Your search keyword '"Lu, Zifeng"' showing total 21 results

1. Provincial Greenhouse Gas Emissions of Gasoline and Plug-in Electric Vehicles in China: Comparison from the Consumption-Based Electricity Perspective.

Author

Gan, Yu, Lu, Zifeng, He, Xin, Hao, Chunxiao, Wang, Yunjing, Cai, Hao, Wang, Michael, Elgowainy, Amgad, Przesmitzki, Steven, and Bouchard, Jessey

Published

2021

2. Measurement and compensation of a stitching error in a DMD-based step-stitching photolithography system

Author

Zhou, Shuang, Lu, Zifeng, Yuan, Qixiang, Wu, Guangkun, Liu, Chunxia, and Liu, Hua

Abstract

The step-stitching issue occurring in digital micromirror device (DMD)-based step lithography, which refers to overlapping and misalignment, has dramatically influenced the overall accuracy of the exposed patterns. To address this technical challenge, this paper proposes a testing method to resolve the system tolerance parameters, inclination angle with 0.060^∘±0.003^∘, and magnification with 3.60399±0.00020, which induce the stitching problem. With these two parameters, a compensation strategy on motion is implemented to precisely control the step distance of the stage so that the edge-to-edge stitching error is reduced to about 0.150 µm and the corner-to-corner stitching error is less than 0.500 µm. The changes of the linewidth induced by the displacement error due to the stage control accuracy and illumination nonuniformity caused by the light source are simulated and analyzed, and the image preprocessing method based on a gradual grayscale mask is employed to improve the quality of stitching. Using this method, the linewidth difference is controlled to be within 0.150 µm. After finishing all the corrections and imaging preprocessing, the transverse error has become almost invisible, and the longitudinal error has been reduced by 97.72%. Experimental results demonstrate that the improved stitching accuracy could achieve high-fidelity devices.

Published

2021

3. Provincial Greenhouse Gas Emissions of Gasoline and Plug-in Electric Vehicles in China: Comparison from the Consumption-Based Electricity Perspective

Author

Gan, Yu, Lu, Zifeng, He, Xin, Hao, Chunxiao, Wang, Yunjing, Cai, Hao, Wang, Michael, Elgowainy, Amgad, Przesmitzki, Steven, and Bouchard, Jessey

Abstract

China has implemented strong incentives to promote the market penetration of plug-in electric vehicles (PEVs). In this study, we compare the well-to-wheels (WTW) greenhouse gas (GHG) emission intensities of PEVs with those of gasoline vehicles at the provincial level in the year 2017 by considering the heterogeneity in the consumption-based electricity mix and climate impacts on vehicle fuel economy. Results show a high variation of provincial WTW GHG emission intensities for battery electric vehicles (BEVs, 22–293 g CO2eq/km) and plug-in hybrid electric vehicles (PHEVs, 82–298 g CO2eq/km) in contrast to gasoline internal combustion engine vehicles (ICEVs, 227–245 g CO2eq/km) and gasoline hybrid electric vehicles (HEVs, 141–164 g CO2eq/km). Due to the GHG-intensive coal-based electricity and cold weather, WTW GHG emission intensities of BEVs and PHEVs are higher than those of gasoline ICEVs in seven and ten northern provinces in China, respectively. WTW GHG emission intensities of gasoline HEVs, on the other hand, are lower in 18 and 26 provinces than those of BEVs and PHEVs, respectively. The analysis suggests that province-specific PEV and electric grid development policies should be considered for GHG emission reductions of on-road transportation in China.

