Solid Waste Landfill Site Identification Employing GIS-Based Multi-Criteria Decision Analysis Within the Thach That District, Hanoi, Vietnam

Oanh, N. T.,¹ Thanh, P. T.,^1*Long, N. B.,¹Chien, L. H.,¹ Dinh, N. T.,¹ Thom, T. T.,¹ Bich, N. T.¹ and Elshewy, M. A.²

¹College of Land Management and Rural Development, Viet Nam National University of Forestry, Vietnam

²Department of Civil Engineering, Faculty of Engineering, Al-Azhar University, Cairo, Egypt

*Corresponding Author

Abstract

The principal aim of this investigation was to identify optimal locations for solid waste landfill in the Thach That district of Hanoi. Employing Geographic Information System (GIS) and Multi-Criteria Decision Analysis (MCDA), nine thematic layers were assessed as pivotal criteria, including proximity to surface water, distance to historical and cultural sites, distance to rural population areas, proximity to waste collection points, current land use status, and slope. A Boolean logic model was applied based on the criteria outlined in the Vietnamese standard TCVN 6696: 2009, and Analytical Hierarchical Process (AHP) methodology was utilized for the analysis of the remaining criteria. The study results showed that 10,641.40 hectares were unsuitable, 7,867.60 hectares were less suitable and 220.89 hectares were suitable for a landfill, corresponding to 56.81%, 42.01%, and 1.18% of the study area, respectively. In terms of size, there are two unsatisfactory zones because the area is too small. Although the distance from suitable locations to some communes in Thach That district is quite far, about 20km, it is equivalent to the distance to the current. Therefore, these positions are accepted. This research has profound significance because it contributes to adding scientific basis for choosing landfill locations not only in Thach That district but also in Vietnam.

Keywords: AHP, GIS, Landfill Site Selection, MCDA, Solid Waste

1. Introduction

As outlined in the National Environmental Status Report spanning the period 2016 to 2020, Vietnam is experiencing a notable surge in the overall quantity of generated solid waste nationwide. Statistical estimates indicate an annual escalation in the range of 10-16% for solid domestic waste (SDW) in urban areas on a national scale. Industrial solid waste, quantified at 25 million tons per year, likely surpasses this figure due to underrepresentation, as industrial facilities beyond designated parks and clusters are incompletely accounted for. Ordinary solid medical waste production is approximately 96 thousand tons per year. The solid waste emanating from livestock activities and crop by-products is recorded at approximately 85-90 million tons and nearly 95 million tons per year, respectively [1].

In 2019, the total volume of SDW developed nationwide was 64,658 tons/day [2]. In most localities, the most common form of household waste treatment is landfilling, accounting for about 71%. In Hanoi City, the rate of landfilling SDW is 89%, the rate of burning (without generating electricity) is 11.0% [2]. The rate of industrial solid waste collected and processed reaches 90% of the generated volume. Most medical solid waste in hospitals is collected and classified daily at source. The application of solid waste treatment technologies is still limited [1]. In the Decision sanctioning the solid waste management plan for Hanoi Capital until 2030, with a perspective extending to 2050, it is stipulated that the capital city will be equipped with 17 solid waste disposal complexes [3].

Presently, however, only three operational solid waste disposal complexes exist: Nam Son Solid Waste Disposal Complex in Soc Son district, Xuan Son Solid Waste Disposal Complex in Son Tay town, and Cau Dien Solid Waste Disposal Complex in Nam Tu Liem district. Many wastes disposal complexes are behind schedule due to problems with site clearance. In Thach That district, the solid waste disposal complex in Lai Thuong commune was approved with an area of 4 hectares by 2020; In 2030, it will be 6 hectares; In 2050, it will be 11.8 hectares, but due to inappropriate location selection, people's complaints, and disagreement, it has not yet been implemented. can be constructed. On the other hand, in the district, there are spontaneous landfills on many roads and waste is jammed and overloaded at the dumps with all kinds of waste, from household waste to industrial waste (Commune Canh Nau, Huu Bang, Kim Quan, Di Nau, Chang Son, etc.) cause serious environmental pollution, affecting the landscape as well as people's lives. Therefore, it is extremely necessary to research and select a suitable solid waste landfill location in Thach That district.

