Recent peat fire trend in the Mega Rice Project (MRP) area in Central Kalimantan, Indonesia Erianto Indra Putra Candidate for the Degree of Doctor of Philosophy Supervisor : Associate Prof. Hiroshi Hayasaka Division of Human Environmental System I. INTRODUCTION In 1996, the Indonesian Government initiated the Mega Rice Project (MRP) in Central Kalimantan to convert one million hectares of peatland between Sebangau and Barito rivers to fields for cultivating rice and promoting transmigration (migration inside of Indonesia). The MRP closed at 1999 but it left vast drained peatland mainly due to the built of the channels to open up this area and make it suitable for cultivation. Frequently large fire occurrences in MRP area is believed released huge amounts of carbon dioxide to the atmosphere. Around 4,74 km2 area in MRP has been damaged from severe fire episodes in 1997 and released.19.23 Gt of carbon to the atmosphere [1]. This huge amount of carbon released to the atmosphere is suggesting that severe peat fires in may lead to the large amount of carbon emission. More than 9% of peat fires in Central Kalimantan from 1997 to 27 occurred in dry season. Ground Water Level (GWL) in peatland area is getting lowered under dry weather condition, dry up peat and organic fuel in its upper layer and creates suitable condition for fires to be ignited. Main goal of this study is to gain better understanding on the peat fire trend in the and underlying it causes and impacts. To achieve this, objectives of this study were as follows: (1) to understand how drought and peat fires were related in the through daily hotspot and weather data analysis, (2) to investigate the relationship among precipitation pattern in the dry season, SST Anomalies, ground water level and peat fire trend in the MRP, (3) to identify the most affected areas from peat fires and to assess the burnt area in MRP, (4) to estimate carbon emission due to peat fire in, and (5) to clarify the effect of peat fire occurrences to the air quality. II. METHODOLOGY Analysis is done for daily hotspots data captured in by SiPongi-NOAA and NASA-MODIS satellite, daily precipitation and SST anomalies data to clarify the relationship among SST anomalies, precipitation and peat fire occurrences. and hotspots data are processed by using five-days moving average to obtain their smoothed daily and seasonal pattern. Ground water level (GWL) is modeled from data measurement done by Takahashi et al. [2]. Mapping of hotspots using 3,117 grids of 1 km 2 by using ArcView is done to determine where the worst fire occurred in the MRP. To assess the burnt area, this study built an algorithm to obtain the of 1.21 km 2 buffer of each of hotspots captured by SiPongi-NOAA and 1 km 2 of NASA-MODIS. To observe impact of peat fire occurrences on air pollution condition in Palangkaraya, daily hotspots and daily air pollution data were analyzed. Number of fire was derived from daily hotspots detected on about 4 km 2 area of MRP surrounding Palangkaraya. Carbon-loss due to peat fire in is estimated by using formula of : C l = ρ A d c, where C l = carbon-loss (ton), ρ = peat bulk density (g/cm 3 or ton/m 3 ), A = burnt area (m 2 ), d = peat burnt depth (m) and c = peat carbon content (%). Peat bulk density assumed here was.1 g/cm 3 and peat carbon content is 57% [1]. CO 2 emission is derived by converting carbon-loss using conversion factor of 3.67 (ratio of molecular weights of CO 2 and carbon). III. RESULTS AND DISCUSSIONS 3.1 Recent hotspot (fire) trend in Kalimantan and Sumatra Fires in tropical forest and peat area in Indonesia are not new phenomenon. Recently forest and land fires in Indonesia have become commonplace and occurred every year. Unfortunately, the old fires history data in Indonesia is not documented well. Official reports on burned forest areas provided by the Ministry of Forestry of Indonesia became available only from 1984. In other hand, the daily