WBroader understanding of waste management is an increasingly visible and essential element to functioning civilization. However, while the theory of waste management is studied widely, waste management remains for many a difficult concept to understand. There ishas the potential to bring about broad societal change impacting the climate crisis and public health. A survey motivates the need for enhanced interactive tools providing clear feedback through quick visibility performance indicators. After identifying an opportunity to create an informative,build upon highly-detailed multi-criteria simulation tools, we explore the need for easy-to-use simulator to help all types of individuals build an understanding of read performance metrics that will bring to the field of waste management easily identifiable and measurable key performance indicators (KPIs) that vary alongside factors affecting waste management and to evaluate the impact of various changes on policies. Such metrics are introduced and detailed as part of a unified waste management performance, particularly in the context of gamified tools model. We then develop a representative gamified educational tool based upon this model to be used by students, decision makers planning real-world policies, and the public.
This section presents commercial games and research tools that include as a central theme elements of waste management and waste management modelling. We present popular games such as “Sim City 4” and “Cities: Skylines” alongside research tools like “NetLogo” and explore the level of depth of their waste management approach as well as their relative strengths and opportunities for improvement.
Commercial Games /Research Tools |
Information about Waste Management Systems |
---|
SimCity 4 | All waste lumped as “garbage” |
Multiple disposal avenues (Landfill, Recycling, Waste-to-Energy) |
|
Waste accumulation reported though desirability reports, Mayor Rating |
|
Cities: Skylines | All waste lumped as “garbage” |
Multiple disposal avenues (Landfill, Recycling, Incinerator, Waste Processing, …) |
|
Waste accumulation reported though feedback bubbles |
|
Wu and Huang’s Research Tool [6] |
All waste lumped as “garbage” |
Multiple disposal avenues (Waste Product Dump, Incinerator, Environment Factory, Trading Companies) |
|
Waste accumulation reported though reports of garbage-driven natural disasters |
|
Wood of War | Multiple waste monsters found with varied garbage piles |
Waste disposed of by defeating monsters Real-world waste reported through GPS tags |
|
Real-world waste build-up is communicated to developers, authorities |
|
NetLogo | All waste types lumped |
Sociotechnical approach for complex waste management and decision-making |
|
Waste management parameters (agents) executed serially. Empirical calibration necessary to mirror real-world scenarios. |
Waste management tools are important to informing policy and educating the public about the consequences of waste and necessary remediation. Here, we evaluate critical waste parameters as a means of identifying the policy and procedural “levers” suitable for changing certain key metrics. We will use the developed metrics and models as the basis for the development of our novel waste management simulator. Based on the team’s prior field research [12][13][14][15][16], we present what we believe to be the most crucial and measurable factors in waste management to inform the design and development of a waste management tool (as described in Section 4). This way, we are trying to model an approximation of the problem, but not optimize it, as our first step.
These factors are the Key Performance Indicators and are showcased in Section 3.2.
3.2. Key Performance Indicators
The KPIs chosen to create a realistic user interface for the virtual city are amongst those widely used in waste management analysis [12][13][15][16][17][18][19] and include: Waste Compositional Analysis (MSW-C), Municipal Solid Waste Production (MSW-P), Municipal Solid Waste Recycling (MSW-R), Waste Production Rate (WPR), Waste Recovery Rate (WRR), Generation Rate (WGR), Waste Infrastructure (WI), Clean Index (CI), Accumulation Rate (AR) and Accumulation Index (AI), Mobility, Renewable Energy, Waste Water Treatment Plant, Air Pollution, and Strategies.
3.2.1. Waste Compositional Analysis(MSW-C)
MSW-C provides the data pertaining to the several produced waste streams, providing authorities with measurable data to design and implement waste prevention and waste management strategies [13][18]. MSW-C categorizes the types of material in solid waste such as PMD, Plastic Film, non-recyclable Plastic, Aluminium and Ferrous objects, Paper, Glass, Toilet and Kitchen Papers, Edible Food Waste, Inedible Food Waste, Organic Waste, and other materials [13]. To provide a representative baseline for the creation of a novel waste management simulator, a study in the Area of Paralimni, Cyprus was used. In the study, according to the population of the area in 2011 (18,601 residents), 15,100,000 tonnes of municipal solid waste were produced [12][13][15]. According to the compositional analysis carried out for the population of 18,601, the numbers were scaled to reflect the population of the virtual city (100,000). The estimated amount of each type of waste as scaled up for the virtual city is shown in Table 2.
Table 2. Waste Compositional Analysis categories, percent relative range and scaled amount of Waste for the virtual City.