Published

2021

4. Lithographic pattern quality enhancement of DMD lithography with spatiotemporal modulated technology

Author

Guo, Shuping, Lu, Zifeng, Xiong, Zheng, Huang, Long, Liu, Hua, and Li, Jinhuan

Abstract

In this paper, we propose spatiotemporal modulation projection lithography (STPL) technology, which is a spatiotemporal modulation technology applied to the conventional digital micromirror device (DMD) projection lithography system. Through coordinating the micro-movement of the piezoelectric stage, the flexible pattern generation of DMD, and the exposure time, the proposed STPL enables us to fabricate a microstructure with smooth edges, accurate linewidth, and accurate line position. Further application on fabricating a diffraction lens has been implemented. The edge sawtooth of the Fresnel zone plate fabricated by using the STPL is reduced to 0.3 µm, the error between the actual measured linewidth and the ideal linewidth is only within ±0.1µm, and the focal length is 15 mm, which is basically consistent with the designed focal length. These results indicated that STPL can serve a significant role in the micromanufacturing field for achieving high-fidelity microdevices.

Published

2021

5. Enhanced Capabilities of TROPOMI NO2: Estimating NOX from North American Cities and Power Plants.

Author

Goldberg, Daniel L., Lu, Zifeng, Streets, David G., de Foy, Benjamin, Griffin, Debora, McLinden, Chris A., Lamsal, Lok N., Krotkov, Nickolay A., and Eskes, Henk

Published

2019

6. Criteria Air Pollutants and Greenhouse Gas Emissions from Hydrogen Production in U.S. Steam Methane Reforming Facilities.

Author

Sun, Pingping, Young, Ben, Elgowainy, Amgad, Lu, Zifeng, Wang, Michael, Morelli, Ben, and Hawkins, Troy

Published

2019

7. Criteria Air Pollutant and Greenhouse Gases Emissions from U.S. Refineries Allocated to Refinery Products.

Author

Sun, Pingping, Young, Ben, Elgowainy, Amgad, Lu, Zifeng, Wang, Michael, Morelli, Ben, and Hawkins, Troy

Published

2019

8. Impacts of transportation sector emissions on future U.S. air quality in a changing climate. Part I: Projected emissions, simulation design, and model evaluation.

Author

Campbell, Patrick, Zhang, Yang, Yan, Fang, Lu, Zifeng, and Streets, David

Subjects

TRANSPORTATION & the environment, AIR quality, CLIMATE change, EMISSIONS (Air pollution), SIMULATION methods & models

Abstract

Emissions from the transportation sector are rapidly changing worldwide; however, the interplay of such emission changes in the face of climate change are not as well understood. This two-part study examines the impact of projected emissions from the U.S. transportation sector (Part I) on ambient air quality in the face of climate change (Part II). In Part I of this study, we describe the methodology and results of a novel Technology Driver Model (see graphical abstract) that includes 1) transportation emission projections (including on-road vehicles, non-road engines, aircraft, rail, and ship) derived from a dynamic technology model that accounts for various technology and policy options under an IPCC emission scenario, and 2) the configuration/evaluation of a dynamically downscaled Weather Research and Forecasting/Community Multiscale Air Quality modeling system. By 2046–2050, the annual domain-average transportation emissions of carbon monoxide (CO), nitrogen oxides (NO x ), volatile organic compounds (VOCs), ammonia (NH 3 ), and sulfur dioxide (SO 2 ) are projected to decrease over the continental U.S. The decreases in gaseous emissions are mainly due to reduced emissions from on-road vehicles and non-road engines, which exhibit spatial and seasonal variations across the U.S. Although particulate matter (PM) emissions widely decrease, some areas in the U.S. experience relatively large increases due to increases in ship emissions. The on-road vehicle emissions dominate the emission changes for CO, NO x , VOC, and NH 3 , while emissions from both the on-road and non-road modes have strong contributions to PM and SO 2 emission changes. The evaluation of the baseline 2005 WRF simulation indicates that annual biases are close to or within the acceptable criteria for meteorological performance in the literature, and there is an overall good agreement in the 2005 CMAQ simulations of chemical variables against both surface and satellite observations. [ABSTRACT FROM AUTHOR]

Published

2018

9. Impacts of transportation sector emissions on future U.S. air quality in a changing climate. Part II: Air quality projections and the interplay between emissions and climate change.

