Indoor Air Pollution (IAP) Updates

PCIA Bulletin Issue 20, July 2009. (pdf, 494KB)

Health impacts associated with exposure to indoor air pollution include acute respiratory infections (ARI), including pneumonia; chronic obstructive pulmonary disease (COPD); lung cancer (for users of open coal stoves); cataracts; tuberculosis; asthma; and adverse pregnancy outcomes (stillbirth, low birthweight). Because of these and other serious health impacts associated with household energy use, and the interest in this topic generated at the 4th Biennial Partnership for Clean Indoor Air Forum held in Kampala, Uganda in March 2009, this issue of the Bulletin focuses on highlighting recent research findings on some of these serious health impacts.

Household Energy Health Impacts
Feature Articles:
-IAP and Cardiovascular Impacts
-Biomass and HIV
-IAP and Children’s Health
-IAP and Lung Function Testing
-CO Emissions and Stove Testing
-IAP and Visual Impairment
-Biomass and Burns and Falls
-ARI Reduction in Pakistan
-Health Impact Tracking in India
Happenings
What’s New
Fact Box
Health Impacts QUIZ!

A successful microfinance mechanism is PFAN (Private Financing Advisory Network), a finance coaching and investor matchmaking service that works well in many developing markets as well as India and China. A new REEEP project will expand PFAN activities to Uganda and Mozambique, and aim to attract between $10-60 million of funding to clean energy projects in those two countries during its first year.

Establishing microfinancing systems on the islands of Fiji, Vanuatu and Samoa over the next 15 months is the aim of the PREM (Pacific Renewable Energy and Microfinance) project. It kicks off with a baseline study on renewables and energy efficiency in these countries, and following this, a set of training tools will be created to assist MFIs in developing their own sustainable loan products.

In Brazil, REEEP will target the agricultural sector in a project combining international and local sources of financing to make solar water pumps for irrigation, solar dryers for fruits, and bio-digestors for agricultural waste available to small farmers.  

With microfinancing at one end of the spectrum, other REEEP projects will aim to unlock the potential of large-scale investment in renewables.  Institutional investors such as pension funds, insurance companies, and savings and investment banks see high risks associated with the emerging markets and with renewable energy.  A REEEP project will seek to develop risk mitigation strategies and financing products through intermediaries such as E+Co, to attract these major players to the renewables market. 

In a similar vein, REEEP has also provided funding for the establishment of a Public-Private Mezzanine Finance facility for renewable energy projects in Morocco, Tunisia and Egypt. A shortage of investor equity capital and government subsidies are barriers to project financing renewable energy projects in the region. Mezzanine finance is a ‘quasi-equity’ structure that could help alleviate the current lack of developer equity.

Finally, a REEEP project together with the China Development Bank will develop new financial tools and risk mitigation instruments for renewable energy project finance, and help build a network of market-based banks interested in renewable energy project finance.

“We are convinced that targeted interventions like these will help to mobilise funding for renewables and energy effiency in the emerging markets,” said Marianne Osterkorn, Director General of REEEP.

Source – ScienceDaily (June 30, 2009) — Particulate pollution thought to be holding climate change in check by reflecting sunlight instead enhances warming when combined with airborne soot, a new study has found. 

Like a black car on a bright summer day, soot absorbs solar energy. Recent atmospheric models have ranked soot, also called black carbon, second only to carbon dioxide in potential for atmospheric warming. But particles, or aerosols, such as soot mix with other chemicals in the atmosphere, complicating estimates of their role in changing climate.

“Until now, scientists have had to assume how soot is mixed with other chemical species in individual particles and estimate how that ultimately impacts their warming potential,” said Kimberly Prather, professor in the Department of Chemistry and Biochemistry and the Scripps Institution of Oceanography at the University of California, San Diego. “Our measurements show that soot is most commonly mixed with other chemicals such as sulfate and this mixing happens very quickly in the atmosphere. These are the first direct measurements of the optical properties of atmospheric soot and allow us to better understand the role of soot in climate change.”

Prather and Ryan Moffet, a former graduate student at UC San Diego who is now at the Lawrence Berkeley National Laboratory, measured atmospheric aerosols over Riverside, California and Mexico City. Using an instrument that measures the size, chemical composition and optical properties of aerosols in real time, they showed that jagged bits of fresh soot quickly become coated with a spherical shell of other chemicals, particularly sulfate, nitrate, and organic carbon, through light-driven chemical reactions.

Within several hours of sunrise, most of the atmospheric carbon they measured had been altered in this way, they report in the Proceedings of the National Academy of Sciences online the week of June 29.

Particles of sulfate or nitrate alone reflect light, and some have proposed pumping sulfate aerosols into the atmosphere to slow climate change. But these chemicals play a different role when they mix with soot.

“The coating acts like a lens and focuses the light into the center of the particle, enhancing warming,” Prather said. “Many people think sulfate aerosols are a good thing because they are highly reflective and cool our planet. However we are seeing that sulfate is commonly mixed with soot in the same particles, which means in some regions sulfate could lead to more warming as opposed to more cooling as one would expect for a pure sulfate aerosol.”

Their measurements showed that in the atmosphere the lens-like shell of sufate and nitrate enhances absorption of light by coated soot particles 1.6 times over pure soot particles.

Soot comes from fires, including those used to cook food and clear agricultural fields, as well as burning of diesel fuel in trucks and ships. Simple measures such as providing better cook stoves with more complete combustion to those in developing countries would help reduce atmospheric soot levels.

Efforts to reduce soot would pay off soon. Unlike carbon dioxide, which lingers in the atmosphere for centuries, soot falls from the sky in a matter of days to weeks, making the reduction of soot a quicker option for slowing down climate change.

“While reducing CO₂ concentrations is extremely important, changes we make today will not be felt for quite a while, whereas changes we make today on soot and sulfate could affect our planet on timescales of months,” Prather said. “This could buy us time while we grapple with the problems of reducing carbon dioxide and other greenhouse gases.”