Curriculum Vitaes

HAEMI PARK

  (朴 慧美)

Profile Information

Affiliation
Assistant Professor, Graduate School of Global Environmental Studies, Master's (Doctoral) Program in Global Environmental Studies, Sophia University

Researcher number
60854700
ORCID ID
 https://orcid.org/0000-0002-4289-0713
J-GLOBAL ID
202201017586855230
researchmap Member ID
R000034352

Committee Memberships

 1

Papers

 8
  • Haemi Park, Junghee Lee, Cheolhee Yoo, Seongmun Sim, Jungho Im
    IEEE Journal of Selected Topics in Applied Earth Observations and Remote Sensing, 14 8614-8626, 2021  Peer-reviewedLead author
  • Haemi Park, Wataru Takeuchi, Kazuhito Ichii
    Remote Sensing, 12(2) 250-250, Jan 10, 2020  Peer-reviewedLead author
    Tropical peatland ecosystems are known as large carbon (C) reservoirs and affect spatial and temporal patterns in C sinks and sources at large scales in response to climate anomalies. In this study, we developed a satellite data-based model to estimate the net biosphere exchange (NBE) in Indonesia and Malaysia by accounting for fire emissions (FE), ecosystem respiration (R-e), and gross primary production (GPP). All input variables originated from satellite-based datasets, e.g., the precipitation of global satellite mapping of precipitation (GSMaP), the land surface temperature (LST) of the moderate resolution imaging spectroradiometer (MODIS), the photosynthetically active radiation of MODIS, and the burned area of MODIS fire products. First, we estimated the groundwater table (GWT) by incorporating LST and precipitation into the Keetch-Byram Drought Index (KBDI). The GWT was validated using in-situ measurements, with a root mean square error (RMSE) of 24.97 cm and an r-squared (R-2) of 0.61. The daily GWT variations from 2002 to 2018 were used to estimate respiration (R-e) based on a relationship between the in situ GWT and flux-tower-observed R-e. Fire emissions are a large direct source of CO2 from terrestrial ecosystems into the atmosphere and were estimated by using MODIS fire products and estimated biomass. The GPP was calculated based on the MODIS GPP product after parameter calibration at site scales. As a result, averages of long-term (17 years) R-e, GPP, FE, and NBE from whole peatlands in the study area (6 degrees N-11 degrees S, 95-141 degrees E) were 66.71, 39.15, 1.9, and 29.46 Mt C/month, respectively. We found that the NBE from tropical peatlands in the study area was greater than zero, acting as a C source. R-e and FE were influenced by El Nino, and the value of the NBE was also high in the El Nino period. In future studies, the status of peatland degradation should be clarified in detail to accurately estimate the C budget by applying appropriate algorithms of R-e with delineations of types of anthropogenic impacts (e.g., drainages and fires).
  • Juhyun Lee, Jungho Im, Dong-Hyun Cha, Haemi Park, Seongmun Sim
    Remote Sensing, Dec 28, 2019  Peer-reviewed
  • Sumin Park, Haemi Park, Jungho Im, Cheolhee Yoo, Jinyoung Rhee, Byungdoo Lee, ChunGeun Kwon
    PLOS ONE, 14(10) e0223362-e0223362, Oct 10, 2019  Peer-reviewedLead author
  • Jungho Im, Haemi Park, Wataru Takeuchi
    Remote Sensing, 11(18) 2181-2181, Sep 19, 2019  Peer-reviewed
  • Haemi Park, Jungho Im, Miae Kim
    AGRICULTURAL AND FOREST METEOROLOGY, 271 180-192, Jun, 2019  Peer-reviewedLead author
    Gross primary production (GPP) is a crucial factor in the carbon cycle especially for the absorption of carbon dioxide into the biosphere from the atmosphere. A large discrepancy between a satellite-based GPP product named MOD17A2H GPP and in-situ data measured at eddy covariance flux towers has been identified over East Asia where the biome types and climatic characteristics are heterogeneous with rugged terrain. For that reason, this study focuses on two potential major error sources in MOD17A2H GPP, which are the coarse resolution land cover information and inappropriate meteorological parameters. The finer resolution observation and monitoring global land cover (FROM-GLC) and the MODIS land cover product collection 5.1 (MCD12Q1) were used to describe biome types in detail, by combining spatial distribution from FROM-GLC and the phenological characteristics of land cover from MCD12Q1. Meteorological parameters were optimized using the 55-years Japanese reanalysis meteorological data (JRA-55). The light use efficiency of the MOD17 GPP algorithm was modified using the combined land cover information (FROM-MCD). Although the use of FROM-MCD and JRA-55 did not improve MOD17A2H GPP, the optimization of two meteorological parameters-daily minimum air temperature (TMIN) and vapor pressure deficit (VPD) significantly improved the GPP algorithm for East Asia. The results show that the root mean square errors (RMSEs) between the estimated and in situ GPPs decreased from 21.83 (gC/m(2)/8days) to 16.11 (gC/m(2)/8days) through optimizing the two parameters at 9 flux tower sites. The optimized TMIN and VPD thresholds in the MOD17 GPP algorithm were applied to the entire study area (i.e., East Asia) according to the Koppen-Geiger climate classes. The estimated GPP using the proposed approach was compared to GPPs from widely used process-based models (i.e., VISIT, BEAMS, and BESS), which confirmed that the proposed approach with locally optimized meteorological parameters improved on the underestimation of the MOD17 GPP algorithm for East Asia. The uncertainty of the VPDmin parameter was revealed to be larger than that of TMINmax.
  • Haemi Park
    Remote Sensing, 10(4) 631-631, Apr 19, 2018  Peer-reviewed
  • Miae Kim, Jungho Im, Haemi Park, Seonyoung Park, Myong-In Lee, Myoung-Hwan Ahn
    Remote Sensing, 9(7) 685-685, Jul 4, 2017  Peer-reviewed

Major Misc.

 10
  • Haemi Park, Takeo Tadono
    2021 IEEE International Geoscience and Remote Sensing Symposium IGARSS, Jul 11, 2021  
  • Haemi Park, Daiki Shimizu, Wataru Takeuchi
    IGARSS 2020 - 2020 IEEE International Geoscience and Remote Sensing Symposium, 4777-4778, Sep 26, 2020  
    Tropical peatlands have been experienced human-induced disturbances including drainage constructions, oil palm plantations, and wildfires. Since peat soils consist of large organic matter, it is important for the carbon cycle in the tropical area. This study aimed at the delineating of the distribution of drainage canals using microwave images. As the result of validation, overall accuracy was 56.3 % and about 10 % of the peatland areas detected as the drainage canals. For further study, a Keetch Byram Drought Index-based groundwater table will be revised applying the decreasing effect by drainage canals.
  • Haemi Park, Wataru Takeuchi
    2014 IEEE INTERNATIONAL GEOSCIENCE AND REMOTE SENSING SYMPOSIUM (IGARSS), 2014  
    Carbon dioxide (CO2) budget from tropical peat lands in Indonesia was estimated by using satellite data. Indonesia has many CO2 sources that related with peat lands. Our previous results have been continued to estimate CO2 budget from ground water decreasing. The new motivation of this study is to estimate human impact on the peat lands hydrologic environment. The drainage canal is supposed to be artificial in this region. ALOS PALSAR mosaic data was used for detection of drainage canal in Indonesia. Canny edge detection method was used. As the result, daily soil respirations of Jambi and Palangkaraya became 12.63% and 16.84% larger than before consideration of human effect.

Books and Other Publications

 1

Teaching Experience

 1

Professional Memberships

 2

Research Projects

 2