Categories of Waste |
Range (%) |
Scaled Estimated Amount (tn) |
PMD |
5–30 |
7639 |
Plastic Film |
1–7 |
3588 |
Plastics Non-Recyclable |
1–3 |
1835 |
Aluminium/Ferrous |
0.5–2 |
682 |
Paper |
5–20 |
8572 |
Glass |
1–7 |
4327 |
Toilet and Kitchen Paper |
1–15 |
9652 |
Food Waste (edible) |
2–20 |
12,055 |
Food Waste (inedible) |
2–20 |
4091 |
Organic Waste(Green Waste, Yard Waste) |
2–20 |
22,243 |
Others |
1–10 |
6494 |
Total |
81,178 (figures per [13]) |
MSW-C is defined in Equation (3). The equation presents the ratio of the known reported amount of each category of MSW(QknownMSW) to the total amount of MSW(QTotalMSW) at a given time(t) [18]:
The values are adapted from [13].
3.2.2. Municipal Solid Waste Production(MSW-P)
MSW-P represents the ratio of the amount of MSW produced (QTot) to the population (POP) at a given time (t) in the selected area (see Equation (4)). This indicator delivers a ratio of the average waste quantity per capita [12][13][18]. City geometry and population determine the range of this number:
3.2.3. Municipal Solid Waste Recycling (MSW-R)
MSW-R measures the MSW that has been recycled (QRecycledMSW) in comparison with the total solid waste produced (QTotalMSW) at a moment in time (t), per Equation (5). Table 3 presents the categories of the recycled waste which are PMDs,
Paper and Glass [12][13][16]. These numbers will be useful in the strategic planning of
Waste Management Systems, give information on the prevention activities performed in each area as well as provide data regarding the technical aspects of Waste Management like Waste Bin Capacity, types of Recycle Bins in each area, etc. [12]:
The data used in Table 3 were obtained from www.greendot.com.cy, accessed on October 24, 2021, and reflect figures for Paralimni, Cyprus in 2011 as scaled to fit the virtual city’s population of 100,000 [20]. Green Dot Cyprus Public Co Ltd. is a nonprofit organization and the first collective recycling system approved by the Ministry of Agriculture, Rural Development and Environment in Cyprus. It is established based on the Packaging and Waste Packaging (Amendment) Law, 2005 (Law No. 159(I)/2005) of Cyprus and implemented based on Directive 2003/35/EC of the European Parliament and the Council of the European Union [21][22].
Table 3. Municipal Solid Waste Recycling Categories and Range.
Glass | ||
4327 |
3000–5000 |
|
Toilet and Kitchen Paper |
9652 |
8000–11,000 |
Food Waste (edible) |
12,055 |
10,000–14,000 |
Food Waste (inedible) |
4091 |
3000–5000 |
Organic Waste (Green Waste, Yard Waste) |
22,243 |
20,000–25,000 |
Others |
6494 |
5000–7000 |
Table 316. The Lower and Upper Bounds for each of the categories for all population options. These values were scaled based on the range from Table 15.
Population: 1500 |
Population: 2000 |
Population: 5000 |
Population: 6500 |
Population: 7000 |
Population: 10,000 |
Population: 18,000 |
Population: 20,000 |
Population: 30,000 |
||||||||||
Lower Bound |
Upper Bound |
Lower Bound |
Upper Bound |
Lower Bound |
Upper Bound |
Lower Bound |
Upper Bound |
Lower Bound |
Upper Bound |
Lower Bound |
Upper Bound |
Lower Bound |
Upper Bound |
Lower Bound |
Upper Bound |
Lower Bound |
Upper Bound |
|
PMD |
750 |
1500 |
100 |
200 |
250 |
500 |
325 |
650 |
350 |
700 |
500 |
1000 |
900 |
1800 |
1000 |
2000 |
1500 |
3000 |
Plastic Film |
300 |
750 |
40 |
100 |
100 |
250 |
130 |
325 |
140 |
350 |
200 |
500 |
360 |
900 |
400 |
1000 |
600 |
1500 |
Plastic Non Recyclable |
150 |
450 |
20 |
60 |
50 |
150 |
65 |
195 |
70 |
210 |
100 |
300 |
180 |
540 |
200 |
600 |
300 |
900 |
Aluminun/ Ferrous |
75 |
150 |
10 |
20 |
25 |
50 |
32 |
65 |
35 |
70 |
50 |
100 |
90 |
180 |
100 |
200 |
150 |
300 |
Paper |
900 |
1500 |
120 |
200 |
300 |
500 |
390 |
650 |
420 |
700 |
600 |
1000 |
1080 |
1800 |
1200 |
2000 |
1800 |
3000 |
Glass |
450 |
750 |
60 |
|||||||||||||||
Categories |
Range (%) |
Estimated Amount (tn) |
||||||||||||||||
PMD |
50–100 |
3819 |
||||||||||||||||
Paper |
50–100 |
4286 |
||||||||||||||||
Glass |
80–100 |
3461 |
||||||||||||||||
Total |
5172 |
3.2.4. Waste Production Rate (WPR)