Author

Campbell, Patrick, Zhang, Yang, Yan, Fang, Lu, Zifeng, and Streets, David

Subjects

TRANSPORTATION industry, EMISSIONS (Air pollution), AIR quality, CLIMATE change, WEATHER forecasting, TRANSPORTATION & the environment

Abstract

In Part II of this work we present the results of the downscaled offline Weather Research and Forecasting/Community Multiscale Air Quality (WRF/CMAQ) model, included in the “Technology Driver Model” (TDM) approach to future U.S. air quality projections (2046–2050) compared to a current-year period (2001–2005), and the interplay between future emission and climate changes. By 2046–2050, t here are widespread decreases in future concentrations of carbon monoxide (CO), nitrogen oxides (NO x = NO + NO 2 ), volatile organic compounds (VOCs), ammonia (NH 3 ), sulfur dioxide (SO 2 ), and particulate matter with an aerodynamic diameter ≤ 2.5 μm (PM 2.5 ) due mainly to decreasing on-road vehicle (ORV) emissions near urban centers as well as decreases in other transportation modes that include non-road engines (NRE). However, there are widespread increases in daily maximum 8-hr ozone (O 3 ) across the U.S., which are due to enhanced greenhouse gases (GHG) including methane (CH 4 ) and carbon dioxide (CO 2 ) under the Intergovernmental Panel on Climate Change (IPCC) A1B scenario, and isolated areas of larger reduction in transportation emissions of NO x compared to that of VOCs over regions with VOC-limited O 3 chemistry. Other notable future changes are reduced haze and improved visibility, increased primary organic to elemental carbon ratio, decreases in PM 2.5 and its species, decreases and increases in dry deposition of SO 2 and O 3 , respectively, and decreases in total nitrogen (TN) deposition. There is a tendency for transportation emission and CH 4 changes to dominate the increases in O 3 , while climate change may either enhance or mitigate these increases in the west or east U.S., respectively. Climate change also decreases PM 2.5 in the future. Other variable changes exhibit stronger susceptibility to either emission (e.g., CO, NO x , and TN deposition) or climate changes (e.g., VOC, NH 3 , SO 2 , and total sulfate deposition), which also have a strong dependence on season and specific U.S. regions. [ABSTRACT FROM AUTHOR]

Published

2018

10. Enhanced Capabilities of TROPOMI NO2: Estimating NOXfrom North American Cities and Power Plants

Author

Goldberg, Daniel L., Lu, Zifeng, Streets, David G., de Foy, Benjamin, Griffin, Debora, McLinden, Chris A., Lamsal, Lok N., Krotkov, Nickolay A., and Eskes, Henk

Abstract

The TROPOspheric Monitoring Instrument (TROPOMI) is used to derive top-down NOXemissions for two large power plants and three megacities in North America. We first re-process the vertical column NO2with an improved air mass factor to correct for a known systematic low bias in the operational retrieval near urban centers. For the two power plants, top-down NOXemissions agree to within 10% of the emissions reported by the power plants. We then derive top-down NOXemissions rates for New York City, Chicago, and Toronto, and compare them to projected bottom-up emissions inventories. In this analysis of 2018 NOXemissions, we find a +22% overestimate for New York City, a −21% underestimate in Toronto, and good agreement in Chicago in the projected bottom-up inventories when compared to the top-down emissions. Top-down NOXemissions also capture intraseasonal variability, such as the weekday versus weekend effect (emissions are +45% larger on weekdays versus weekends in Chicago). Finally, we demonstrate the enhanced capabilities of TROPOMI, which allow us to derive a NOXemissions rate for Chicago using a single overpass on July 7, 2018. The large signal-to-noise ratio of TROPOMI is well-suited for estimating NOXemissions from relatively small sources and for sub-seasonal timeframes.

