Air Quality Analysis for Amritsar, India


India APnA City ProgramAmritsar, in the state of Punjab, is home to the Golden Temple (the spiritual center for the Sikh community) and home to an estimated 1.2 million people. The city is 217 km northwest of the state capital, Chandigarh and is 28 km away from the Wagah Border with Pakistan. The city lies on the main Grand Trunk road (GT Road) from Delhi to Amritsar connecting to Lahore in Pakistan. The passengers visiting the temple, with frequent inter-city buses to and from Chandigarh, Delhi, Shimla, Jalandhar and Ludhiana; and many other cities in the north, contribute the day to day commercial and transportation activities in the city. Within the city, majority of the short trips are covered via rickshaws, auto rickshaws, taxis and buses. The main commercial activities of Amritsar include tourism, carpets and fabrics, farm produce, handicrafts, service trades, and light engineering.

The city is among the 20 most polluted cities according to the WHO ranking of cities by pollution. However, with insufficient monitoring of sources, the main sectors (industry, domestic burning and transport) are loath to take blame for this. One major source is transport with an increase in the number of vehicles in the city. The number of unregistered auto rickshaws alone is more than 50,000, while that of the registered ones is almost the double. A majority of these use petrol mixed with kerosene, which is one of the major pollutants. Coupled with other small and heavy vehicles plying along the GT Road, they become one of major reasons of air pollution.

To assess Amritsar’s air quality, we selected a 40km x 40km domain. This domain is further segregated into 1km grids, to study the spatial variations in the emission and the pollution loads.

Monitoring Emissions Meteorology Dispersion References


Monitoring

We present below a summary of the ambient monitoring data available under the National Ambient Monitoring Program (NAMP), operated and maintained by the Central Pollution Control Board (CPCB, New Delhi, India). In Amritsar, there is 1 continuous air monitoring station (CAMS) reporting data for all the criteria pollutants and 3 manual stations reporting data on PM10, SO2, and NO2.

 

 


Satellite Data Derived Surface PM2.5 Concentrations:

The results of satellite data derived concentrations are useful for evaluating annual trends in pollution levels and are not a proxy for on-ground monitoring networks. This data is estimated using satellite feeds and global chemical transport models. Satellites are not measuring one location all the time, instead, a combination of satellites provide a cache of measurements that are interpreted using global chemical transport models (GEOS-Chem) to represent the vertical mix of pollution and estimate ground-based concentrations with the help of previous ground-based measurements. The global transport models rely on gridded emission estimates for multiple sectors to establish a relationship with satellite observations over multiple years. These databases were also used to study the global burden of disease, which estimated air pollution as the top 10 causes of premature mortality and morbidity in India. A summary of PM2.5 concentrations from this exercise, for the city of Amritsar is presented below. The global PM2.5 files are available for download and further analysis @ Dalhousie University.


Emissions

We compiled an emissions inventory for the Amritsar region for the following pollutants – sulfur dioxide (SO2), nitrogen oxides (NOx), carbon monoxide (CO), non-methane volatile organic compounds (NMVOCs), carbon dioxide (CO2); and particulate matter (PM) in four bins (a) coarse PM with size fraction between 2.5 and 10 μm (b) fine PM with size fraction less than 2.5 μm (c) black carbon (BC) and (d) organic carbon (OC), for year 2015 and projected to 2030.

We customized the SIM-air family of tools to fit the base information collated from the central pollution control board, state pollution control board, census bureau, national sample survey office, ministry of road transport and highways, annual survey of industries, central electrical authority, ministry of heavy industries, municipal waste management, geographical information systems, meteorological department, and publications from academic and non-governmental institutions.

This emissions inventory is based on the available local activity and fuel consumption estimates for the selected urban airshed (presented in the grid above) and does not include natural emission sources (like dust storms, lightning) and seasonal open (agricultural and forest) fires; which can only be included in a regional scale simulation. These emission sources are accounted in the concentration calculation as an external (also known as boundary or long-range) contribution to the city’s air quality.

The emissions inventory was then spatially segregated at a 0.01° grid resolution in longitude and latitude (equivalent of 1 km) to create a spatial map of emissions for each pollutant (PM2.5, PM10, SO2, NOx, CO and VOCs). The gridded PM2.5 emissions and the total (shares by sector) emissions are presented below.

