Subscriber access provided by CORNELL UNIVERSITY LIBRARY
Article 3
Identification of major sources of atmospheric NH in an urban environment in northern China during wintertime Xiaolin Teng, Qingjing Hu, Leiming Zhang, Jiajia Qi, Jinhui Shi, Huan Xie, Huiwang Gao, and Xiaohong Yao Environ. Sci. Technol., Just Accepted Manuscript • Publication Date (Web): 15 May 2017 Downloaded from http://pubs.acs.org on May 15, 2017
Just Accepted “Just Accepted” manuscripts have been peer-reviewed and accepted for publication. They are posted online prior to technical editing, formatting for publication and author proofing. The American Chemical Society provides “Just Accepted” as a free service to the research community to expedite the dissemination of scientific material as soon as possible after acceptance. “Just Accepted” manuscripts appear in full in PDF format accompanied by an HTML abstract. “Just Accepted” manuscripts have been fully peer reviewed, but should not be considered the official version of record. They are accessible to all readers and citable by the Digital Object Identifier (DOI®). “Just Accepted” is an optional service offered to authors. Therefore, the “Just Accepted” Web site may not include all articles that will be published in the journal. After a manuscript is technically edited and formatted, it will be removed from the “Just Accepted” Web site and published as an ASAP article. Note that technical editing may introduce minor changes to the manuscript text and/or graphics which could affect content, and all legal disclaimers and ethical guidelines that apply to the journal pertain. ACS cannot be held responsible for errors or consequences arising from the use of information contained in these “Just Accepted” manuscripts.
Environmental Science & Technology is published by the American Chemical Society. 1155 Sixteenth Street N.W., Washington, DC 20036 Published by American Chemical Society. Copyright © American Chemical Society. However, no copyright claim is made to original U.S. Government works, or works produced by employees of any Commonwealth realm Crown government in the course of their duties.
Page 1 of 31
Environmental Science & Technology
1
Identification of major sources of atmospheric NH3 in an urban
2
environment in northern China during wintertime
3 4
Xiaolin Teng1#, Qingjing Hu2#, Leiming Zhang3*, Jiajia Qi1, Jinhui Shi1, Huan Xie1,
5
Huiwang Gao1,4 & Xiaohong Yao1,4*
6
1
7
Ocean University of China, Qingdao 266100, China
8
2
9
Agriculture, Yellow Sea Fisheries Research Institute, Chinese Academy of Fishery
Key Lab of Marine Environmental Science and Ecology, Ministry of Education,
Key Laboratory of Sustainable Utilization of Marine Fisheries Resources, Ministry of
10
Sciences, Qingdao 266071, China
11
3
12
Climate Change Canada, Toronto, Canada
13
4
14
China
15
# contributed equally to the work; * corresponding authors:
[email protected] 16
and
[email protected] (phone number: 86-532-66782565, fax number:
17
86-532-66782810)
Air quality Research Division, Science and Technology Branch, Environment and
Qingdao Collaborative Center of Marine Science and Technology, Qingdao 266100,
18 19
Abstract
20
To assess the relative contributions of traffic emission and other potential sources to
21
high-levels of atmospheric ammonia (NH3) in urban areas in wintertime, atmospheric
22
NH3 and related pollutants were measured at an urban site, ~300 m from a major
23
traffic road, in northern China in November and December 2015. Hourly average NH3
24
varied from 0.3 to 10.8 ppb with an average of 2.4 ppb during the campaign. Contrary
25
to the common perspective in literature, traffic emission was demonstrated to be a
26
negligible contributor to atmospheric NH3. Atmospheric NH3 correlated well with
ACS Paragon Plus Environment
1
Environmental Science & Technology
Page 2 of 31
27
ambient water vapor during many time periods lasting from tens of hours to several
28
days, implying NH3 released from water evaporation being an importance source.
29
Emissions from local green space inside the urban areas were identified to
30
significantly contribute to the observed atmospheric NH3 during ~60% of the
31
sampling times. Evaporation of pre-deposited NHx through wet precipitation
32
combined with emissions from local green space likely caused the spikes of
33
atmospheric NH3 mostly occurring 1-4 hours after morning rush hours or after and
34
during slight shower events. There are still ~30% of the data samples with appreciable
35
NH3 level for which major contributors are yet to be identified.