Published

2019

11. Criteria Air Pollutants and Greenhouse Gas Emissions from Hydrogen Production in U.S. Steam Methane Reforming Facilities

Author

Sun, Pingping, Young, Ben, Elgowainy, Amgad, Lu, Zifeng, Wang, Michael, Morelli, Ben, and Hawkins, Troy

Abstract

The global and U.S. domestic effort to develop a clean energy economy and curb environmental pollution incentivizes the use of hydrogen as a transportation fuel, owing to its zero tailpipe pollutant emissions and high fuel efficiency in fuel cell electric vehicles (FCEVs). However, the hydrogen production process is not emissions free. Conventional hydrogen production via steam methane reforming (SMR) is energy intensive, coproduces carbon dioxide, and emits air pollutants. Thus, it is necessary to quantify the environmental impacts of SMR hydrogen production alongside the use-phase of FCEVs. This study fills the information gap, analyzing the greenhouse gas (GHG) and criteria air pollutant (CAP) emissions associated with hydrogen production in U.S. SMR facilities by compiling and matching the facility-reported GHG and CAP emissions data with facilities’ hydrogen production data. The actual amounts of hydrogen produced at U.S. SMR facilities are often confidential. Thus, we have developed four approaches to estimate the hydrogen production amounts. The resultant GHG and CAP emissions per MJ of hydrogen produced in individual facilities were aggregated to develop emission values for both a national median and a California state median. This study also investigates the breakdown of facility emissions into combustion emissions and noncombustion emissions.

Published

2019

12. Criteria Air Pollutant and Greenhouse Gases Emissions from U.S. Refineries Allocated to Refinery Products

Author

Sun, Pingping, Young, Ben, Elgowainy, Amgad, Lu, Zifeng, Wang, Michael, Morelli, Ben, and Hawkins, Troy

Abstract

Using Greenhouse Gas Reporting Program data (GHGRP) and National Emissions Inventory data from 2014, we investigate U.S. refinery greenhouse gas (GHG) emissions (CO2, CH4, and N2O) and criteria air pollutant (CAP) emissions (VOC, CO, NOx, SO2, PM10, and PM2.5). The study derives (1) combustion emission factors (EFs) of refinery fuels (e.g., refinery catalyst coke and refinery combined gas), (2) U.S. refinery GHG emissions and CAP emissions per crude throughput at the national and regional levels, and (3) GHG and CAP emissions attributable to U.S. refinery products. The latter two emissions were further itemized by source: combustion emission, process emission, and facility-wide emission. We estimated U.S. refinery product GHG and CAP emissions via energy allocation at the refinery process unit level. The unit energy demand and unit flow information were adopted from the Petroleum Refinery Life Cycle Inventory Model (PRELIM version 1.1) by fitting individual U.S. refineries. This study fills an important information gap because it (1) evaluates refinery CAP emissions along with GHG emissions and (2) provides CAP and GHG emissions not only for refinery main products (gasoline, diesel, jet fuel, etc.) but also for refinery secondary products (asphalt, lubricant, wax, light olefins, etc.).

Published

2019

13. Numerical Simulation of Pollutants dilution in a ventilation system.

Author

Qu, Andi, Yang, Kaimin, Fu, Xiaoping, and Lu, Zifeng

Subjects

CARBON dioxide, NUMERICAL analysis, INDOOR air quality, AIR pollutants, VENTILATION

Abstract

Taking CO 2 as tracer gas, and using numerical simulation, the law of indoor air pollutant concentration with the change of ventilation time was obtained. Using the standard κ-ε model and component transport model can simulate the ventilation process of diluting contaminants in a chamber. Through analyzing the results, it is found that the up-supply down-return ventilation does well in ventilation. [ABSTRACT FROM AUTHOR]

Published

2017

14. Indoor Turbulent Natural Convection Heat Transfer with Thermal Radiation in Rooms with Porous Building Envelopes.

Author

Wang, Yuancheng, Yu, Yaofang, Lu, Zifeng, Qu, Andi, and Yun, Yiyi

Subjects

HEAT transfer, ENERGY transfer, HEAT conduction, CURTAIN walls, HEAT radiation & absorption, POROUS materials, NATURAL heat convection

