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International Journal of Energy Economics and 
Policy

ISSN: 2146-4553

available at http: www.econjournals.com

International Journal of Energy Economics and Policy, 2022, 12(2), 497-501.

International Journal of Energy Economics and Policy | Vol 12 • Issue 2 • 2022 497

Energy Demand Modeling for the Eastern Economic Corridor of 
Thailand: A Case Study of Rayong Province

Chanidaporn Lunsamrong, Atit Tippichai*

Department of Architecture and Planning, Faculty of Architecture, Art, and Design, King Mongkut’s Institute of Technology 
Ladkrabang, Bangkok, Thailand. *Email: atit.ti@kmitl.ac.th

Received: 03 January 2022 Accepted: 13 March 2022 DOI: https://doi.org/10.32479/ijeep.12884

ABSTRACT

This paper assesses long-term energy consumption and greenhouse gas (GHG) emissions in Rayong Province which is one of the three provinces in the 
Eastern Economic Corridor (EEC) of Thailand. LEAP (the low emissions analysis platform) is used to project final energy demand for each economic 
sector by using the 2019 data as a base year. In the model, we defined the energy consumption into two scenarios; a business-as-usual (BAU) scenario 
and a low carbon scenario (LCS), to see different energy demand and CO2 emissions up to the year 2050. There are different assumptions between 
BAU and LCS in each sector such as energy efficiency improvement, shift to modern energy, the share of high energy-efficient vehicles, etc. In the 
BAU scenario, the final energy consumption needed by Rayong Province will increase with an average annual growth rate (AAGR) of 3.49%, while 
only 1.52% for the LCS. CO2 emissions in the LCS will be reduced by 41.7% by 2050 when compared with the BAU scenario. Most interestingly, 
even though energy demand in Rayong Province will be increasing up to 2050, CO2 emissions will peak about 2035 and then reduce. The industry 
and transport sectors are the most final energy consumption and the highest CO2 emissions. This is because EEC is driven by a production-based 
economy. The solution for this is to transform to alternative energies sourcing, shift all productions to sustainable ones, restructure the industrial estate 
to become the eco-industrial and GHG emissions management, which will also result in obvious carbon reduction. This kind of information will be 
beneficial to energy demand conservation and GHG emission mitigation at the provincial level which will depend on the energy policies initiated and 
implemented in the future.

Keywords: Energy Demand Modeling, Greenhouse Gas, CO2 Emissions, Scenario Analysis, Low Carbon City, Thailand 
JEL Classifications: O22, Q47, Q54

1. INTRODUCTION

Rayong is one of the three provinces in the Eastern Economic 
Corridor (EEC) project which is a highly important economic 
area of Thailand. This will be a huge source of employment with 
the most industrial estates in Thailand. With rapid industrial and 
infrastructure development, the energy demand is constantly 
increasing. If there is no energy policy, it can lead to an energy 
shortage crisis and other environmental problems such as air 
pollution and greenhouse gas emissions. In addition, energy 
imports are costly, thus making development inefficient. It could 
result in disruption to economic growth in the future. In the past, 

energy was not planned at the provincial level. However, in 
Thailand, energy policy and planning have been centralized to 
government agencies, the local governments had mainly functioned 
as implementing agencies of national policies and programs, which 
makes planning inefficient. Therefore, anticipating energy demand 
and finding ways to reduce energy consumption at the provincial 
level is an option to cope with future challenges. It can be used to 
plan energy appropriately and meet the potential of the province.

Energy modeling is commonly used to assess predictions of future 
energy needs. We compiled and summarized the research related 
to energy consumption projections as follows. Wangjiraniran et al. 

This Journal is licensed under a Creative Commons Attribution 4.0 International License



Lunsamrong and Tippichai: Energy Demand Modeling for the Eastern Economic Corridor of Thailand: A Case Study of Rayong Province

International Journal of Energy Economics and Policy | Vol 12 • Issue 2 • 2022498

(2017) conducted a study to analyze changes in the energy sector in 
Thailand. The results of this study showed that the high penetration 
of disruptive technologies will result in reducing greenhouse gas 
(GHG) emissions by 8.9% compared with Thailand’s Integrated 
Energy Blueprint (TIEB) scenario. Electric vehicle (EV) is one of 
the disruptive technologies which will replace the use of oil in the 
transportation sector in Thailand. Chaichaloempreecha et al. (2019) 
conducted a study to evaluate the long-term energy demand in the 
building sector and the industrial sector during 2005–2050 through 
the perspective of GHG mitigation potential by end-use approach 
by using the LEAP model. Policies considered in this study include 
the Energy Efficiency Plan and the Alternative Energy Development 
Plan of Thailand. A review of the literature and models involved in 
the study found that the LEAP model is a favorite model for energy 
planning which can be used to evaluate policies and measures 
(Wangjiraniran et al., 2017; Chaichaloempreecha et al., 2019; Hu 
et al., 2019; Misila et al., 2020; Dioha et al., 2021; Chen et al., 
2021; Gebremeskel et al., 2021; Kehbila et al., 2021). As a result 
of this study, the relevant authorities can apply the information to 
plan the implementation of energy efficiency improvements for 
future needs. In addition to creating energy security, it can also 
help reduce environmental problems effectively.