WPR illustrates fluctuations in the volume of waste produced annually. These fluctuations inform the actions necessary to minimize waste production increases [12][18]. With the use of WPR, a possible percentage of achievement until a given time can be evaluated. WPR can be calculated using Equation (6):
3.2.5. Waste Recovery Rate (WRR)
WRR indicates the recovery of generated waste in a specific period (Equation (7)). Numerous recovery options are available, including recycling, reuse, waste to energy, etc. WRR should not be misinterpreted for MSW-R, as waste stream recycling states the actual percentage of recycled material in a particular area with a specific population density, whereas WRR refers to the potential of recovering 100% of any significant waste stream like plastic, paper, etc. Waste recovery informs waste prevention strategies to reach the full potential of recovery of a stream [12][16][23]. The recovery rate of each material is listed in Table 4:
Table 4. Typical municipal solid waste recovery rates.
Range of Recovery (%)
100 | ||||||||||||||||||
150 | ||||||||||||||||||
250 | 195 |
325 |
210 |
350 |
300 |
500 |
540 |
900 |
600 |
1000 |
900 |
1500 |
||||||
Toilet and Kitchen paper |
1200 |
1650 |
160 |
220 |
400 |
550 |
520 |
715 |
560 |
770 |
800 |
1100 |
1440 |
1980 |
1600 |
2200 |
2400 |
3300 |
Food Waste Edible |
1500 |
2100 |
200 |
280 |
500 |
700 |
650 |
910 |
700 |
980 |
1000 |
1400 |
1800 |
2520 |
2000 |
2800 |
3000 |
4200 |
Food Waste Inedible |
450 |
750 |
60 |
100 |
150 |
250 |
195 |
325 |
210 |
350 |
300 |
500 |
540 |
Categories |
Min range of recovery (%) |
Max range of recovery (%) |
Estimated Waste Recovered (tn) |
PMD |
50 |
100 |
3819 |
Aluminium/Ferrous |
50 |
100 |
341 |
Paper |
50 |
100 |
4286 |
Glass |
80 |
100 |
3461 |
Food waste |
50 |
100 |
8073 |
Green Waste |
80 |
100 |
17,794 |
37,776 |
3.2.6. Waste Generation Rate (WGR)
WGR estimates the generation of waste in the selected area in unit of time (i.e., per day, week, month, or year) and is represented by Equation (8) [16][24]. As product and service demands increase along with economic and population growth, waste generation is inevitable. World waste production was estimated at approximately 1.30 billion tonnes in 2012 and by 2016 waste generation reached 2.01 billion tonnes of waste. If waste generation continues in the same trajectory, by 2050, this number is estimated to reach on average 3.40 billion tonnes of waste [25][26]. The indicator provides an assessment of an area’s ecological trends as well as showcase the effectiveness of any sustainability practises and strategies implemented in that area according to the increase or decrease of its value.
WGR will vary with the population density of each selected area in the virtual city. As the total quantity of waste produced for the 100,000 citizens is 65,000 tones, an average citizen will produce 650 kg/year.
3.2.7. Waste Infrastructure (WI)
A crucial indicator (Equation (9)) concerning environmental performance is the available waste management infrastructure. WI estimates without limitation the number of bins and collection bins in general in a specific area. It provides useful information about the current infrastructure in relation to the residential density of that area [12][13][16].
Depending on area, the user will be able to choose from one to all the bins listed in Table 5. WI depends strongly on the population density; as population density increases, the number of bins will increase proportionally. Depending on the user’s choice, the outcome will be different. For population density of 100,000 citizens and 65,000 tones of waste, 750 bins are required. This indicator provides useful information to inform policies and actions required in relation to the existing infrastructure and number of citizens [12][13].
The range of recycle bins per population density must comply with the requirements of the level of services presented in Section 3.2.8. The minimum range of waste bin capacity must be the minimum 0.5–1.5 L/capita in line with 3(C) and maximum/over 1.5–2.5 L/capita as mentioned in level 1(A) in Table 6 [12][15].
Table 5. Types of recycling bins proposed range per population density and range.
