This page has only limited features, please log in for full access.

Dr. AGAPOL JUNPEN
King Mongkut's Institute of Technology Thonburi

Basic Info


Research Keywords & Expertise

0 Emission Inventories
0 forest fires
0 Enviromental Assessment
0 Biomass Burning
0 Transport emissions

Honors and Awards

The user has no records in this section


Career Timeline

The user has no records in this section.


Short Biography

The user biography is not available.
Following
Followers
Co Authors
The list of users this user is following is empty.
Following: 0 users

Feed

Journal article
Published: 06 August 2020 in Climate
Reads 0
Downloads 0

Moderate Resolution Imaging Spectroradiometer (MODIS) burnt area products are widely used to assess the damaged area after wildfires and agricultural burning have occurred. This study improved the accuracy of the assessment of the burnt areas by using the MCD45A1 and MCD64A1 burnt area products with the finer spatial resolution product from the Landsat-8 Operational Land Imager/Thermal Infrared Sensor (OLI/TIRS) surface reflectance data. Thus, more accurate wildfires and agricultural burning areas in the Greater Mekong Subregion (GMS) for the year 2015 as well as the estimation of the fire emissions were reported. In addition, the results from this study were compared with the data derived from the fourth version of the Global Fire Emissions Database (GFED) that included small fires (GFED4.1s). Upon analysis of the data of the burnt areas, it was found that the burnt areas obtained from the MCD64A1 and MCD45A1 had lower values than the reference fires for all vegetation fires. These results suggested multiplying the MCD64A1 and MCD45A1 for the GMS by the correction factors of 2.11−21.08 depending on the MODIS burnt area product and vegetation fires. After adjusting the burnt areas by the correction factor, the total biomass burnt area in the GMS during the year 2015 was about 33.3 million hectares (Mha), which caused the burning of 109 ± 22 million tons (Mt) of biomass. This burning emitted 178 ± 42 Mt of CO2, 469 ± 351 kilotons (kt) of CH4, 18 ± 3 kt of N2O, 9.4 ± 4.9 Mt of CO, 345 ± 206 kt of NOX, 46 ± 25 kt of SO2, 147 ± 117 kt of NH3, 820 ± 489 kt of PM2.5, 60 ± 32 kt of BC, and 350 ± 205 kt of OC. Furthermore, the emission results of fine particulate matter (PM2.5) in all countries were slightly lower than GFED4.1s in the range between 0.3 and 0.6 times.

ACS Style

Agapol Junpen; Jirataya Roemmontri; Athipthep Boonman; Penwadee Cheewaphongphan; Pham Thi Bich Thao; Savitri Garivait. Spatial and Temporal Distribution of Biomass Open Burning Emissions in the Greater Mekong Subregion. Climate 2020, 8, 90 .

AMA Style

Agapol Junpen, Jirataya Roemmontri, Athipthep Boonman, Penwadee Cheewaphongphan, Pham Thi Bich Thao, Savitri Garivait. Spatial and Temporal Distribution of Biomass Open Burning Emissions in the Greater Mekong Subregion. Climate. 2020; 8 (8):90.

Chicago/Turabian Style

Agapol Junpen; Jirataya Roemmontri; Athipthep Boonman; Penwadee Cheewaphongphan; Pham Thi Bich Thao; Savitri Garivait. 2020. "Spatial and Temporal Distribution of Biomass Open Burning Emissions in the Greater Mekong Subregion." Climate 8, no. 8: 90.