2. MATERIALS AND METHODS

2.1. Study Area
Rayong is a province located in the Eastern part of Thailand 
with an area of 3,552 square kilometers and a total population 
of 724,979 people. Rayong is a province with the highest gross 
provincial product (GPP) in Thailand at 993,977 million baht and 
the province with the highest gross provincial product per capita 
(GPP Per Capita) in Thailand, at 988,748 baht per year (Office of 
the National Economic and Social Development Council, 2019).

2.2. Data Collection
Data both top-down and bottom-up information was collected 
according to 5 economic sectors, i.e., household sector, building 
sector, industrial sector, agricultural and another sector, and 
transport sector. The collected data used in this study were 
obtained from previous studies and various official data sources 
in Thailand during 2010–2019. The collected data for each sector 
are as follows.
•	 Household sector: Urban and rural population, number of 

households, and end-use energy consumption per household
•	 Building sector: Sectoral value-added, and final energy 

consumption by fuel type
•	 Industrial sector: Sectoral value-added, and final energy 

consumption by fuel type
•	 Agricultural and other sectors: Sectoral value-added, and final 

energy consumption by fuel type
•	 Transportation sector: Number of vehicle registration by 

vehicle technology and fuel type, number of vehicle sales 
by vehicle technology and fuel type, fuel economy, vehicle 
kilometer-traveled, vehicle age distribution, etc.

2.3. LEAP Model
LEAP is developed by the Stockholm Environment Institute which 
is a software tool widely used for energy policy analysis and 

development of climate change mitigation assessment. LEAP is 
an integrated, scenario-based modeling tool that can account for 
both energy sector and non-energy sector greenhouse gas emission 
sources and sinks (Hu et al., 2019).

In general, LEAP calculates energy demand using four different 
methods: Final energy demand, useful energy demand, stock, 
and transport analysis (Dioha et al., 2021). Energy demand can 
be estimated in LEAP using Equations (1) - (4). For a detailed 
description of the Nigerian LEAP model, see the work of Emodi 
et al. (2017). In addition, emission factors (EF) are required 
by specific types of energy resources or fuel to analyze the 
environmental impacts used in Equation (5). The structure of the 
LEAP model in this study is shown in Figure 1 and the structure of 
the sectoral modules in the LEAP model is shown in Figures 2 and 3.
Final energy analysis= Activity level × Energy intensity (1)

Useful energy analysis = Activity level × (useful energy intensity/
efficiency) (2)

Stock analysis = stock and x device intensity (3)

Transport analysis = stock (vehicle miles/fuel economy) (4)

GHG emissions = Activity Data: AD × Emission Factor: EF (5)

2.4. Scenarios and Assumptions
The energy demand forecasting in this study is divided into two 
scenarios: (1) Business as usual (BAU) and (2) low carbon scenario 
(LCS) which are defined as follows.
•	 Business as usual (BAU) scenario: No change in economic 

structure, it is a normal energy forecast based on historical 

Figure 1: The structure of the LEAP model in this study



Lunsamrong and Tippichai: Energy Demand Modeling for the Eastern Economic Corridor of Thailand: A Case Study of Rayong Province

International Journal of Energy Economics and Policy | Vol 12 • Issue 2 • 2022 499

growth data. With the key driver of enhancement of economic 
competitiveness among provinces under the current policy plans

•	 Low Carbon scenario (LCS): Transformation of economic 
structure towards quality and sustainable growth which aims 
at reducing the impact of GHG-emission and environmentally 

friendly, due to the energy development policy and 
technological change to meet the climate goal.

Specific assumptions of each economic sector for both scenarios 
are shown in Table 1.

3. RESULTS AND DISCUSSION

3.1. Final Energy Consumption and GHG Emissions 
in the BAU Scenario
In the business-as-usual (BAU) scenario, during 2019–2050, 
results show that total final energy consumption increases from 
2,109 to in 2019 to 5,915 ktoe in 2050 and accounted for an 
average annual growth rate of 3.49%. In 2050, the industrial sector 
will be the largest energy-consuming sector and accounted for 
73.21% of total energy consumption. In addition, the transport, 
household, building agricultural and other sectors are accounted for 
14.57%, 6.69%, 4.57%, and 0.95% of total energy consumption, 
respectively (Figure 4).