satellite data detection was available only from July 1997 when the Ministry of Forestry (MOF) and Japan International Cooperation Agency (JICA) started hotspot detection using NOAA-AVHRR satellite for the western part of Indonesia. From the end of 2, MODIS satellite from NASA/FIRMS started to detect hotspots in Indonesia. However, the complete fire datasets from NASA/FIRMS were available from 21. Fig. 1 showed recent Indonesian forests burns and the number of hotspots detected in western Indonesia by NOAA-AVHRR satellite from the Japan International Cooperation Agency Forest Fire Prevention Management Project (JICA-FFPMP) SiPongi. The hotspots data in Fig. 1 covers Sumatra, Kalimantan, Java, Bali, and Sulawesi Islands. Over 1, km 2 of forest area burned in 1991, 1994, and 1997, with the highest in 1998. Over 6, hotspots or Indonesian fires were recorded in 1997 and 22 or in years, brought the evidence of the close relationship between fire and event. However, recently large number of fires also found in
84 85 96 87 88 89 9 91 92 93 94 95 96 97 98 99 1 2 3 4 5 6 7 Forest Burnt area (km 2 ) Number of Hotspots Non year such as in 21, 23, 24, 25, and 26. The highest number of hotspots is found in 26 (147,731), made 26 as the worst fire year since 1997. These findings strongly suggesting that recently fire in Indonesia has become yearly occurrences and not only event any more. 6, 5, 4, 3, 2, 1, Fig 1. Forest burnt area and number of hotspots detected by SiPongi-NOAA, 1984 27 3.2. Recent hotspot (fire) trend in 3.2.1. Trend of dry season in Palangkaraya The smoothed mean daily precipitation curve shows a U-shaped precipitation pattern in Palangkaraya (Fig. 2). A daily mean precipitation (7.84 mm) is used to differentiate the dry and wet seasons in Palangkaraya. The wet season lasts about seven months and it is two months longer than the dry season. The length of the dry season is about five months from the start of June (DN 152) to the end of October (DN 31). Thus, this study defines June to October as the dry season in Palangkaraya. 3 27 24 21 18 15 12 9 6 3 Burnt Area Hotspots Indonesia Hotspots Kalimantan Hotspots Sumatra Data Source : Burnt area : Ministry of Forestry and State Ministry of Environment Hotspot : NOAA - SiPongi Hotspot 1997 : July - Dec. 1997 Hotspot 26 : Jan. - Oct. 26 Palangkaraya, 1978-27 SD SD Poly. () Mean wet precipitation (1. mm) Mean precipitation (7.84 mm) 1 13 25 37 49 61 73 85 97 19 121 133 145 157 169 181 193 25 217 229 241 253 265 277 289 31 313 325 337 349 361 Dry Season (698.9 mm, 24.6%) Annual : 2845.7 mm Fig. 2. Daily precipitation cycle in Palangkaraya The precipitation pattern in Fig. 2 clearly shows the large difference in precipitation between the wet and dry seasons in Palangkaraya. There is a more than two times difference between the mean daily precipitation values in the dry season (4.69 mm) and wet season (1. mm), and the total precipitation in the dry season (698.9 mm) is only 1/3 of that in the wet season, this pattern clearly describes the overall dry climate conditions in Palangkaraya during the dry season. Low daily precipitation, less than the mean dry precipitation (4.69 mm), occurred between July and September and the lowest daily precipitation of less than 3 mm is in the middle of August. Low precipitation brings a drier climate and increases the dryness of the peat in the. Thus, based on 15, 125, 1, 75, 5, 25, Mean wet precipitation (1. mm) Mean dry precipitation (4.69 mm) the data here we suggest the middle of August as both the peak of the dry season as well as the start of the peak of the fire season. There was a negative correlation between SST Anomalies and precipitation in Palangkaraya in July October, 1978-26 (Fig. 3), indicating that the drought in Palangkaraya is proportional to positive SST anomalies. The of more than +.5 C SST Anomalies bring less than 4 mm precipitation in July October such as in 1997, 1991, 24, 26, 1982, 1987, and 22. However, below mean value precipitation also occurred in several neutral or non years such as in 23, 24 and 25, when there were low positive SST Anomalies between +.1 C and +.5 C. This may indicate that recently even low positive SST Anomaly occurrences may bring on severe dry conditions in Palangkaraya. 