Gridded PM2.5 Emissions (2015)

Emissions Inventory

Total PM2.5 Emissions by Sector 2015-2030

Emissions Inventory Emissions Inventory Emissions Inventory

Total Estimated Emissions by Sector for 2015 (units – mil.tons/year for CO2 and tons/year for the rest)

PM2.5PM10BCOCNOxCOVOCSO2CO2
TRAN 3,900 4,100 1,500 1,300 6,250 85,900 27,950 1001.98
RESI 1,300 1,350 300600450 18,650 2,300 3500.33
INDU 4,400 4,450 500850 4,950 3,500 2,550 2,600 1.77
DUST 1,550 9,700 -------
WAST85090050500- 4,150 850-0.01
DGST500550300100 4,800 1,250 100500.22
BRIC 1,250 1,250 350500 1,000 17,050 1,750 5500.13
13,750 22,300 3,000 3,850 17,450 130,500 35,500 3,650 4.44

TRAN = transport emissions from road, rail, aviation, and shipping (for coastal cities); RESI = residential emissions from cooking, heating, and lighting activities; INDU = industrial emissions from small, medium, and heavy industries (including power generation); DUST = dust emissions from road re-suspension and construction activities; WAST = open waste burning emissions; DGST = diesel generator set emissions; BRIC = brick kiln emissions (not included in the industrial emissions)


Meteorology

We processed the NCEP Reanalysis global meteorological fields from 2010 to 2016 through the 3D-WRF meteorological model. A summary of the data for year 2015, averaged for the district of amritsar is presented below. Download the processed data which includes information on year, month, day, hour, precipitation (mm/hour), mixing height (m), temperature (C), wind speed (m/sec), and wind direction (degrees) – key parameters which determine the intensity of dispersion of emissions.







Dispersion Modeling

We calculated the ambient PM2.5 concentrations and the source contributions, using gridded emissions inventory, 3D meteorological data (from WRF), and the CAMx regional chemical transport model. The model simulates concentrations at 0.01° grid resolution and sector contributions for the urban area, which include contributions from primary emissions, secondary sources via chemical reactions, and long range transport via boundary conditions (represented as “outside” in the pie graph below).

PM2.5 Source Contributions Ambient PM2.5 Concentrations PM2.5 Source Contributions


Findings and Recommendations

  • Modeled urban average ambient PM2.5 concentration is 83.4 ± 8.3 μg/m3 – more than 2 times the national standard (40) and more than 8 times the WHO guideline (10)
  • The city requires at least 18 continuous air monitoring stations to statistically, spatially, and temporally, represent the mix of sources and range of pollution in the city (current status – 3 manual and 1 continuous)
  • The city has an estimated 53% of the ambient annual PM2.5 pollution (in 2015) originating outside the urban airshed, which strongly suggests that air pollution control policies need a regional outlook, including trans-political boundary.
  • Stricter emission standards at the coal-fired thermal power plants in the region will help reduce the share of outside contributions
  • The city needs to aggressively promote public transport as part of the city’s urban development plan, along with the improvement of the road infrastructure to reduce on-road dust re-suspension. The non-motorized transport can play a critical role, given the presence of increasingly large number of short-term visitors every year
  • By 2030, the share of emissions from residential cooking and lighting is expected to decrease with a greater share of LPG, residential electrification, and increasing urbanization. However, biomass and coal burning to provide warmth in the winter will still be an issue
  • By 2030, the vehicle exhaust emissions are expected to remain constant, if and only if, Bharat 6 fuel standards are introduced nationally in 2020, as recommended by the Auto Fuel Policy
  • The small and the medium industry, largely textiles and light engineering need an energy efficiency management plan to address the emissions from coal, heavy fuel oil, and gas combustion or shift towards using electricity
  • About 110 brick kilns in this urban airshed are fueled mostly by coal and agri-waste, can benefit from technology upgrade from the current fixed chimney to (for example) zig-zag, in order to improve the overall energy efficiency of the kilns
  • Open waste burning is dispersed across the city and requires stricter regulations for addressing the issue, as the city generates ever more garbage, with limited capacity to sort and dispose of it.

Back to the APnA page.

All the analysis and results are sole responsibility of the authors @ UrbanEmissions.Info. Please send you comments and questions to simair@urbanemissions.info