest gradient within 2.5 km height above ground was recorded in October (− 9.3 ppm), followed by November (− 7.6 ppm). The WRF-CO2 and ACTM models partially capture these gradients (October − 3.3 and − 2.7 ppm and November − 3.8 and − 4.3 ppm respectively). A study of the seasonal variability of CO2 indicates seasonal amplitudes decrease with increasing height (amplitude is ~ 21 ppm at the near ground and ~ 6 ppm at 6–8 km altitude bin). Correlation coefficients (CC) between the WRF-CO2 model and observation are noted to be greater than 0.59 for all the altitude bins. In contrast to simulated fossil CO2, the biospheric CO2 is in phase with observed seasonality, having about 80% at the lowest level and gradually declines with height due to mixing processes, reaching around 60% at the highest level. The model simulation reveals that meteorology plays a significant role of the horizontal and vertical gradient of CO2 over the region.

利用飞机和全球模型数据评估 WRF-CO2 模拟的德里地区二氧化碳垂直分布图
高分辨率的区域二氧化碳模型模拟可能更有利于通过反演模型减少二氧化碳源和汇估算的不确定性。然而,利用区域模式研究印度大气中的二氧化碳传输却很少见。在此,通过比较飞机观测数据(CONTRAIL)和全球模式(ACTM)数据,利用针对二氧化碳进行调整的天气研究和预报化学模式(WRF-CO2)模拟了印度德里(北纬 27.4-28.6 度,东经 77-96 度)上空的二氧化碳垂直分布,并对其进行了评估。在 8 月和 9 月期间,由于新生长植被对二氧化碳的大量吸收,在约 2.5 千米的高度范围内观测到了正的垂直梯度(约 13.4 ppm)。在二月份,由于新生长的冬季作物的光合作用,也观察到类似的模式(约 4 ppm)。WRF-CO2 在 8 月和 9 月没有显示出如此陡峭的上升斜率(捕获率高达 5%),但 2 月份的估计值为 1.7 ppm。一般来说,二氧化碳在离地面约 2.5 至约 8 千米的高度之间混合良好,WRF-CO2 模型对此进行了很好的模拟。在 2010 年秸秆焚烧期间,离地面 2.5 千米高度范围内的最高梯度出现在 10 月份(- 9.3 ppm),其次是 11 月份(- 7.6 ppm)。WRF-CO2 和 ACTM 模型部分捕捉到了这些梯度(10 月份分别为 - 3.3 ppm 和 - 2.7 ppm,11 月份分别为 - 3.8 ppm 和 - 4.3 ppm)。对二氧化碳季节变化的研究表明,季节振幅随着高度的增加而减小(近地面的振幅约为 21 ppm,6-8 公里高度的振幅约为 6 ppm)。WRF-CO2 模型与观测数据之间的相关系数 (CC) 在所有高度分段都大于 0.59。与模拟的化石二氧化碳相比,生物圈二氧化碳与观测到的季节性相吻合,在最低层约为 80%,并由于混合过程而随高度逐渐下降,在最高层约为 60%。模型模拟结果表明,气象对该地区二氧化碳的水平和垂直梯度起着重要作用。
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来源期刊
Asian Journal of Atmospheric Environment
Asian Journal of Atmospheric Environment METEOROLOGY & ATMOSPHERIC SCIENCES-
CiteScore
2.80
自引率
6.70%
发文量
22
审稿时长
21 weeks
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