1 9 8 7 6 5 4 3 2 1 Fig. 3. Correlation between SST Anomalies and total precipitation in July - October, 1978 27 Dry climate during dry season may dry up above ground fuel and peat and increasing its flaming risk. Over 9% of hotspots in the from 1997 to 27 (Fig. 4) occurred between July and October or during the dry season. High numbers of hotspots were detected primarily in the dry seasons with high positive SST Anomalies. The SiPongi-NOAA captured 8,41 hotspots in 1997, 4,961 in 22, 3,591 in 24, and 5,734 in 26, when high positive SST Anomalies enhanced longer dry periods. In these years fire events peaked in August, September, and October, when the area had precipitation below 1 mm. 3 25 2 15 1 5 88 98 99 89 78 85 84 95 96 83 8 1 81 9 J A J O J A J O J A J O J A J O J A J O J A J O J A J O J A J O J A J O J A J O J A J O Month R 2 =.6267-1.5-1 -.5.5 1 1.5 2 2.5 3 Maximum SST Anomalies July - Oct 1978-26 Hotspot 1997 1998 1999 2 21 22 23 24 25 26 27 Fig. 4. and hotspot occurrences in the, 1997 27. High numbers of fires, however, also occurred in the dry seasons of 21, 23 and 25; when positive SST anomalies were low. suggesting that fire occurrence is associated with droughts as indicated by positive SST anomalies. Therefore peat fires in the 92 93 3 5 6 79 94 4 86 91 2 87 82 97 7 6 5 4 3 2 1
Hotspots density (hotspots/km 2 ) are no longer limited to El Niño years. Strong relationship (R 2 =86.42%) is found between the number of hotspots and positive SST anomalies in July to October in 1997 to 27 (Fig. 5). Positive SST anomalies thus clearly induced high numbers of fires. The highest number of hotspots occurred during the 1997 following the highest SST anomalies in this year. A relatively high number of fires were observed also, however, in non-el Niño years with positive SST anomalies, i.e., in 21, 23, and 25. Over 1,5 fires occurred in these years when SST anomalies exceeded +.3 C, indicating that recently even low positive SST Anomalies yield high numbers of fires. 9 July - October, 1997-26 75 97 6 6 45 2 1 3 4 y = 1.852x 2 + 2153.5x + 1954.6 3 R 2 =.8642 15 99 98 5-1.5-1 -.5.3.5.8 1 1.5 2 2.5 3 Fig. 5. Relationship between number of hotspots and maximum SST anomalies, July October 1997-26 Number of hotspot detected per km 2 area is used in this study to express fire density.. Hotspots density from 1997-27 in MRP and non- is shown in Fig. 6. In average, hotspots density in MRP area (21 hotspots/1 km 2 ) is 5.54 times higher than that in non- (6 hotspots/1 km 2 ), suggesting that MRP is became the most dense peat fires area in Central Kalimantan in recent years. More than 63% (9,191 km 2 ) areas of MRP consist of peatland which is equal to 3% of total existing peatlands in Central Kalimantan (3,951 km 2 )..6.5.4.3.2.1 MRP Non-MRP Maximum SST Anomalies ( C) 1997 1998 1999 2 21 22 23 24 25 26 27 Fig. 6. Hotspots density in and non-mrp, 1997-27 Analysis on daily hotspot occurrences captured by NASA-MODIS satellite (Fig. 7) showed fire is more pronounced in the dry season. More than 88% fires occurred during the dry season, strongly suggesting the close relation between dry season and fire occurrences in. The number of fires increased progressively in the dry season as the dry season progressed. Fires in the starting month of the dry season (June) contributed only 1.24% of the total number of fires, but fires at the end of the dry season (October) contributes more than 39% of the total number. The peak of the fire period tends to start from the middle of August and ends at the start of November. Fires in the peak fire periods numbered 2938 or around 87.1% of the annual number of fires