Abstract
Brick manufacturing is the fastest-growing industrial sector in Bangladesh and among the top three sectors, along with vehicle exhaust and resuspended road dust, contributing to the air pollution and health problems in Dhaka. The brick manufacturing in the Greater Dhaka region, from ~1,000 brick kilns spread across six districts, is confined to the winter season (October to March) as current technologies do not allow production during the monsoon. The total emissions are estimated at 23,300 t of PM2.5, 15,500 t of sulfur dioxide (SO2), 302,000 t of carbon monoxide (CO), 6,000 t of black carbon, and 1.8 million tons of CO2 emissions from these clusters, to produce 3.5 billion bricks per year, using energy-inefficient fixed chimney bull trench kiln technology and predominantly using coal and agricultural waste as fuel. The associated health impacts largely fall on the densely populated districts of Dhaka Metropolitan Area (DMA), Gazipur, and Narayanganj. Using the Atmospheric Transport Modeling System dispersion model, the impact of brick kiln emissions was estimated over DMA—ranging from 7 to 99 μg/m3 (5th and 95th percentile concentration per model grid) at an average of 38 μg/m3; and spatial contributions from the surrounding clusters—with 27 % originating from Narayanganj (to the south with the highest kiln density), 30 % from Gazipur (to the north with equally large cluster spread along the river and canals), and 23 % from Savar. The modeling results are validated using evidence from receptor modeling studies conducted in DMA. An introduction of emerging vertical shaft combustion technology can provide faster benefits for public health in DMA and reduce climate precursor emissions by selecting the most influential clusters discussed in this paper.
This is a preview of subscription content, log in via an institution to check access.
Similar content being viewed by others
References
Azad AK, Kitada T (1998) Characteristics of the air pollution in the city of Dhaka, Bangladesh in winter. Atmos Environ 32:1991–2005
Begum BA, Biswas SK, Hopke PK (2006) Temporal variations and spatial distribution of ambient PM2.2 and PM10 concentrations in Dhaka, Bangladesh. Sci Total Environ 358:36–45
Begum B, Biswas S, Hopke P (2008) Assessment of trends and present ambient concentrations of PM2.2 and PM10 in Dhaka, Bangladesh. Air quality. Atmos Health 1:125–133
Begum BA, Biswas SK, Hopke PK (2011) Key issues in controlling air pollutants in Dhaka, Bangladesh. Atmos Environ 45:7705–7713
Billah Ibn Azkar MAM, Chatani S, Sudo K (2012) Simulation of urban and regional air pollution in Bangladesh. J Geophys Res 117:D07303
CAI-Asia (2008) Clean brick making technology—success of VSBK in Kathmandu. Clean Air Initiative for Asia Cities, Manila
Calori G, Carmichael GR (1999) An urban trajectory model for sulfur in Asian megacities: model concepts and preliminary application. Atmos Environ 33:3109–3117
GAINS (2010) Greenhouse gas and air pollution interactions and synergies—South Asia program. International Institute of Applied Systems Analysis, Laxenburg
Guttikunda S, Gurjar B (2012) Role of meteorology in seasonality of air pollution in megacity Delhi, India. Environ Monit Assess 184:3199–3211
Guttikunda SK, Thongboonchoo N, Arndt RL, Calori G, Carmichael GR, Streets DG (2001) Sulfur deposition in Asia: seasonal behavior and contributions from various energy sectors. Water Air Soil Pollut 131:383–406
Guttikunda SK, Carmichael GR, Calori G, Eck C, Woo J-H (2003) The contribution of megacities to regional sulfur pollution in Asia. Atmos Environ 37:11–22
Hasan S, Mulamoottil G (1994) Environmental problems of Dhaka city: a study of mismanagement. Cities 11:195–200
Heffter JL (1983) Branching atmospheric trajectory (BAT) model, NOAA Tech. Memo. ERL ARL-121, Air Resources Laboratory, Rockville