Abstract

Numerical analysis is undertaken of turbulent natural convection heat transfer with thermal radiation in enclosures. The objective is to investigate the turbulent natural heat transfer characteristics for rooms considering surface thermal radiation on the inner walls. A finite-element method was used to numerically solve the governing equations in the two regions. It was found that with the increase of Rayleigh number, Ra, the Nusselt numbers on the inner wall increase; surface thermal radiation can significantly change the temperature fields in both the regions of air flow and porous medium. The mean temperature at the interface decreases with increase of the surface emissivity. The mean convective, radiative and total Nusselt numbers show different trends at the interface with several emissivities. The Nuc at the interface decrease with increase of thickness of porous media until d ≥0.25, and there is no change in Nuc as d is further increased. [ABSTRACT FROM AUTHOR]

Published

2017

15. Effect of the Thickness of Porous Medium on Natural Convection Heat Transfer with Thermal Radiation in Building Envelope.

Author

Lu, Zifeng, Yang, Kaimin, Yu, Yaofang, and Qu, Andi

Subjects

ENERGY conservation, AIRTIGHTNESS of buildings, HEAT transfer, POROUS materials, FINITE element method

Abstract

With the development of living standards and energy conservation awareness, people pay more and more attention to the building energy saving and evaluation of building thermal performance. This paper deals with the effect of the thickness of wall on natural convection heat transfer with thermal radiation in a building room with porous medium envelope. The governing equations for the momentum and heat transfer in both free fluid and porous medium were solved by the finite element method. Comparisons with experimental and numerical results in the literature have been carried out. Effects of the thickness of wall on natural convection and heat transfer in both free fluid and porous medium were analyzed. It was found that The Nu c at the interface decrease with increase of thickness of porous media until d ≤0.25, and there is no change in Nu c as d is further increased. When d reaches a certain value, the flow field and the temperature field won’t change as d increases. [ABSTRACT FROM AUTHOR]

Published

2017

16. Total Mercury Released to the Environment by Human Activities.

Author

Streets, David G., Horowitz, Hannah M., Jacob, Daniel J., Lu, Zifeng, Levin, Leonard, ter Schure, Arnout F. H., and Sunderland, Elsie M.

Published

2017

17. Cradle-to-grave mercury emissions of light-duty gasoline and electric vehicles in China.

Author

Gan, Yu, Lu, Zifeng, Wu, Qingru, He, Xin, Dai, Qiang, Kelly, Jarod C., Ankathi, Sharath K., and Wang, Michael

Subjects

ELECTRIC vehicle batteries, RURAL electrification, GASOLINE, MERCURY, INTERNAL combustion engines, METAL recycling, CARBON offsetting, ELECTRIC vehicles

Abstract

• Lifecycle mercury emissions of electric cars in China are higher than gasoline cars. • Higher Hg emissions of electric cars are mainly due to the coal-based electricity in China. • Emissions from vehicle manufacturing account for most of lifecycle Hg emissions. • Vehicle electrification in China increases automotive mercury emissions. China is actively promoting vehicle electrification, which is deemed to help achieve its ambitious carbon neutrality goal by 2060. Here we show that vehicle electrification in China leads to an increase in automotive emissions of mercury, a persistent, global hazardous pollutant regulated in the United Nations' Minamata Convention. We found that with current technologies, life-cycle mercury emissions of battery electric vehicles of 300 miles of all-electric range are 92% higher than conventional gasoline internal combustion engine vehicles, primarily due to the high mercury emissions from coal-based electricity generation. Notably different from greenhouse gases, mercury emissions are mainly embedded in vehicular material production and vehicle manufacturing, accounting for 50–60% for electric vehicles and ∼90% for gasoline vehicles of their life-cycle mercury emissions. Even with a deeply decarbonized power grid, mercury footprints of electric vehicles would still be higher than those of gasoline vehicles, implying a potential increase in automotive mercury emissions in any countries that promote vehicle electrification. Measures including decarbonizing electric grid, implementing mercury-specific emission control through vehicle supply chain, and increasing metal recycling in electric vehicle batteries will help mitigate the unintended mercury emission increase caused by vehicle electrification. [Display omitted] [ABSTRACT FROM AUTHOR]