in the. 7 6 5 4 3 2 1 Fig. 7. Daily hotspot occurrences trend, 21-27 Fig. 3-26 shows that the peat fire occurrence in the coincides with the precipitation curve. Daily precipitation decreased gradually from June and reached the lowest point in the middle of August, creating the necessary dry conditions for fires to ignite. Then, fires start to occur on a daily basis from the middle of June and become numerous from the end of July, making the end of July the start of the fire season in the. The peak fire period starts from the middle of August when daily precipitation drops below the lowest mean value, less than 3 mm. The fire season ended at the middle of November or about twenty days after the end of the dry season at the end of October. This may indicate that peat in the MRP area is still in the dry condition at the beginning of the wet season, after suffering from the severe dry conditions of the long dry season, thus maintaining the condition where ignition is easy. 7 6 5 4 3 2 1 MODIS 21-27 1978-27 (precipitation) 21-27 (MODIS hotspots) HS Dry season Mean dry precipitation (4.69 mm) Dry Season 2974 fires (88.2%) 1 13 25 37 49 61 73 85 97 19 121 133 145 157 169 181 193 25 217 229 241 253 265 277 289 31 313 325 337 349 361 Fire season Mean precipitation (7.84 mm) Fire season Peak fire period 2938 fires (87.1%) Peak fire period 1 13 25 37 49 61 73 85 97 19 121 133 145 157 169 181 193 25 217 229 241 253 265 277 289 31 313 325 337 349 361 Annual fires : 3374 fires.14%.5%.17%.1%.25% 1.24% 2.1% 18.44% 3.28% 39.3% 6.56%.4% Fig. 7. Daily precipitation and hotspot occurrences trend in 3.3. Ground water level, precipitation and peat fire occurrence in Fig. 8 showed the changes in GWL in the MRP area. The GWL stays steady at around 5 cm higher than the soil surface between January and the middle of May, in the wet season; suggests that the area could be categorized as a peat swamp forest area. The GWL decreased progressively below soil surface during the dry season from the end of May until it reached the lowest value in early October; clearly indicating that the GWL followed the precipitation changes. However, there is a time-lag between GWL and precipitation. There is about a one and a half month time-lag between the lowest precipitation in mid August and the lowest GWL in early October. The decrease of 18 16 14 12 1 8 6 4 2
Ground water level (cm) Ground water level (cm) precipitation takes 3 months to reach the lowest in mid August (from mid May), but the lowering of GWL below the soil surface takes around 4.5 months from the middle of May until it reaches its lowest value in early October. The GWL then reaches the soil surface again at the end of December after the precipitation has reached its highest value in mid December. This may suggest that the recovery of the ground water level in the occurs after having been replenished by the water supplied by the continuous precipitation. affected by fires, with the highest fire density in the southern part of Block C and upper part of Block A. High fire density was also observed along channels in Blocks C and B, central part of Block A and near main drainage channels in Block A and B. Recurring fires in these areas resulted to the high fire density. 18 2 16 Ground water level Dry season Soil surface ( cm) 1 14 12 1 8 6 4 2 Critical level (-4 cm) -1-2 -3-4 -5 1 13 25 37 49 61 73 85 97 19 121 133 145 157 169 181 193 25 217 229 241 253 265 277 289 31 313 325 337 349 361 Fig. 8. Ground water level and precipitation changes Fire occurrences in the coincide with the GWL (Fig. 9). More than 99% of fires occurred when the GWL was below the soil surface. The peak fire period in the started when the GWL reached -4 cm in the middle of August and fires become more severe when GWL is below -4 cm from the middle of August till early November. Therefore this study suggests -4 cm as a critical level of GWL for large peat fire occurrences in the MRP area, and this GWL should be used as an indicator for a high likelihood of severe fire occurrences there. 