1997 Southeast Asian haze

Southeast Asian haze series
Haze in Borneo, 2019
History
1990s 1997 Southeast Asian haze 1997 Indonesian forest fires
2000s 2005 Malaysian haze 2006 Southeast Asian haze 2009 Southeast Asian haze
2010s 2010 Southeast Asian haze 2013 Southeast Asian haze 2015 Southeast Asian haze 2016 Malaysian haze 2016 Southeast Asian haze 2017 Southeast Asian haze 2019 Southeast Asian haze
Key topics
Chemical equator Deforestation in Borneo in Indonesia Mega Rice Project Peat swamp forest Borneo
Responses
ASEAN Agreement on Transboundary Haze Pollution Operation Haze Transboundary Haze Pollution Act 2014 People's Movement to Stop Haze
See also
Air pollution in Malaysia API Singapore PSI Social and environmental impact of palm oil
Category
v t e

The 1997 Southeast Asian haze was an international air pollution disaster that occurred during the second half of 1997, its after-effects causing widespread atmospheric visibility and health problems within Southeast Asia. Considered the most severe Southeast Asian haze event of all time,^[1] the total costs of the 1997 haze are estimated at US$9 billion, due mainly to health care and disruption of air travel and business activities.

The influence of the 1997 fires in Kalimantan and Sumatra on ambient air quality was evident by July and peaked in September/October before weakening by November, when the delayed monsoonal rain extinguished the fires and improved air quality within the region. During the peak episode, satellite imagery (NASA/TOMS aerosol index maps) showed a haze layer that expanded over an area of more than 3,000,000 km² (1,200,000 sq mi), covering large parts of Sumatra and Kalimantan. Its northward extension partially reached Malaysia, Singapore, Brunei, Thailand and the Philippines and its westward extension reached Sri Lanka.^[2] During this period, particulate matter concentrations frequently exceeded national ambient air quality standards. Monthly mean horizontal visibility at most locations in Sumatra and Kalimantan in September was below 1 km (0.62 mi) and daily maximum visibility was frequently below 100 metres (330 ft).

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Countries affected

Causes

The 1997 Southeast Asian haze was caused mainly by slash-and-burn techniques adopted by farmers in Indonesia.^[3] Slash and burn has been extensively used for many years as the cheapest and easiest means to clear the lands for traditional agriculture.^[4] Fire is also used during the long fallow rotation of the so-called jungle rubber in Sumatra and Kalimantan to remove most of the biomass, including the woody parts before new plantations are re-established.^[5]

Fire may also be deliberately used as a weapon to claim property on the islands and provinces where land ownership is not clear, an action taken by both smallholders and large operators alike. After burning out its previous owner, the smallholder or large operator plants their own crops there, gaining de facto control over the disputed land^{[citation needed]}.

During the dry season, dry fuels readily ignite and lead to large wildfires, and due to the 1997–98 El Niño event, the dry season in Southeast Asia was even drier than normal. These accidental fires may have the same underlying socio-economic and institutional problems. In cases like this, fire suppression can be very difficult and costly especially when they reach the highly flammable peat-swamp areas.

Effects

Atmospheric particulate matter was the form of air pollutant that predominantly contributed to the haze and degradation in ambient air quality standards during this crisis. In all countries affected by the smoke haze, an increase of acute health outcomes was observed. Health effects; included emergency room visits due to respiratory symptoms such as asthma, upper respiratory infection, decreased lung function as well as eye and skin irritation, were caused mainly by this particulate matter. In Singapore, for instance, health surveillance showed a 30% increase in hospital attendance due to air quality related symptoms. Generally, children and the elderly, as well as those with pre-existing respiratory and cardiac diseases were the most susceptible to adverse health outcomes from the haze exposure. The smoke haze episode has added to the urban and industrial air pollution in Southeast Asia, causing it to reach alarming levels in many metropolitan areas.

By scattering and absorbing light, the fire-related particulate also resulted in reduced visibility; impairing transportation by air, land and water and seriously affecting the economies of Indonesia, Malaysia and Singapore. Among the economic sectors affected most were air, land and sea transportation, construction, tourism and agricultural industries. EEPSEA/WWF estimated the economic value of the damages caused by the 1997 fires and haze. They estimated one billion US$ from haze-related damages for Indonesia only. The damages to Malaysia and Singapore are figured at 0.4 billion US$. Including the fire related damages, the total damages are estimated to amount to 4.5 billion US$. However, a variety of the damages such as decreased quality of life, loss of biodiversity and atmospheric impacts are difficult to establish.

Fire-related smoke haze episodes also reveal a social component: a large part of the population in Southeast Asia do not have the financial means to buy protective measures such as respiratory masks and air conditioning, nor are they able to refrain from outdoor work when air pollution is high.

