Your search keyword '"Chen, Yingying"' showing total 2 results

1. Using Stable Sulfur Isotope to Trace Sulfur Oxidation Pathways during the Winter of 2017-2019 in Tianjin, North China.

Author

Ding S, Chen Y, Li Q, and Li XD

Subjects

Aerosols analysis, China, Coal, Hydrogen Peroxide, Nitrogen Dioxide, Particulate Matter analysis, Seasons, Sulfates analysis, Sulfur, Sulfur Isotopes analysis, Sulfur Oxides, Air Pollutants analysis, Environmental Monitoring

Abstract

After the implementation of the Coal Replacing Project (CRP) in the northern parts of China in 2017, its effect on PM 2.5 composition is still unclear. In the study, water-soluble ionic components (WSICs) and stable sulfur isotope ratios (δ 34 S) of SO 4 2- in PM 2.5 collected during the domestic heating period before and after the implementation of CRP in Tianjin were analyzed. Results showed that the average concentrations of both PM 2.5 and WSICs have dropped dramatically after the CRP, especially for the SO 4 2- (by approximately 57-60%). After the CRP, the range of δ 34 S sulfate was significantly narrowed to 4.1-7.5‱ in January 2018 and 1.4-6.1‱ in January 2019, which suggested that the sulfur source was becoming simple. It was interesting that the δ 34 S sulfate value in the pollution period before the CRP was higher than that in the clean period, whereas it showed the opposite tendency after the CRP, which implied that the contribution of sea salt was high during the pollution period before the CRP. The MIXSIAR model calculated that the contributions of the transition-metal ion (TMI) oxidation and NO 2 oxidation pathways in the three sampling stages were higher than those of the OH radical oxidation and H 2 O 2 /O 3 oxidation pathways, indicating that the formation pathway of sulfate was mainly dominated by heterogeneous oxidation. Before the CRP, the NO 2 oxidation pathway was the dominant sulfate oxidation pathway during a haze episode, and the TMI oxidation pathway dominated the formation of sulfates after the CRP.

Published

2022

2. Satellite-Enabled Internet of Remote Things Network Transmits Field Data from the Most Remote Areas of the Tibetan Plateau.

Author

Chen, Yingying, Zhang, Minghu, Li, Xin, Che, Tao, Jin, Rui, Guo, Jianwen, Yang, Wei, An, Baosheng, and Nie, Xiaowei

Subjects

*INTERNET of things, *LAND surface temperature, *INFORMATION retrieval, *SNOW accumulation, *ENVIRONMENTAL monitoring, *SERVER farms (Computer network management)

Abstract

In this article, we employed a satellite-enabled Internet of Remote Things (IoRT) network as a promising solution to retrieve data in the most remote areas of interest, where public networks are absent. This article presents a system network based on the satellite-enabled IoRT, a new paradigm that defines a network where each environmental monitoring device can autonomously establish a network with a remote data center. The Xingyun satellite constellation was employed for data retrieval on the Tibetan Plateau (TP). The monitoring system was mainly composed of a ground Internet of Things (IoT) terminal that was built with satellite transceivers, environmental monitoring devices, and system software. We deployed five of these newly developed terminals in harsh areas to monitor environmental variables, and accordingly, air temperature and relative humidity, precipitation, snow depth, land surface temperature, tree stemflow rate, and photosynthetically active radiation were retrieved with the satellite-enabled IoRT network. Field experiments were conducted to evaluate the performance of the proposed system network, and the results indicated that the average time delay with and without the packet creation mode reached 32 and 32.7 s, respectively, and the average packet loss rate with and without the packet creation mode reached 5.63% and 4.48%, respectively. The successful implementation of the satellite-enabled IoRT network for the rapid retrieval of monitoring data in remote glacier, forestland, and canyon areas at very high altitudes on the TP provides an entirely new and revolutionary data retrieval means for backhauling data from remote areas of interest. [ABSTRACT FROM AUTHOR]

Published

2022