2 1-1 -2-3 -4-5 -6 : MODIS hotspots (21-27) : Ground w ater level Critical level (-4 cm) Dry season Fire season Peak fire period Soil surface ( cm) 1 13 25 37 49 61 73 85 97 19 121 133 145 157 169 181 193 25 217 229 241 253 265 277 289 31 313 325 337 349 361 Fig. 9. Ground water level and hotspot occurrence in MRP Area The decreases of GWL clearly indicated that in recent years GWL in the Mega Rice Project (MRP) area became very deep mainly in the dry season. Therefore peatlands were in severely dry conditions in the dry season and this creates a situation where ignition and combustion is promoted, and the large number of fires that occur while the ground water level is low in the dry season substantiates this. 3.4 Peat fire distribution and density In order to find the most dense areas from peat fire, local fire density of 1 x 1 km grids is calculated based on NASA-MODIS daily hotspot data from 21 to 29 (Fig. 1). /km 2 is used as a unit for fire density. Almost all areas were 7 6 5 4 3 2 1-6 : 1 13 hotspots/km 2 : 14 31 hotspots/km 2 : 32 55 hotspots/km 2 : 56 93 hotspots/km 2 : 94 167 hotspots/km 2 Fig. 1. Hotspot (fire) density in during 21 29 High hotspots density of more than 32 hotspots/km 2 during 21 29 was found along the canals in southern part of Block C, paddy fields in Block A and along primary channel in Block A and B. Southern part of Block C is dominated by high hotspot density of more than 53 hotspots/km 2 as well as along Trans-Kalimantan highway road and along canals in northern and eastern part of study area. Less hotspots density was found in forest area of Block E. There were many agricultural field and abandoned farmland found along the canals as well as along Trans-Kalimantan highway road. The fact that these high-fire-density areas mainly involve paddy fields and abandoned farmland, mostly located near channels, suggests that using fire in land preparation and slash-and-burn activities in the dry season still continuing. Thus, as the peat fires here are human-caused fires, peat fire in MRP must be prevented by reducing both intentional and careless fire use. This requires that people in communities must be trained and their awareness of fire prevention and fire extinguishing must be raised. 3.5. Assessment of fire-affected area Series of fire-affected areas in MRP from 1997 to 29 is shown in Fig. 11. The estimation of these fire affected areas is done by using daily hotspots dataset provided by SiPongi-NOAA (from 1997 to 21) and NASA MODIS (from 21 to 29). Large fire-affected areas in MRP are found in 1997, 22, 26 and 29. Highest number of hotspots (fires) was detected in 1997 (8,481) and largest burnt area (4,344 km 2 ) was found in the same year.
CO Max (ppm (mg/l) ) Ratio of burnt area to block area (%) PM PM1 Max (ug/l) 1 Max (µg/m3 ) Carbon-loss (Gt) Fire-affcted area (km 2 ) Number of Hotspots 5, 4,5 4, 3,5 3, 2,5 2, 1,5 1, 5 Fig. 11. and burnt area in MRP, 1997 29 About 837,33 km 2 areas in the MRP (or around 57.4% of total ) were affected by fire during 21 29. Among this number, 231,1 km 2 were in Block A and 325, km 2 in Block C. This means more than 74.6% area of Block C and 74.5% of Block A was affected by fire during 22 29. Area affected by fire in Block B reached 68.%, 53.2% for Block D and 26.6% for Block E. Ratio of fire-affected or burnt area to block area is introduced to assess the severity of fire impact to the block area. Fig. 12 showed that fires in 1997, 22 and 26 were distributed evenly in Blocks A, B and C. More than 3% area in Blocks B and C were affected by fires in 1997, 22 and 26. Around 29% areas in Block A burned in 1997, and more than 32% in 22 and 26. Fires were also burnt severely Block D in 1997, 22 and 26. These evidences clearly indicated 1997, 22 and 26 as severe fire years in MRP. However, 29 may also categorize as severe peat fires episode in MRP when burnt area ratios in Blocks A, B and C exceeded 25%. 