The total final energy consumption by fuel type in the business-as-
usual (BAU) scenario in 2050, the highest proportion of electricity 
consumption at 53.01% followed by Biomass, Diesel, and LPG are 
accounted for 24.30%, 8.54%, and 6.80%, respectively (Figure 5). 
In the future, Rayong Province shall promote economic zones 
and industrial zones; consequently, Rayong Province has a large 
potential to increase energy demand, especially for electricity. 
When considering the non-electricity energy consumption in BAU, 
it found that the share of non-electricity energy consumption in 
2050 will change slightly from 2019 because it is not affected by 
any future projects or measures.

In addition, during 2019-2050, CO2 emission and accounted for 
an annual average growth rate (AAGR) of 3.20%, increases from 
1,949.0 ktCO2eq in 2019 to 3,756.9 ktCO2eq in 2050. More than 
half of CO2 emissions will be dominated by the transport sector. 
The transport sector accounts for 60% of total CO2 emissions from 
fuel combustion, followed by the industrial, building, agricultural 
and other, and household sectors at 22.18%, 11.21%, 4.01%, and 
2.73%, respectively (Figure 6). CO2 emissions will increase from 
26.76 ktCO2eq in 2019 to 38.45 ktCO2eq in 2050 in the rural area 
of the household sector (increased by 1.33% annually). Similarly, 
CO2 emissions in an urban area will increase with an AAGR of 
5.64%. Moreover, LPG demand for cooking in the urban area will 
be significantly higher than that in greater rural areas. Therefore, CO2 
emission will be 64.24 ktCO2eq in the urban area or 62.6% of total 
CO2 emission in the household sector in 2050. This is the reason why 
the household sector in an urban area has the highest CO2 emission.

3.2. Final Energy Consumption and GHG Emissions 
in the Low Carbon Scenario
In the low carbon scenario, due to the vigorous efforts paid toward 
removing fossil fuels from the Rayong Province (Figure 4), during 
2019–2050, the total final energy consumption slightly increases 
with an AAGR of 1.52%, from 2,077 to 2019 to 3,256 ktoe in 
2050. The industrial sector still is the largest energy-consuming 
sector as accounted for 71.1% of total energy consumption. In 
addition, the transport, household, building agricultural and other 

Figure 2: The structure of the household, building, and industry 
modules in the LEAP model

Figure 3: The structure of the transport module in the LEAP model



Lunsamrong and Tippichai: Energy Demand Modeling for the Eastern Economic Corridor of Thailand: A Case Study of Rayong Province

International Journal of Energy Economics and Policy | Vol 12 • Issue 2 • 2022500

sectors are accounted for 17.33%, 6.21%, 4.44%, and 0.92% of 
total energy consumption, respectively.

In the LCS, the advanced technologies will have an impact on the 
non-electricity energy demand, as the result, the proportion of non-
electricity energy consumption in 2050 will change significantly 
from 2019, especially fossil fuels, while the proportion of 
alternative energy and electricity consumption will increase.

In 2050, total CO2 emission will be 2,190.2 ktCO2eq with an 
AAGR of 1.31% per year. In addition, our analysis showed that 
CO2 emission in the LCS will be reduced by 1,566.7 ktCO2eq in 
2050 when compared to the BAU scenario (Figure 6) or reduced 
by 41.7%, by 2050 when compared with the BAU scenario, and 
the transport sector contributes more than half (about 56%) of total 
CO2 emission reductions from the Rayong Province.

Figure 4: Final energy demand by economic sector in Rayong Province; (a) BAU; (b) LCS

ba

Figure 5: Final energy demand by fuel in Rayong Province; (a) BAU; (b) LCS

ba

Figure 6: Energy-related CO2 emissions by sector in Rayong Province; (a) BAU; (b) LCS

ba

Table 1: Assumptions of each economic sector by scenario
Economic 
sector

Key driving force
Business-as-usual 
scenario

Low carbon scenario

Household Urbanization, 
Shifting from 
traditional fuel to 
LPG

Energy efficiency improvement 
of appliances, Shifting from 
traditional fuel to LPG, 
electricity, and biogas

Building Growth of value-
added, Building 
energy code

Utilization of Photovoltaic 
Rooftop towards net-zero 
energy buildings

Industry Driven by EEC 
and production-
based economy

Factory energy management, 
Smart Factories

Transport Vehicle ownership, 
Population, and 
income

Public transport promotion, 
Penetration of electric vehicles, 
Fuel economy improvement

Agricultural 
and other

Growth of value-
added

Productivity and technological 
improvement, Smart framing



Lunsamrong and Tippichai: Energy Demand Modeling for the Eastern Economic Corridor of Thailand: A Case Study of Rayong Province

International Journal of Energy Economics and Policy | Vol 12 • Issue 2 • 2022 501

Moreover, the entry of electric vehicles and fuel economy 
improvement can reduce demands for petroleum products, 
particularly gasoline and diesel. Although the increase of EVs 
on the road will lead to higher demands for electricity, it will 
reduce CO2 emissions in the transport sector. CO2 emission in 
the transport sector in 2019 were about 1,477 ktCO2eq and will 
increase to 2,248 ktCO2eq in 2050. CO2 emission will reduce by 
878.9 ktCO2eq in 2050 compared to the CO2 emission level of the 
transport sector in the BAU scenario (Figure 6). As anticipated, 
the low carbon scenario proves to be the case with the largest CO2 
emission potential.