Journal article
Published: 10 April 2020 in Atmosphere
Reads 0
Downloads 0

In the middle of 2019, Thailand introduced an urgent measure to solve the haze and fine particles problem caused by preharvest sugarcane. The measure is to eradicate the burning of sugarcane before harvesting within the next four years. This study focuses on estimation of future reduced air emissions from the implementation of this measure. The study results showed that without the implementation of the measure in the production season 2022/23, the amount of burned sugarcane will be as high as 102.4 ± 1.0 Mt/yr, resulting in the release of small particulate matter of 2.5 microns or less in diameter (PM2.5) emissions into the atmosphere at 30.6 ± 8.6 kt/yr, which is about a 21% increase in emissions from the 2018/19 season. However, with the government’s enforcement of the measure to reduce burned sugarcane, the amount of air emissions will immediately be reduced in the first year. In order to effectively implement the sugarcane burning reduction measure, in which the harvesting methods will change from cutting burned sugarcane to cutting fresh sugarcane with human labor and with machinery, the government must provide financial support, to farmers, of approximately 3.3 USD per ton of fresh sugarcane for the use of human labor and 2.9 USD per ton of fresh sugarcane for the use of machinery. The costs of investment to reduce PM2.5 emissions can be calculated in the range of 9.7−11.0 million USD per kiloton of PM2.5.

ACS Style

Agapol Junpen; Jirataya Pansuk; Savitri Garivait. Estimation of Reduced Air Emissions as a Result of the Implementation of the Measure to Reduce Burned Sugarcane in Thailand. Atmosphere 2020, 11, 366 .

AMA Style

Agapol Junpen, Jirataya Pansuk, Savitri Garivait. Estimation of Reduced Air Emissions as a Result of the Implementation of the Measure to Reduce Burned Sugarcane in Thailand. Atmosphere. 2020; 11 (4):366.

Chicago/Turabian Style

Agapol Junpen; Jirataya Pansuk; Savitri Garivait. 2020. "Estimation of Reduced Air Emissions as a Result of the Implementation of the Measure to Reduce Burned Sugarcane in Thailand." Atmosphere 11, no. 4: 366.

Journal article
Published: 15 November 2018 in Atmosphere
Reads 0
Downloads 0

Crop residue burning negatively impacts both the environment and human health, whether in the aspect of air pollution, regional and global climate change, or transboundary air pollution. Accordingly, this study aims to assess the level of air pollutant emissions caused by the rice residue open burning activities in 2018, by analyzing the remote sensing information and country specific data. This research also aims to analyze the trend of particulate matter 10 microns or less in diameter (PM10) concentration air quality sites in provinces with large paddy rice planting areas from 2010–2017. According to the results, 61.87 megaton (Mt) of rice residue were generated, comprising 21.35 Mt generated from the irrigated fields and 40.53 Mt generated from the rain-fed field. Only 23.0% of the total rice residue generated were subject to open burning—of which nearly 32% were actually burned in the fields. The emissions from such rice residue burning consisted of: 5.34 ± 2.33 megaton (Mt) of CO2, 44 ± 14 kiloton (kt) of CH4, 422 ± 179 kt of CO, 2 ± 2 kt of NOX, 2 ± 2 kt of SO2, 38 ± 22 kt of PM2.5, 43 ± 29 kt of PM10, 2 ± 1 kt of black carbon (BC), and 14 ± 5 kt of organic carbon (OC). According to the air quality trends, the results shows the higher level of PM10 concentration was due to the agricultural burning activities, as reflected in the higher monthly averages of the months with the agricultural burning, by around 1.9–2.1 times. The result also shows the effect of government’s policy for farmers on the crop burning activities and air quality trends.

ACS Style

Agapol Junpen; Jirataya Pansuk; Orachorn Kamnoet; Penwadee Cheewaphongphan; Savitri Garivait. Emission of Air Pollutants from Rice Residue Open Burning in Thailand, 2018. Atmosphere 2018, 9, 449 .

AMA Style

Agapol Junpen, Jirataya Pansuk, Orachorn Kamnoet, Penwadee Cheewaphongphan, Savitri Garivait. Emission of Air Pollutants from Rice Residue Open Burning in Thailand, 2018. Atmosphere. 2018; 9 (11):449.

Chicago/Turabian Style

Agapol Junpen; Jirataya Pansuk; Orachorn Kamnoet; Penwadee Cheewaphongphan; Savitri Garivait. 2018. "Emission of Air Pollutants from Rice Residue Open Burning in Thailand, 2018." Atmosphere 9, no. 11: 449.