Numerous countries globally have proactively engaged in the early planning of suitable locations for solid waste landfills due to the adverse impacts it poses on the environment, public health, society, and the economy. Addressing this intricate spatial analysis challenge is imperative for effective land use and urban planning. The complexity of the issue necessitates the evaluation of diverse criteria spanning nature, economics, society, and the environment [4]. Methodologically, multi-criteria analysis emerges as the most fitting approach, with Geographic Information System (GIS) serving as a potent decision support tool [5]. GIS facilitates the analysis and processing of spatial data, the computation of numerous criteria, and the integration of informational layers, thereby aiding in the identification of optimal landfill locations. Notably, a multitude of studies worldwide have successfully employed GIS and multi-criteria decision analysis (MCDA) methodologies for solid waste landfill site selection in various countries, including Thailand, India, Indonesia, Iran, Iraq, Turkey, Zambia, Pakistan, Ethiopia, among others [6][7][8][9][10][11][12] [13] and [14].

Multi-Criteria Decision Analysis (MCDA), also referred to as Multi-Criteria Decision-Making (MCDM), involves the process of decision-making when multiple criteria or objectives need to be collectively considered to rank or choose between alternatives. The applications of Multi-Criteria Decision Analysis (MCDA) primarily involve the evaluation of process impacts on the environment and aiding planning endeavors in determining optimal locations for specific purposes. The Analytic Hierarchy Process (AHP), developed in the late 1970s, has emerged as the predominant method within MCDA. AHP facilitates the determination of criteria weighting and alternative preferences by eliciting values through pairwise comparisons, rather than relying on direct numerical assessments.

Criteria for landfill location analysis are aggregated from diverse fields, encompassing binding environmental regulations, as well as natural and socio-economic conditions in the area. Spatial data, sourced from various outlets, is also incorporated. Research findings demonstrate that the amalgamation of Geographic Information System (GIS) and multi-criteria analysis amplifies the decision-making capacity of planners and relevant agencies in the selection of suitable landfill locations. This integrated approach contributes significantly to mitigating environmental concerns, including water contamination and public health degradation associated with inadequate waste disposal sites.

2. Materials and Methods

2.1 Study Area

Thach That district is a suburban district located northwest of Hanoi, a semi-mountainous area, with geographical coordinates from: 20^°56'45" to 21^°06'10" North latitude and 105^°23'30" to 105^° 38'22" East longitude as shown in Figure 1. Thach That district is located in the Northern Delta, but is also a transition area between the Northern mountainous and midland regions and the plains. In general, the terrain gradually lowers from West to East and is divided into three main terrain types: Low mountainous terrain¸ accounts for 29.0% of the entire district area. Although the terrain slope is not large, compared to other regions in the district, it is much larger. The terrain is semi-mountainous and hilly, accounting for 46.0% of the entire district. The average height above sea level in this area is from 10m - 15m. In the area there are many independent, low, gentle hills, with an average slope of 30 - 80 degrees. Plain terrain, accounting for 25.0% of the entire district area. The terrain is quite flat, the average terrain height ranges from 5m - 10m above sea level.

The climatic conditions in Thach That exhibit characteristics of a tropical monsoon climate, characterized by high temperatures and humidity, accompanied by substantial rainfall during the summer and a dry, colder period in winter. The mean annual temperature stands at 23.4°C, with an average annual precipitation of 1,628mm.

Figure 1: Thach That District, Hanoi, Vietnam

The region experiences an annual average of 1,680 hours of sunshine, while the prevailing air humidity is registered at 83.0%, with an annual evaporation rate of approximately 86.0mm. Notably, during the cold season from November to March of the succeeding year, the dominant wind direction is influenced by the Northeast monsoon. The remaining months of the year are dominated by Southeast winds. Occasionally, southwest winds appear in June and July. The district has 22 communes and 01 town with a district population of 253,786 people, and an economic growth rate of 13.6%. Economic structure: Industry and construction account for 69.2%; trade and services account for 25.0%; Agriculture, forestry, and fisheries account for 5.8%. Nowadays, this is the district with the most craft villages in Hanoi, with a rich and diverse system of craft villages, with a long tradition and famous nationwide. Currently, the district has more than 50 craft villages, of which 9 villages are recognized as traditional craft villages.