References

^ Tacconi, Luca (July 2016). "Preventing fires and haze in Southeast Asia". Nature Climate Change. 6 (7): 640–643. Bibcode:2016NatCC...6..640T. doi:10.1038/nclimate3008. ISSN 1758-6798.
^ Jim, C.Y. (1999). Geography Vol. 84, No. 3 (The Forest Fires in Indonesia 1997-98: Possible Causes and Pervasive Consequences). Geographical Association. pp. 253–55.
^ Jambi Collaboration Booklet_English (reduced).pdf - Asean^{[dead link]}
^ "The Role of Fire in Changing Land Use and Livelihoods in Riau-Sumatra". Retrieved 11 May 2016.
^ "Farmers' perspectives on slash-and-burn as a land clearing method for small-scale rubber producers in Sepunggur, Jambi Province, Sumatra, Indonesia" (PDF). Retrieved 11 May 2016.

Disasters in Malaysia

Health disasters

Air pollution

Haze	1997 Indonesian forest fires 1997 Southeast Asian haze 2005 Malaysian haze 2006 Southeast Asian haze 2009 Southeast Asian haze 2010 Southeast Asian haze 2013 Southeast Asian haze 2015 Southeast Asian haze 2016 Malaysian haze 2017 Southeast Asian haze 2019 Southeast Asian haze
Radioactive contamination	1982 Bukit Merah radioactive pollution

Contagious/Viral diseases

Soil pollution

2015–16 Kuantan bauxite disaster

Water issues

Pollution	2019 Kim Kim River toxic pollution
Scarcity	1998 Klang Valley water crisis 2014 Negeri Sembilan and Selangor water crisis

Natural disasters

Earthquakes	1976 Sabah earthquake 2015 Sabah earthquake
Floods	1971 Kuala Lumpur floods 2006–07 Southeast Asian floods 2010 floods in Thailand and north Malaysia 2013 Cameron Highlands mud floods 2014 Cameron Highlands mud floods Early 2014 Sabah floods 2014–15 floods in Southeast Asia and South Asia 2014–15 Malaysia floods 2015 East Malaysian floods 2016 Malaysian floods 2020–21 Malaysian floods 2021–2022 Malaysian floods 2022 Malaysian east coast floods
Landslides	1993 Pantai Remis landslide Highland Towers collapse 2002 Taman Hillview landslide 2006 Kampung Pasir landslide 2008 Bukit Antarabangsa landslide 2011 Hulu Langat landslide 2022 Batang Kali landslide
Tornadoes	Peninsula Malaysia tornado outbreak of 2014
Tropical storms	Tropical Depression Gloria (1965) Typhoon Sally (1967) Tropical Storm Ruth (1970) Severe Tropical Storm Judy (1971) Typhoon Sally (1972) Typhoon Percy (1983) Severe Tropical Storm Irving (1985) Typhoon Gay (1989) Tropical Storm Forrest (1992) Tropical Depression BOB 03 (1993) Tropical Depression 34W (1995) Tropical Depression Greg (1996) Tropical Storm Linda (1997) Tropical Storm Gil (1998) Tropical Depression Hilda (1999) Tropical Depression 31W (1999) Tropical Depression 32W (1999) Tropical Depression 29W (2001) Tropical Storm Vamei (2001) Typhoon Muifa (2004) Tropical Depression 25W (2005) Typhoon Utor (2006) Typhoon Hagibis (2007) Tropical Depression 01W (2008) Tropical Depression 01W (2010) Tropical Depression 19W (2010) Tropical Depression 25W (2011) Tropical Depression 26W (2011) Tropical Depression 25W (2012) Severe Tropical Storm Sonamu (2013) Tropical Storm Shanshan (2013) Tropical Storm Jangmi (2014) Tropical Depression (2016) Tropical Depression 29W (2017) Typhoon Tembin (2017) Tropical Storm Kai-tak (2017) Tropical Storm Toraji (2018) Tropical Storm Pabuk (2019) Typhoon Lekima (2019) Typhoon Saudel (2020) Typhoon Molave (2020) Tropical Depression 29W (2021)
Tsunamis	Effect of the 2004 Indian Ocean earthquake on Malaysia

Asia pollution topics

Air pollution

Notable incidents

Dust storm	2010 China dust storms
Forest fires and haze	1997 SEA haze 1997 Indonesian forest fires 2005 Malaysian haze 2006 SEA haze 2009 SEA haze 2010 SEA haze 2013 SEA haze 2015 SEA haze 2016 Malaysian haze 2016 SEA haze 2017 SEA haze 2019 SEA haze 2019 Vietnam forest fires
Air radioactive contamination	1982 Bukit Merah radioactive pollution

By countries

Recurrent issues

Counter-measures

Water pollution

Notable incidents

Water radioactive contamination	2011 Fukushima Daiichi nuclear disaster
Marine pollution	2016 Vietnam marine life disaster 2019 Kim Kim River toxic pollution Pollution of the Pasig River

By countries

3°S 105°E / 3°S 105°E / -3; 105

This page was last edited on 14 May 2023, at 22:28

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