Journal article
Published: 20 July 2018 in Sustainability
Reads 0
Downloads 0

The purpose of this study was to assess household solid waste management in areas governed by local administrative organizations (LAOs). The obtained results would be used to assess the amount of air pollution emitted from household solid waste open burning. A survey was employed, through the use of questionnaires, to collect data from a random sample of 4300 households residing in areas governed by 96 LAOs. According to the results, it was evident that a total of 26.17 Mt of solid waste were generated per year, of which 6.39 Mt/year was not collected by the LAOs and was eliminated by households. Moreover, the percentage of waste burned on or outside the households’ property was 53.7%, or an equivalent of 3.43 Mt/year of solid waste burned in open areas. In addition, it was found that 0.66 Mt/year of solid waste collected by the LAOs was burned in open areas and was not eliminated properly. Hence, the total amount of solid waste from these two sources was 4.09 Mt/year, which resulted in the emissions of carbon dioxide equivalent, carbon monoxide, sulfur dioxide, nitric oxide, and particulate matter of 1247.3 kt/year, 103.0 kt/year, 1.2 kt/year, 7.4 kt/year, and 19.6 kt/year, respectively.

ACS Style

Jirataya Pansuk; Agapol Junpen; Savitri Garivait. Assessment of Air Pollution from Household Solid Waste Open Burning in Thailand. Sustainability 2018, 10, 2553 .

AMA Style

Jirataya Pansuk, Agapol Junpen, Savitri Garivait. Assessment of Air Pollution from Household Solid Waste Open Burning in Thailand. Sustainability. 2018; 10 (7):2553.

Chicago/Turabian Style

Jirataya Pansuk; Agapol Junpen; Savitri Garivait. 2018. "Assessment of Air Pollution from Household Solid Waste Open Burning in Thailand." Sustainability 10, no. 7: 2553.

Journal article
Published: 23 January 2018 in Energies
Reads 0
Downloads 0

Agricultural residue is a major raw material for renewable energy production, particularly heat production, in Thailand. Meanwhile, the process-based residue, such as bagasse, rice husk, wood residue, palm fiber, palm shell, and saw dust, is used as a fuel for energy production in the agro-industry. Hence, this study is intended to assess the net potential and capacity of alternative agricultural residues, specifically rice straws, to serve as the supplementary fuel for very small power plants (VSPPs) in Thailand. According to the results obtained during the crop season of 2015/2016, approximately 26 Mt of rice straws were generated upon the harvesting process. The net potential of rice straws, including those that were burned and those that were left in the fields, was only about 15% or 3.85 Mt, which could be used for heat and electricity production at 1331 kilotons of oil equivalent (ktoe) or 457 MWe. As agro-residues vary by seasonality, the peak season of rice straws was in November, where approximately 1.64 Mt (43%) were generated, followed by December, at 1.32 Mt (34%). On the basis of the results, rice straw has the potential to serve as a fuel supply for VSPPs at 14.2%, 21.6%, 26.3%, and 29.0% for the radii of compilation at 24, 36, 48 km and 60 km, respectively.

ACS Style

Penwadee Cheewaphongphan; Agapol Junpen; Orachorn Kamnoet; Savitri Garivait. Study on the Potential of Rice Straws as a Supplementary Fuel in Very Small Power Plants in Thailand. Energies 2018, 11, 270 .

AMA Style

Penwadee Cheewaphongphan, Agapol Junpen, Orachorn Kamnoet, Savitri Garivait. Study on the Potential of Rice Straws as a Supplementary Fuel in Very Small Power Plants in Thailand. Energies. 2018; 11 (2):270.

Chicago/Turabian Style

Penwadee Cheewaphongphan; Agapol Junpen; Orachorn Kamnoet; Savitri Garivait. 2018. "Study on the Potential of Rice Straws as a Supplementary Fuel in Very Small Power Plants in Thailand." Energies 11, no. 2: 270.