Published

2023

18. Transboundary health impacts of transported global air pollution and international trade

Author

Zhang, Qiang, Jiang, Xujia, Tong, Dan, Davis, Steven J., Zhao, Hongyan, Geng, Guannan, Feng, Tong, Zheng, Bo, Lu, Zifeng, Streets, David G., Ni, Ruijing, Brauer, Michael, van Donkelaar, Aaron, Martin, Randall V., Huo, Hong, Liu, Zhu, Pan, Da, Kan, Haidong, Yan, Yingying, Lin, Jintai, He, Kebin, and Guan, Dabo

Abstract

Millions of people die every year from diseases caused by exposure to outdoor air pollution. Some studies have estimated premature mortality related to local sources of air pollution, but local air quality can also be affected by atmospheric transport of pollution from distant sources. International trade is contributing to the globalization of emission and pollution as a result of the production of goods (and their associated emissions) in one region for consumption in another region. The effects of international trade on air pollutant emissions, air quality and health have been investigated regionally, but a combined, global assessment of the health impacts related to international trade and the transport of atmospheric air pollution is lacking. Here we combine four global models to estimate premature mortality caused by fine particulate matter (PM2.5) pollution as a result of atmospheric transport and the production and consumption of goods and services in different world regions. We find that, of the 3.45 million premature deaths related to PM2.5pollution in 2007 worldwide, about 12 per cent (411,100 deaths) were related to air pollutants emitted in a region of the world other than that in which the death occurred, and about 22 per cent (762,400 deaths) were associated with goods and services produced in one region for consumption in another. For example, PM2.5pollution produced in China in 2007 is linked to more than 64,800 premature deaths in regions other than China, including more than 3,100 premature deaths in western Europe and the USA; on the other hand, consumption in western Europe and the USA is linked to more than 108,600 premature deaths in China. Our results reveal that the transboundary health impacts of PM2.5pollution associated with international trade are greater than those associated with long-distance atmospheric pollutant transport.

Published

2017

19. Global climate forcing of aerosols embodied in international trade

Author

Lin, Jintai, Tong, Dan, Davis, Steven, Ni, Ruijing, Tan, Xiaoxiao, Pan, Da, Zhao, Hongyan, Lu, Zifeng, Streets, David, Feng, Tong, Zhang, Qiang, Yan, Yingying, Hu, Yongyun, Li, Jing, Liu, Zhu, Jiang, Xujia, Geng, Guannan, He, Kebin, Huang, Yi, and Guan, Dabo

Abstract

International trade separates regions consuming goods and services from regions where goods and related aerosol pollution are produced. Yet the role of trade in aerosol climate forcing attributed to different regions has never been quantified. Here, we contrast the direct radiative forcing of aerosols related to regions’ consumption of goods and services against the forcing due to emissions produced in each region. Aerosols assessed include black carbon, primary organic aerosol, and secondary inorganic aerosols, including sulfate, nitrate and ammonium. We find that global aerosol radiative forcing due to emissions produced in East Asia is much stronger than the forcing related to goods and services ultimately consumed in that region because of its large net export of emissions-intensive goods. The opposite is true for net importers such as Western Europe and North America: global radiative forcing related to consumption is much greater than the forcing due to emissions produced in these regions. Overall, trade is associated with a shift of radiative forcing from net importing to net exporting regions. Compared to greenhouse gases such as carbon dioxide, the short atmospheric lifetimes of aerosols cause large localized differences between consumption- and production-related radiative forcing. International efforts to reduce emissions in the exporting countries will help alleviate trade-related climate and health impacts of aerosols while lowering global emissions.

