Improving indoor air quality for poor families : a controlled experiment in Bangladesh

The World Health Organization's 2004 Global and Regional Burden of Disease Report estimates that acute respiratory infections from indoor air pollution (pollution from burning wood, animal dung, and other bio-fuels) kill a million children annually in developing countries, inflicting a particularly heavy toll on poor families in South Asia and Africa. This paper reports on an experiment that studied the use of construction materials, space configurations, cooking locations, and household ventilation practices (use of doors and windows) as potentially-important determinants of indoor air pollution. Results from controlled experiments in Bangladesh are analyzed to test whether changes in these determinants can have significant effects on indoor air pollution. Analysis of the data shows, for example, that pollution from the cooking area diffuses into living spaces rapidly and completely. Furthermore, it is important to factor in the interaction between outdoor and indoor air pollution. Among fuels, seasonal conditions seem to affect the relative severity of pollution from wood, dung, and other biomass fuels. However, there is no ambiguity about their collective impact. All are far dirtier than clean fuels. The analysis concludes that if cooking with clean fuels is not possible, then building the kitchen with porous construction material and providing proper ventilation in cooking areas will yield a better indoor health environment.Renewable Energy,Energy Production and Transportation,Air Quality&Clean Air,Pollution Management&Control,Sanitation and Sewerage

Indoor air quality for poor families: new evidence from Bangladesh

Indoor air pollution (IAP) from cooking and heating is estimated to kill a million children annually in developing countries. To promote a better understanding of IAP, the authors investigate the determinants of IAP in Bangladesh using the latest air monitoring technology and a national household survey. The study concludes that IAP is dangerously high for many poor families in Bangladesh. Concentrations of respirable airborne particulates(PM10) 300 ug/m3 or greater are common in the sample, implying widespread exposure to a serious health hazard. Poor households in Bangladesh depend heavily on wood, dung, and other biomass fuels. The econometric results indicate that fuel choice significantly affects indoor pollution levels: Natural gas and kerosene are significantly cleaner than biomass fuels. However, household-specific factors apparently matter more than fuel choice in determining PM10 concentrations. In some biomass-burning households, concentrations are scarcely higher than in households that use natural gas. The results suggest that cross-household variation is strongly affected by structural arrangements-cooking locations, construction materials, and ventilation practices. The authors'analysis also suggests that poor families may not have to wait for clean fuels or clean stoves to enjoy significantly cleaner air. Within their sample household population, some arrangements are already producing relatively clean conditions, even when"dirty"biomass fuels are used. Since these arrangements are already within the means of poor families, the scope for cost-effective improvements may be larger than is commonly believed.Sanitation and Sewerage,Public Health Promotion,Health Monitoring&Evaluation,Montreal Protocol,Construction Industry,Montreal Protocol,Transport and Environment,Health Monitoring&Evaluation,TF030632-DANISH CTF - FY05 (DAC PART COUNTRIES GNP PER CAPITA BELOW USD 2,500/AL,Sanitation and Sewerage

Who suffers from indoor air pollution? evidence from Bangladesh

In this paper the authors investigate individuals'exposure to indoor air pollution. Using new survey data from Bangladesh, they analyze exposure at two levels-differences within households attributable to family roles, and differences across households attributable to income and education. Within households, they relate individuals'exposure to pollution in different locations during their daily round of activity. The authors find high levels of exposure for children and adolescents of both sexes, with particularly serious exposure for children under 5. Among prime-age adults, they find that men have half the exposure of women (whose exposure is similar to that of children and adolescents). They also find that elderly men have significantly lower exposure than elderly women. Across households, they draw on results from their previous paper (Dasgupta et al, 2004), which relate pollution variation across households to choices of cooking fuel, cooking locations, construction materials, and ventilation practices. They find that these choices are significantly affected by family income and adult education levels (particularly for women). Overall, the authors find that the poorest, least-educated households have twice the pollution levels of relatively high-income households with highly-educated adults. For children in a typical household, pollutionexposure can be halved by adopting two simple measures-increasing their outdoor time from 3 to 5 or 6 hours a day, and concentrating outdoor time during peak cooking periods. The authors recognize that weather and other factors may intervene occasionally, and that child supervision outdoors may be difficult for some households. However, the potential benefits are so great that neighbors might well agree to pool outdoor supervision once they became aware of the implications for their children's health.Environmental Economics&Policies,Public Health Promotion,Population&Development,Health Monitoring&Evaluation,Water and Industry,Health Monitoring&Evaluation,Water and Industry,Environmental Economics&Policies,Population&Development,TF030632-DANISH CTF - FY05 (DAC PART COUNTRIES GNP PER CAPITA BELOW USD 2,500/AL

Elemental analysis of liquids by external beam PIXE down to PPB level

Summarization: A method is reported for the direct elemental analysis of solutions and liquids by PIXE, utilizing the external proton beam facility at the Van de Graaff accelerator of the Atomic Energy Centre, Dacca. The samples were irradiated in liquid form through a thin Mylar window holding the liquid in a small polyethylene cup. The proton beam was allowed to pass from the vacuum into the air through a 7 μm Be window, then through an air path of 23 mm and the Mylar window of the sample cup, into the solution. Mylar windows up to 1 mg/cm2 in thickness were used. The X-rays were detected at 90° relative to the beam with a Si(Li) detector. Minimum detection limits and efficiency curves are reported, and the behaviour of some ions during irradiation is discussed. It is shown that under favourable conditions the sensitivity of the method can reach the ppb level.Παρουσιάστηκε στο: Nuclear Instruments and Method