Winter urban atmospheric NH3
~30%
Unidentified local emission sources
~60%
Traffic
Green space
36
Dew or rain droplets Evaporation of pre-deposited NHx
37
Keywords: Atmospheric NH3, emission potentials of NH3, NHx deposition, vehicle
38
emission, ion chromatograph
39 40
Introduction
41
Atmospheric ammonia (NH3) and acidic gases such as SO2 and NOx are important
42
gaseous precursors forming secondary inorganic ammonium salts, e.g., NH4NO3,
43
(NH4)2SO4, NH4HSO4, etc., in PM2.5 (atmospheric particles with an aerodynamic
44
diameter smaller than 2.5 µm)1-6. It was reported that these ammonium salts
45
accounted for 40-60% of PM2.5 mass under extremely polluted conditions in China,
46
e.g., when PM2.5 mass concentrations exceeded 300 µg m-3 7-9. Large-scale severe
ACS Paragon Plus Environment
2
Page 3 of 31
Environmental Science & Technology
47
PM2.5 pollution events occurred frequently during wintertime in the last few years in
48
northern China. A thorough knowledge on the sources of these gaseous precursors is
49
needed for making effective emission control policies to alleviate PM2.5 pollution.
50
With decreasing emissions of SO2 and NOx in recent years in China, more attention
51
needs to be paid to NH310-13. Major contributors responsible for increasing NH3
52
mixing ratios in urban environments in China are yet to be identified14-15.
53
Agriculture emissions of NH3 are at low levels in winter due to limited agriculture
54
activities13. Thus, the relative contributions of non-agriculture emissions to
55
atmospheric NH3 become more important13-19. Three-way catalytic converters
56
equipped on on-road vehicles are commonly believed to generate NH310-29. In addition,
57
the use of urea to remove NOx in diesel plumes can be another emission source of
58
NH3 in urban atmospheres26. Some studies suggested traffic emissions as important
59
sources of NH3 in different urban atmospheres in China14-15, 25. However, our previous
60
studies reported negligible contributions from traffic emissions to atmospheric NH3 at
61
a sampling site ~190 m from a highway with the highest traffic flow (~4.0*105
62
vehicles/day) in Toronto and an urban site in downtown Toronto, Canada18, 31. Our
63
previous findings motivate us to design a study to examine the contribution of traffic
64
emissions to urban atmospheric NH3 in winter in China. To date, there is still no
65
consensus whether traffic emissions are among the major sources of urban
66
atmospheric NH3 in winter season.
67 68
In this study, a winter campaign was launched to measure hourly NH3 and other
69
supporting data in an urban environment in northern China. The objectives of the
70
present study are to 1) examine whether traffic emission is a significant contributor to
71
urban atmospheric NH3 in northern China; 2) explore major contributors of
ACS Paragon Plus Environment
3
Environmental Science & Technology
Page 4 of 31
72
atmospheric NH3 during wintertime; and 3) present implications for mitigation of
73
urban atmospheric NH3.
74
Experimental
75
The sampling site is located in an urban area in Qingdao, a city with 9 million
76
population in northern China (Fig. 1). From mid-November to the end of December
77
2015, a suite of semi-continuous and real-time instruments were used to monitor
78
atmospheric NH3, H2O vapor, and other pollutant gases such as CO2, NO, NO2, O3
79
and SO2. All instruments were housed in an air-conditioned lab at the second floor of
80
an academic building. The lab is approximately 300 m away from a major traffic road
81
with moderately heavy traffic flow, for which the counted traffic density on weekdays
82
and weekends are shown in Fig. S1. On weekday morning (07:30-08:00) and
83
afternoon (16:30-17:00) rush hours, the maximum traffic flows reached ~3300-3500
84
vehicles per hour, which were about three times of the minimum traffic from midnight
85
to early morning. On weekends, the maximum traffic decreased by approximately
86
30%. The on-site counting also showed that ~90% of the vehicle fleet consisted of
87
passenger cars and light-duty vehicles. In China, passenger cars and light-duty
88
vehicles are overwhelmingly powered by gasoline and they are enforced to equip with
89
3-way catalytic converters. When winds blow from the northwest, west and southwest,
90
the major traffic road is situated upwind of the lab.
91 92
An URG-9000D Ambient Ion Monitor - Ion Chromatograph (AIM-IC) was operating
93
at a flow rate of 3 L min-1 to semi-continuously measure atmospheric NH3 together
94
with acidic gases, anion and cation in PM2.5 at 1-hr resolution. The AIM-IC is
95
equipped with a wet denuder to absorb NH3 and acidic gases and the denuder solution
96
is injected to IC for chemical analysis. Details about AIM-IC instrument can be found
ACS Paragon Plus Environment
4
Page 5 of 31
Environmental Science & Technology
97
in Markovic et al.31 In this study, the ambient air was drawn through a stainless steel
98
tube in 1.2 m length and then passed through a PM2.5 sharp-cut cyclone on the
99
AIM-IC. The tube’s inlet was ~5 m above the ground level and the surrounding
100
buildings are ~15 m height. As reported32, the length of sampling line had a negligible
101
influence on the low resolution measurement of atmospheric NH3, e.g., time
102
resolution > 30 minutes. The hourly average mixing ratios of atmospheric NH3
103
measured by the AIM-IC were available only on 18-30 November, and 10-12 and
104
18-30 December 2015 while the system experienced maintenance or calibration at
105
other times.