4. CONCLUSION

The results of the Low Emissions Analysis Platform (LEAP) 
can be used for inputting data, analyzing energy consumption, 
forecasting future energy, and assessing greenhouse gas 
emissions consumption to set appropriate energy measures 
correctly. It can be used to plan energy appropriately and meet 
the potential of the province. Furthermore, the quality of the 
scenario depends on the quality of the data and the analytical 
process of the user.

This paper defined two scenarios. The results of the Business-
as-usual (BAU) scenario suggest a trend that it needs energy 
for all kinds of fuel. This is due to people lifestyles is changing 
gradually by income and quality of life rises. Environmental 
damages are increasingly becoming an issue. In the Low Carbon 
Scenario (LCS), the total final energy consumption will lower 
energy demand due to economic restructuring and intense energy 
efficiency push, moving toward a high value and low energy-
intensive sector.

Given the overall energy use within the various sectors in Rayong, 
the industrial and transportation sectors are the most final energy 
consumption and the highest CO2 emissions. The solution for 
this is to transform to alternative energies sources, e.g., clean 
electricity. The shifting of all production to the sustainable ones, 
by the successful restructuring of the industrial estate to become 
the eco-industrial and GHG emission management, will also result 
in obvious carbon reduction. The prospects of a sustainable urban 
energy system will depend on the energy policies initiated and 
implemented in the future.

5. ACKNOWLEDGMENTS

The authors would like to thank the Ministry of Energy, Thailand 
that supporting the statistical data of energy consumption of 
Rayong Province in this study.

REFERENCES

Chaichaloempreecha, A., Chunark, P., Limmeechokchai, B. (2019), 
Assessment of Thailand’s energy policy on CO2 emissions: 
Implication of national energy plans to achieve NDC target. 
International Energy Journal, 19, 47-60.

Chen, S., Liu, Y., Lin, J. Shi, X., Jiang, K., Zhao, G. (2021), Coordinated 
reduction of CO2 emissions and environmental impacts with 
integrated city-level LEAP and LCA method: A case study of Jinan, 
China, Advances in Climate Change Research, 12(6), 848-857.

Dioha, M.O., Kumar, A., Ewim, D.R.E., Emodi, N.V. (2021), 
Alternative scenarios for low-carbon transport in Nigeria: A long-
range energy alternatives planning system model application. 
In: Chaiechi, T, editor. Economic Effects of Natural Disasters: 
Theoretical Foundations, Methods, and Tools. Ch. 30. Cambridge, 
Massachusetts: Academic Press.

Emodi, N.V., Emodi, C.C., Murthy, G.P., Emodi, A.S.S. (2017), Energy policy 
for low carbon development in Nigeria: A LEAP model application. 
Renewable and Sustainable Energy Reviews, 68(1), 247-261.

Gebremeskel, D.H., Ahlgren, E.O., Beyene, G.B. (2021), Long-term 
evolution of energy and electricity demand forecasting: The case of 
Ethiopia, Energy Strategy Reviews, 36, 100671.

Hu, G., Ma, X., Ji, J. (2019), Scenarios and policies for sustainable 
urban energy development based on LEAP model a case study of a 
postindustrial city: Shenzhen China. Applied Energy, 238, 876-886.

Kehbila, A.G., Masumbuko, R.K., Ogeya, M., Osano, P. (2021), Assessing 
transition pathways to low-carbon electricity generation in Kenya: 
A hybrid approach using backcasting, socio-technical scenarios 
and energy system modelling, Renewable and Sustainable Energy 
Transition, 1, 100004.

Misila, P., Winyuchakrit, P., Limmeechokchai, B. (2020), Thailand’s long-
term GHG emission reduction in 2050: The achievement of renewable 
energy and energy efficiency beyond the NDC. Heliyon, 6, e05720.

Office of the National Economic and Social Development Council. (2019), 
Gross Regional and Provincial Product Chain Volume Measure. 
Available from: https://www.nesdc.go.th/main.php?filename=gross_
regional [Last accessed on 2021 Jul 30].

Wangjiraniran, W., Pongthanaisawan, J., Junlakarn, S., Phadungsri, D. 
(2017), Scenario analysis of disruptive technology penetration on 
the energy system in Thailand. Energy Procedia, 142, 2661-2668.