5 4 3 2 1 1997 1998 1999 2 21 22 23 24 25 26 27 28 29 A B C D E 1997 1998 1999 2 21 22 23 24 25 26 27 28 29 Fire-affected area Hotspots Fig. 12. Ratio of fire-affected area to block area in MRP, 1997-29 1, 3.6. Estimation of carbon emission due to peat fire occurrences Fig 13. showed estimated carbon emission due to peat fire in from 1997 to 29. In this study, peat burnt depth is assumed more shallow in recent years. Page et.al [1] proposed 51 cm as the average peat burnt depth of in 1997, but Usup A [56] in 22 found average peat burnt depth of 39 cm in Block C of MRP [3]. No publication is found for the peat burnt depth in after these findings. Thus, this study used 39 cm for peat burnt depth from 22 to 29, and 51 cm from 1997 to 21. Based on the peat burnt depth assumption described above, highest carbon emission due to fire 9, 8, 7, 6, 5, 4, 3, 2, 1, in MRP in 1997 is estimated at.87 Gt, following largest burnt area in this year. Carbon emission is estimated at.56 Gt in 22,.59 Gt in 26, and.42 Gt in 29..1.9.8.7.6.5.4.3.2.1..87.8.15.2.17.56.24.34.21.59.7.3 1997 1998 1999 2 21 22 23 24 25 26 27 28 29 Fig. 13. Carbon-loss due to peat fire in MRP, 1997-29 Even the MRP land area (14,571 km 2 ) occupies only.77% of whole land area of Indonesia (1,89,754 km 2 ), but CO 2 emission from fires here are estimated to be responsible for 12.4% (.32 Gt) and 11.6% (.22 Gt) of Indonesian CO 2 emission in 1997 and 26, respectively. The estimation for CO 2 emissions from fires in Indonesia is derived from Hoijeer et al. [4]. Numbers provided above strongly suggest the importance of fire prevention in MRP for carbon emission reduction. 3.7. Peat fire impacts on air quality Figs 14 and 15 showed that PM 1 and CO concentration increased significantly every year in the dry season, and peaked in October after large number of peat fires occurred. Highest PM 1 and CO concentration was observed in 22 following largest number of fires in this year; decreased air quality in Palangkaraya to seriously hazardous level for PM 1 and to very unhealthy level for the CO. 35 2 3 HS 18. PM1 Max 16 25 14 2 12 1 15 8 1 6 4 5 2 J A J O J A J O J A J O J A J O J A J O J A J O J A J O J A 2 21 22 23 24 25 26 27 35 3 25 2 15 1 5 HS CO max Month J A J O J A J O J A J O J A J O J A J O J A J O J A J O J A 2 21 22 23 24 25 26 27 Month Fig. 14. Hotspots and PM 1 (up) and CO oncentration (bottom) in Palangkaraya, 2 June 27 Number of fires from July October 22 was 775 and maximum PM 1 and CO concentration was observed in October 22 (194 µg/m 3 for PM 1 and 38 ppm for CO). Peat fire occurrences in 26 increased PM 1 concentration to around 17 µg/m 3 45 4 35 3 25 2 15 1 5.42
PM1 Max ( and 21.9 ppm for CO (Fig. 14). CO concentration in 26 was almost similar with that in 24. These evidences clearly indicate that large number of fire occurrences will decrease air quality in Palangkaraya greatly to dangerous levels for human health IV. CONCLUSIONS Hotspot (fire) data, daily weather data, SST Anomalies, and ground water level data were analyzed in this study to clarify recent peat fire trend in the Mega Rice Project (MRP) area. The results of this study are summarized as follows: 1. This study clearly showed that large areas of bared peat in the now are highly susceptible to fires. Recent trend of hotspot (fire) showed that many hotspots (fires) found in bared peatland in after MRP development. Most of hotspots (fires) were occurred in dry months of August to October from 21; indicating the couples of dry season and peat fire trend in MRP area. 2. The daily precipitation analysis using 3 years weather data from 1978 to 27 clearly showed that Palangkaraya has seven month wet season and five months dry season that starts from early of June and ends at the end of October. About two times difference between mean precipitation values in the dry and wet season was also found. Mean daily precipitation less than 3 mm were found in August or in the middle of dry season, suggesting the middle of August as the peak of the dry season as well as the start of the peak fire period. Under this precipitation pattern, dryness of peat is increased and stimulated the large number of fire occurrences. 