900 | |||||||
600 | |||||||
1000 | 900 | 1500 | |||||
Organic Waste |
3000 |
3750 |
400 |
500 |
1000 |
||
Categories |
Bin Colour |
Proposed Range |
|||||
Recycle Bin for: |
|||||||
Plastics |
Yellow |
||||||
Paper |
Brown |
||||||
PMD |
Blue |
min: W.I > 0.5–1.5 L/capita |
|||||
Mixed waste |
Green |
max: W.I > 1.5–25 L/capita |
|||||
Food Waste |
Pink |
||||||
Green Waste |
Light Green |
||||||
Batteries |
Transparent |
||||||
Glass Packaging |
Grey |
||||||
Aluminium |
Perforated |
3.2.8. Clean Index (CI)
CI rates how clean the selected area is using Equation (10), where NIcol is the number of items collected (i.e., cigarette butts, PMD, papers, other plastics, etc.) and Sur is the surface in m2 of the specific selected area. K is a constant equalling 20 [12][15][16][27].
Table 6 is used to scale the area accordingly [16]. Using CI, the infrastructure of the selected area can be assessed to optimize activities including waste collection period, cleaning department size, number of recycling bins per citizen, etc. The indicator was first suggested by Alkalay [27]:
According to [12][15][16], the Level of Services (LoS) may be interpreted as:
1250 | |||||||||||||||
1300 | |||||||||||||||
1625 | |||||||||||||||
1400 | 1750 | 2000 |
2500 |
3600 |
4500 |
4000 |
5000 |
6000 |
7500 |
||||||
Others |
Table 6. Clean Index Identification.
Quality |
Level of Sevices (LOS) |
CI |
Identification |
Very Clean |
1(A) |
0–2 |
No litter seen |
Clean |
2(B) |
2–5 |
No litter seen over a large area |
Moderate |
3(C) |
5–10 |
A few pieces of litter visible |
Dirty |
4(D) |
10–20 |
A lot of litter visible |
Very Dirty |
5(E) |
20+ |
Most of the area is covered in litter |
3.2.9. Accumulation Rate (AR)
AR evaluates the accumulation of waste per unit of surface area and unit time (items/m2/day) (Equation (11)) [12][13][17]. AR is directly affected by population density as, consequently, the more people there are in an area, the more waste will exist [28]. T represents the time elapsed between the survey and the last cleaning activity which also gives an indication of the number of days since the responsible authority completed a full cleaning of the researched area [29]:
3.2.10. Accumulation Index (AI)
AI takes into account the rate of accumulation of liter (Equation (12)), complementing CI and AR. While CI assesses area cleanness and hence the collection period, AI and AR evaluate the accumulation of waste at a given area in a specific period [15]. Table 7 represents the classification given by [16]:
LOS is explained in Table 6.
Table 7. Accumulation rate and index classification.
750 | ||||
LOS |
WAI |
WAR (items/m2/day) |
WAR (items/km2/day) |
|
Extremely Low |
1 |
≤1 |
0.000001 |
1 |
Very Low |
2 |
1–2 |
0.00001 |
10 |
Low |
2–3 |
2–3 |
0.0001 |
100 |
Moderate |
3 |
3–4 |
0.001 |
1000 |
High |
4 |
4–5 |
0.01 |
10,000 |
Very High |
4–5 |
5–6 |
0.1 |
100,000 |
Extremely High |
5 |
≥6 |
1 |
1,000,000 |
3.2.11. Air Pollution
Air Quality Indication (AQI) illustrates the gas emissions in the virtual city including simulated CO2, CO, NO, NO2, SO2, O3 and Benzene as shown in Table 8. The correlation of air pollution with human activity is of significant interest, and are driven by emission sources like vehicles and industrial processes [30]. Greenhouse gas emissions from solid waste treatment emerge mainly from uncontrolled disposal and dumping as well as incineration [26].
The urbanization of the last 60 years has created high transportation network density, encouraged building development, and driven population growth that promote the consumption of variously-sourced energy sources and energy in general while the lifestyle in urban environments make the application of environmentally conscious actions appear to be a far off necessity rather than a personal responsibility [31]. Air quality management is vital to both protect human health and improve the quality of life in urban and industrial areas [32]. Strategies to better handle waste management can decrease greenhouse gas emissions by as much as 200 million tonnes by 2030 [26][33].
The limits were provided considering the existing proposed limits by www.airquality .dli.mlsi.gov.cy/, (accessed on 24 October 2021) presenting the pollutants concentration values in Cyprus in real time. The results can be easily accessed from the official Air Quality Cyprus mobile application [34].