2.2 Data Collection

The investigation utilized QGIS3 and MicroStation V8i software in conjunction with both spatial and non-spatial datasets. The raster data employed a Digital Elevation Model (DEM) with a 30-meter resolution, obtained freely from the United States Geological Survey (USGS) website (https://earthexplorer.usgs.gov).

Vector data layers were derived from the Thach That district's land use status quo map at a 1/10,000 scale, supplied by the Department of Natural Resources and Environment. Attribute data was gathered from specialized departments within the Thach That District People's Committee. The study employed the EPSG:5897 reference coordinate system, specifically VN-2000 / TM-3 zone 482 – Projected.

2.3 Methods

2.3.1 Criteria selection for suitable landfill site

The criteria were identified based on the Vietnamese standard TCVN 6696: 2009 - Solid wastes - Sanitary landfill - General requirements for environmental protection. This is a standard established by Vietnam's national technical standards committee established by the Ministry of Science and Technology of Vietnam. Members of the national standards technical committee include representatives of state agencies, science and technology organizations, societies, associations, businesses, other relevant organizations, consumers and experts. This standard stipulates general environmental protection requirements for the location, design, construction, operation and monitoring of environmental impacts after closure hygienic landfills for burying regular solid waste. This standard does not apply to hazardous solid waste landfills.

Moreover, the chosen criteria are grounded in prior scholarly investigations, the inherent natural and socio-economic conditions of the study area, and the capabilities of data collection. These criteria serve to delimit the placement of a landfill facility, with the overarching objective of preserving environmental integrity, public health, and various pertinent social considerations. There are three criteria identified from Vietnam standard 6696: 2009 distance to urban population area, distance to main roads (National highway, provincial road, highway) and distance to industrial zone [15]. The six criteria selected include distance to surface water, distance to historical and cultural sites, distance to rural population area, distance to waste collection points, land use status quo, slope.

2.3.2 Multi-Criteria Decision Analysis (MCDA)

Multi-Criteria Decision Analysis (MCDA) involves the identification of criteria and the assignment of weights to factors according to their relative significance. Various MCDA methodologies find application in a spectrum of decision-making endeavors, encompassing the discernment of optimal landfill sites [12]. In this investigation, Boolean Logic, Analytic Hierarchy Process (AHP), and the Weighted Linear Combination method (WLC) were employed.

A suitability map for landfill sites in Thach That district, Hanoi city, was generated through the application of GIS and MCDA. The three identified criteria are based on the standards specified in the Vietnamese standard TCVN 6696: 2009 such as distance to urban population area, main roads, industrial zone; combined with six criteria related to actual local conditions and data that can be collected such as distance to surface water, historical and cultural sites, rural population area, collection points, land use status quo and slope. The study results showed 10,641.40 hectares representing 56.81% of the investigation area was unsuitable, 7,867.60 hectares representing 42.01% of the investigation area was less suitable and 220.89 hectares representing 1.18% of the investigation area was suitable for a landfill. Suitable locations for solid waste landfills are located in communes such as Canh Nau, Di Nau, Huu Bang, Phung Xa, Dai Dong, Cam Yen and Tien Xuan. Among them, the locations with the largest area and highest suitability index are located in Di Nau and Canh Nau communes. In Lai Thuong commune, there is no suitable location to choose as a solid waste landfill. This shows that the planning of solid waste landfills in 2011 here is not appropriate.

Considering the size of the landfill, there are two areas that are not suitable because the area is too small. Of the remaining seven zones, there are three zones suitable for small landfills and four zones suitable for medium landfills. Although the distance from suitable locations to some communes in Thach That district is quite far, about 20km, it is equivalent to the distance to the current landfill in Xuan Son commune and Son Tay town. Therefore, these locations are suitable for solid waste landfills in Thach That district in particular and Hanoi city in general. This research is highly significant as it contributes to the ongoing knowledge regarding the selection of suitable landfill sites in developing countries, emphasizing both scientific credibility and social acceptance. Moreover, the findings have the potential to offer valuable insights to the administrators and planners of Hanoi city, assisting them in identifying an appropriate site for solid waste landfill and addressing challenges related to solid waste management administration.

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