HEI (2004) Health effects of outdoor air pollution in developing countries of Asia: a literature review, special report 15. Health Effects Institute, Boston
HEI (2010) Outdoor air pollution and health in the developing countries of Asia: a comprehensive review, special report 18. Health Effects Institute, Boston
Hidy GM, Pennell WT (2010) Multipollutant air quality management. J Air and Waste Manag Assoc 60:645–674
Holloway T, Levy Ii H, Carmichael G (2002) Transfer of reactive nitrogen in Asia: development and evaluation of a source-receptor model. Atmos Environ 36:4251–4264
IPCC (2007) Climate change 2007: impacts, adaptation & vulnerability (fourth asseessment report). Cambridge University Press, Cambridge
Johnson TM, Guttikunda SK, Wells G, Bond T, Russell A, West J, Watson J (2011) Tools for improving air quality management. A review of top-down source apportiontment techniques and their application in developing countries. ESMAP Publication Series, The World Bank, Washington DC
Le H, Oanh N (2010) Integrated assessment of brick kiln emission impacts on air quality. Environ Monit Assess 171:381–394
Li J, Guttikunda SK, Carmichael GR, Streets DG, Chang Y-S, Fung V (2004) Quantifying the human health benefits of curbing air pollution in Shanghai. J Environ Manag 70:49–62
Maithel S, Uma R, Bond T, Baum E, Thao VTK (2012) Brick kilns performance assessment, emissions measurements, & a roadmap for cleaner brick production in India. Study report prepared by Green Knowledge Solutions, New Delhi
NCEP (2012) National Centers for Environmental Prediction. National Oceanic and Atmospheric Administration, Maryland, USA
Ramanathan V, Carmichael G (2008) Global and regional climate changes due to black carbon. Nat Geosci 1:221–227
Shindell D, Kuylenstierna JCI, Vignati E, van Dingenen R, Amann M, Klimont Z, Anenberg SC, Muller N, Janssens-Maenhout G, Raes F, Schwartz J, Faluvegi G, Pozzoli L, Kupiainen K, Höglund-Isaksson L, Emberson L, Streets D, Ramanathan V, Hicks K, Oanh NTK, Milly G, Williams M, Demkine V, Fowler D (2012) Simultaneously mitigating near-term climate change and improving human health and food security. Science 335:183–189
UN HABITAT (2008) State of the world’s cities 2008/2009—harmonious cities. UN HABITAT, Nairobi
UNDP (2011) Improving kiln efficiency in the brick making industry. GEF-United National Development Program, UNDP, Dhaka
WHO (2011) Outdoor air pollution in the world cities. World Health Organization, Geneva
World Bank (2006) Country environmental assessment, Bangladesh. The World Bank, Washington DC
World Bank (2007) Small study on air quality of impacts of the North Dhaka brickfield cluster by modeling of emissions and suggestions for mitigation measures including financing models. Consultant report prepared by Bangladesh University of Engineering and Technology for the World Bank, Washington DC
World Bank (2010) Vertical shaft brick kiln—design manual. ESMAP Publication Series, The World Bank, Washington DC
Zhihong Z (1997) Energy efficiency and environmental pollution of brickmaking in China. Energy 22:33–42
Author information
Authors and Affiliations
Corresponding author
Additional information
Highlights
• An updated map of brick kiln clusters surrounding the Dhaka Metropolitan area • An inventory of brick kiln emissions by district in the Greater Dhaka region • A spatial apportionment of particulate pollution from the kilns by district • An assessment of implications of upgrading the combustion technologies by cluster
Rights and permissions
About this article
Cite this article
Guttikunda, S.K., Begum, B.A. & Wadud, Z. Particulate pollution from brick kiln clusters in the Greater Dhaka region, Bangladesh. Air Qual Atmos Health 6, 357–365 (2013). https://doi.org/10.1007/s11869-012-0187-2
Received:
Accepted:
Published:
Issue Date:
DOI: https://doi.org/10.1007/s11869-012-0187-2