Published

2016

20. Cross-scale and cross-precision structures/systems fabricated by high-efficiency and low-cost hybrid 3D printing technology

Author

Tan, Mingyue, Cao, Jiaji, Zhao, Shaoqing, Huang, Long, Zhang, Han, Liu, Minzhe, Jia, Zhongqing, Zhai, Ruizhan, Lu, Zifeng, and Liu, Hua

Abstract

Three-dimensional (3D) printing is widely used in many fields such as micro-optics, microbiology, and microfluidics. However, using existing technologies is a challenge to efficiently fabricate high-quality 3D structures with cross-scale and cross-precision. In this paper, we propose a low-cost hybrid processing technology that combines two-photon polymerization (TPP) and DMD micro stereolithography (DMDMSL) (TPP-DMDMSL). This low-cost hybrid processing technology is a two-part alignment achieved by combining marker positioning and image processing, and then by coordinating the transformation of processing data. Using the same mark as a bridge, the two independent technologies are linked to realize hybrid processing. The high synergetic combination of the two technologies is realized by using the mask as the benchmark and combining it with the flexible real-time transformation of processing data. The horizontal and vertical alignment accuracy is 2 µm and 3 µm, respectively. TPP-DMDMSL unites the high precision of TPP with the high efficiency of DMDMSL. Taking the aspheric lens as an example (radius = 163 µm, height = 33 µm), TPP-DMDMSL reduces the time from 4 h to 1 h. The maximum surface error is 0.22 µm, which does not affect the image quality according to the Rayleigh criterion. TPP-DMDMSL manufactures different types of structures. These results prove that TPP-DMDMSL can print multiple types of 3D structures across scales and precision, which is challenging or time-consuming with existing technologies. TPP-DMDMSL will likely be extended to more micro and nano fields based on the original general technology. TPP-DMDMSL provides strong basic techniques and ideas for integrated hybrid processing systems in the future.

Published

2022

21. Disentangling the Impact of the COVID‐19 Lockdowns on Urban NO2From Natural Variability

Author

Goldberg, Daniel L., Anenberg, Susan C., Griffin, Debora, McLinden, Chris A., Lu, Zifeng, and Streets, David G.

Abstract

TROPOMI satellite data show substantial drops in nitrogen dioxide (NO2) during COVID‐19 physical distancing. To attribute NO2changes to NOxemissions changes over short timescales, one must account for meteorology. We find that meteorological patterns were especially favorable for low NO2in much of the United States in spring 2020, complicating comparisons with spring 2019. Meteorological variations between years can cause column NO2differences of ~15% over monthly timescales. After accounting for solar angle and meteorological considerations, we calculate that NO2drops ranged between 9.2% and 43.4% among 20 cities in North America, with a median of 21.6%. Of the studied cities, largest NO2drops (>30%) were in San Jose, Los Angeles, and Toronto, and smallest drops (<12%) were in Miami, Minneapolis, and Dallas. These normalized NO2changes can be used to highlight locations with greater activity changes and better understand the sources contributing to adverse air quality in each city. Nitrogen dioxide (NO2) is an air pollutant whose prevalence in urban areas is linked to fossil fuel combustion. The NO2in our atmosphere is primarily a function of the magnitude of nitrogen oxide (NOx) emissions and weather factors such as sun angle, wind speed, and temperature. In this work, we developed two novel methods to account for weather impacts on daily pollution levels during COVID‐19 precautions. Once we accounted for favorable weather conditions that in some cases kept air pollution low independent of tailpipe emissions, calculated air pollutant emission reductions varied dramatically (9–43%) among 20 North American cities. Results can be used to understand factors contributing to inconsistent NO2changes during physical distancing, which can inform the effectiveness of COVID‐19 protocols and aid future policy development. These methodologies will allow us to respond more quickly in future unintended experiments when emissions change suddenly. Meteorological patterns were especially favorable for low NO2in much of the United States in spring 2020, complicating comparisons with spring 2019Weather variations between years can cause column NO2differences of ~15% over monthly timescalesNO2drops attributed to COVID‐19 lockdowns ranged between 9.2% and 43.4% among 20 cities in North America, with a median of 21.6%

Published

2020