106 107
An NH3 analyzer (NH3-H2O, Model 912-0016, LGR), a greenhouse gas analyzer
108
(CO2-CH4-CO2-H2O, Model 911-0011, LGR), and gas analyzers including NOx
109
(TECO 42C), SO2 (TECO 43CTL) and O3 (TECO 49C) were also used to
110
simultaneously measure related gases. The former two analyzers operating at 1-sec
111
resolution at a flow rate of 0.3 L min-1 were calibrated by a commercial company
112
before use. The latter three analyzers operating at 1-min resolution had a regular
113
calibration following the standard protocol (US EPA, Quality Assurance Guidance
114
Document 2.3). Teflon tubes in length of 2-4.5 m were used to connect the analyzers
115
with ambient air. Teflon filters were used to remove particles in the air upstream of the
116
analyzers. In addition, a PM2.5 sampler (Thermo Scientific™) equipped with two
117
denuders was used to measure NH3 and acidic gases and chemical species including
118
NH4+ in PM2.5 during a few days. The sampler stood at ~1.5 m above the green space
119
and was ~30 m away from the lab. The collected samples were extracted and the
120
extracts were determined by the AIM-IC operating offline. The measured mixing
121
ratios of atmospheric NH3 reflected the 24-hr average values.
ACS Paragon Plus Environment
5
Environmental Science & Technology
Page 6 of 31
122
During the campaign, a total of 120 soil samples at 0-1 cm and 1-2 cm depths were
123
also collected from green spaces in surrounding areas (Fig. 1), i.e., Site A was situated
124
at the roadside green space of the major traffic road, Site B at the green space where
125
the denuder sampler stood, and Site C at the green space outside the lab (Table 1). The
126
morning and afternoon soil samples were collected at 08:30-09:30 and 13:00-14:00,
127
respectively, on each day. For each soil sample, 50 g soil was added to 50 ml
128
deionized water and then mixed for one minute. The solution was filtered into two
129
vials for measuring pH immediately and storing at 4C. After the campaign, the stored
130
solution was diluted by 10 times and the diluted solution was injected to the AIM-IC
131
operating offline to determine ionic species. In addition, more soil samples were
132
collected at two other urban green spaces and three agriculture fields across northern
133
China in January and February 2016. These samples were stored at -4C and then
134
moved to the lab using an ice box.
135 136
Soil emission potential (Γg) and canopy compensation point of NH3 (χg) of the urban
137
green space was calculated according to Nemitz et al.33: [NH+ 4 ]𝑔
138
𝛤𝑔 =
139
𝜒𝑔 = 〈
140
where [NH4+]g and [H+]g were the concentrations of NH4+ and H+ (moles per liter),
141
respectively, in the soil. Tg was the temperature of the ground soil (K). In-situ Tg was
142
not measured, and surface soil T (in the top 1-2 cm depth) usually responses rapidly to
143
changes in ambient T, i.e., within a few hours34. The ambient temperature was thus
144
used as a surrogate for Tg, knowing that this could introduce small uncertainties to the
145
calculated χg.
[H+ ]𝑔
=
[NH+ 4 ]𝑔
(1)
10−PH
161,500
10,378
𝛵𝑔
𝛵𝑔
〉 exp (−
) 𝛤𝑔 × (1.703 × 1010 )
ACS Paragon Plus Environment
(2)
6
Page 7 of 31
Environmental Science & Technology
146
Meteorological data were obtained from an automatic weather station set up at the
147
building roof nearby the major traffic road (Fig. 1). During the measurement period in
148
November 2015, the automatic weather station didn’t operate properly. In the
149
November, ambient temperature recorded from a station ~2 km away from the
150
sampling site was used. The recorded ambient temperature was highly consistent with
151
the local ambient temperature (T) based on a comparison using the data collected in
152
the December, which shows Tlocal = 1.01* Tstation, and with Pearson correlation
153
coefficient (r)=0.96. Wind speed (WS) at the two locations also correlated well if
154
excluding a few outlier (accounting for 0.5% of the total data points), WSlocal = 0.66*
155
WSstation and r=0.84.
156
equation for the period of November 22-24 when measurement was not available.
157
Wind direction between the two locations was generally inconsistent under WS