Journal article
Published: 07 September 2017 in Atmosphere
Reads 0
Downloads 0

Bangkok Metropolitan Region (BMR), including the capital city and five adjacent provinces, constitutes one of the top 10 megacities experiencing serious traffic congestion in the world, leading to air quality problems with significant adverse human health risks. Previously, there have been many operations planned to influence the fuel consumption and emissions from the on-road transport sector in the BMR area. It is necessary to estimate emissions using detailed information in order to thoroughly understand the reason for changes in emission levels and their impact on air quality. This paper aims to determine the successful implementation of energy and air pollution control policies in Thailand through an investigation of the emissions inventory of on-road transport in BMR, including ozone precursors (CO, NOX, Non-methane volatile organic compounds (NMVOCs) ), greenhouse gases (CO2, CH4, N2O), acidic substances (SO2 and NH3), and particulate matters (PM2.5, PM10, Black Carbon (BC), Organic Carbon (OC)) during the period from 2007 to 2015, using the Greenhouse Gas and Air Pollution Interactions and Synergies (GAINS) model based on the country-specific activity data together with the emission factor from the GAINS-Asia database. This study found that the amount of exhaust emissions over the BMR area in the year 2015 (and the trend during the period from 2007 to 2015) is approximately 139 kt of CO (−7.9%), 103 kt of NOX (−4.1%), 19.9 kt of NMVOC (−6.7%), 15 kt of CO2 (+1.6%), 8.6 kt of CH4 (+6.8%), 0.59 kt of N2O (+1.3%), 0.87 kt of SO2 (−25.8%), 1.1 kt of NH3 (+7.8%), 4.9 kt of PM2.5 (−5.5%), 5.1 kt of PM10 (−7.9%), 3.1 kt of BC (−2.5%), and 1.4 kt of OC (−7.7%). The change in emissions in each pollutant is a result of the more stringent control of fuel and engine standards, the shift in the fuel type used, and the effects of controlling some emissions. Light duty car gasoline fuel is identified as a major contributor of CO, NH3, N2O, and NMVOC, whereas trucks are the greatest emitters of NOX, SO2, and particulate matter. This study suggests that the most powerful implementation plan for the continuous, significant reduction of ozone precursor, SO2, and particulate matter emissions is the more stringent enforcement of fuel and vehicle standard levels, especially concerning light duty vehicles.

ACS Style

Penwadee Cheewaphongphan; Agapol Junpen; Savitri Garivait; Satoru Chatani. Emission Inventory of On-Road Transport in Bangkok Metropolitan Region (BMR) Development during 2007 to 2015 Using the GAINS Model. Atmosphere 2017, 8, 167 .

AMA Style

Penwadee Cheewaphongphan, Agapol Junpen, Savitri Garivait, Satoru Chatani. Emission Inventory of On-Road Transport in Bangkok Metropolitan Region (BMR) Development during 2007 to 2015 Using the GAINS Model. Atmosphere. 2017; 8 (12):167.

Chicago/Turabian Style

Penwadee Cheewaphongphan; Agapol Junpen; Savitri Garivait; Satoru Chatani. 2017. "Emission Inventory of On-Road Transport in Bangkok Metropolitan Region (BMR) Development during 2007 to 2015 Using the GAINS Model." Atmosphere 8, no. 12: 167.

Journal article
Published: 01 January 2013 in ScienceAsia
Reads 0
Downloads 0
ACS Style

Agapol Junpen; Savitri Garivait; Sebastien Bonnet; Adisak Pongpullponsak. Fire spread prediction for deciduous forest fires in Northern Thailand. ScienceAsia 2013, 39, 1 .

AMA Style

Agapol Junpen, Savitri Garivait, Sebastien Bonnet, Adisak Pongpullponsak. Fire spread prediction for deciduous forest fires in Northern Thailand. ScienceAsia. 2013; 39 (5):1.

Chicago/Turabian Style

Agapol Junpen; Savitri Garivait; Sebastien Bonnet; Adisak Pongpullponsak. 2013. "Fire spread prediction for deciduous forest fires in Northern Thailand." ScienceAsia 39, no. 5: 1.