3. Peat fire in is found more pronounced in years, but number of fires exceeded 2,5 in non-el-niño year with positive SST anomalies in 23 and 25; indicates that recently even low positive SST Anomalies more than +.3 C may result to high number of fires. Thus, SST Anomalies may more precisely relate to fire trend in instead of event. 4. In the, peat fire occurrences are closely related to the severity of drought and SST anomalies. SST anomalies have a negative correlation with precipitation and positive high correlation with number of hotspots (fires). From the above relation, we may say that peat fire trends in the is related to local peat dryness there. 5. GWL (ground water level) starts to decrease from around the middle of May. This GWL tendency is mainly due to precipitation pattern change from the wet to dry season. Then, the fire season starts when GWL becomes negative, showing that fire occurrence is closely related with ground water level change and precipitation pattern in the dry season. 6. The peak fire period coincided with low GWL less than -4 cm, suggesting around -4 cm as a critical level for peat fire occurrence. Thus, -4 cm of GWL could be used as an alarm for the severe peat fire occurrence in the.. 7. A detailed hotspot distribution map showed that large area of Blocks C and A in MRP seriously damaged by peat fires. Their percentage of fire-affected area to total block area during 1997 29 reached 73.9% in Block C and 74.6% in Block A. High peat fire density are found in agricultural fields, abandoned lands and along canals and roads, suggesting that intensive ongoing human activity accelerates fire occurrences in MRP. Thus, this situation allows us to classify peat fires here as one of man-made disasters. 8. Carbon emission from peat fires in MRP is estimated at.87 Gt in 1997,.57 Gt in 22 and.59 Gt in 26, by assuming constant burnt depth of 51 cm from 1997 to 21 and 39 cm from 22 to 29. Although the MRP land area (14,571 km 2 ) occupies only.77% of whole land area of Indonesia (1,89,754 km 2 ), CO 2 emission from fires in the are estimated to be responsible for 12.4% (.32 Gt) and 11.6% (.22 Gt) of Indonesian CO 2 emission in 1997 and 26, respectively, strongly indicating the importance of peat fire prevention in the MRP from the viewpoint of world carbon emission. 9. Severe peat fire occurrences in 22 and 26 decreased air quality in Palangkaraya when PM 1 and CO concentration exceeded 17 µg/m 3 and 2 ppm, respectively.; strongly indicates that large peat fire occurrences will decrease air quality significantly to very dangerous level for human health. REFERENCES [1] Page SE, Siegert F, Rieley JO, Boehm H-DV, Jaya A, Limin S. 22. The amount of carbon released from peat and forest fires in Indonesia during 1997. Nature Vol. 42, Pp. 61 65, 22. [2] Takahashi H, Usup A, Hayasaka H and Limin SH. 27. Overview of hydrological aspects for recent 1 years in the basins of River Sebangau and Kahayan. Environmental Conservation and Land Use Management of Wetland Ecosystem in Southeast Asia. Annual Report for April 26 March 27, Pp. 141 144. [3] Usup A, Hashimoto Y, Takahashi H, Hayasaka H. 24. Combustion and thermal characteristics of peat fire in tropical peatland in Central Kalimantan, Indonesia. Tropics Vol. 14 (1) 24 : 1-19. [4] Hooijer A, Silvius M, Wosten H, Page SE. 26. Peat-CO2: Assessment of CO 2 emission from drained peatlands in SE Asia. Delft Hydraulics Report Q3943 (26) [5] Putra EI, Hayasaka H, Takahashi H, Usup A. 28. Recent peat fire activity in the Mega Rice Project area, Central Kalimantan, Indonesia. Journal of Disaster Research Vol. 3 No. 5 (28), Pp. 334 341