Table 8. Gas emissions observed.
1050 | ||||||||||||||||
100 | ||||||||||||||||
140 | ||||||||||||||||
250 | 350 |
325 |
455 |
350 |
490 |
500 |
700 |
900 |
1260 |
1000 |
1400 |
1500 |
2100 |
|||
Categories |
Range (%) |
Low |
Moderate |
High |
Very High |
|||||||||||
PM10 |
0–100 |
0–50 |
50–100 |
100–200 |
>200 |
|||||||||||
PM2.5 Carbon Dioxide (CO2) Carbon Monoxide (CO) |
0–100 |
0–25 |
25–50 |
50–100 |
>100 |
|||||||||||
To be defined |
||||||||||||||||
0–100 |
0–7000 |
7000–15,000 15,000–20,000 |
>20,000 |
|||||||||||||
Nitrogen Monoxide (NO) |
0–100 |
|||||||||||||||
Nitrogen Dioxide (NO2) |
0–100 |
0–100 |
100–150 |
150–200 |
>200 |
|||||||||||
Sulphur Dioxide (SO2) |
0–100 |
0–150 |
150–250 |
250–350 |
>350 |
|||||||||||
Ozone (O3) |
0–100 |
0–100 |
100–140 |
140–180 |
>180 |
|||||||||||
Benzene (C6H6) |
0–100 |
0–5 |
5–10 |
10–15 |
>15 |
3.2.12. Mobility
The Mobility metric indicates the public transportation available for a given population density. Mobility is directly interlinked with fuel consumption and greenhouse gas emissions. This indicator helps authorities explore new innovative mobility plan strategies in order to limit the environmental impact of transportation, especially in urban areas [35]. The use of public transportation in the simulation versus the choice of the user to transfer by car will make a crucial difference regarding gas emissions. The choices of public transportation offered in the virtual city are listed in Table 9.
Table 9. Available transportation choices.
Transportation |
Buses |
Trams/Trolleys |
Trains/Underground Metro |
Bike lanes |
Walk lanes |
Electric Cars |
Important criteria for the selection of Mobility transportation Choices should be when applicable:
3.2.13. Green Space
The Green Space KPI denotes free green space per population density in m2 or km2 (Equation (13)). Green spaces include parks, open-air sport facilities, playgrounds, etc. [37].
Strategic urban planning for land management encourages good living conditions due to psychological factors and also the reduction of the environmental impact of urban areas [38]. Natural and semi-natural areas designed in urban cities serve not only recreational and aesthetic stress reducing purposes but provide an improved living environment. This is achieved by natural processes in the presence of biodiverse green spaces like purifying the air and water, providing protection from extreme weather conditions like heat and thunderstorms, and also contributing to the reduction of noise pollution [39].
The strategic distribution of green areas across the virtual city is essential in order for all the citizens to have access to these green spaces. Therefore, Green Space must be closely coupled to population density as well available public free space.
Table 10 indicates the choices of the user regarding green space categories. The limits were chosen according to the recommendations of the World Health Organization [40][41].
Table 10. Green space requirements per capita.
Green Space Categories |
Green Space Requirements (m3/capita) |
Green Space (Parks, Playgrounds, Open-air Sport Facilities) |
min: 9 m3/capita optimum: 50–57 m3/capita |
3.2.14. Renewable Energy Sources (RES)
Fossil fuels have been a primary energy source for cities for decades. Wasteful handling of raw materials, food, and energy made necessary the creation of innovative renewable energy technologies [42]. The use of renewable energy sources, coupled with emerging energy storage technologies, may present a more balanced approach towards sustainable socioeconomic development and prosperity [43]. Production of renewable domestic energy is of interest as a means of managing the need for raw materials that each technology requires [43][44].
The RES available are listed in Table 11, calculated per population density or km2. The available categories of RES and the percentage they hold in the Total Energy production are Photovoltaic (P/V) Parks (1–5%), P/V Houses (5–100%), and Wind Parks (1–4%) according to the Transmission System Operator Cyprus for the year 2020 and the Cyprus Energy Regulatory Authority [45][46]. The indicator measures the number of RES in place and national targets.
Table 11. Renewable Energy Sources percentage share in Total Energy Production.
Category |
RES Share in Total Energy Production (MWh) |
RES (P/V Parks, P/V houses, Wind Parks) |
min: 11.7% (63,176 MWh) max ≥ 32% (≥114,760 MWh) |
Data provided by the Transmission System Operator Cyprus for the year 2020 and the Cyprus Energy Regulatory Authority [45][46]. The data collected concerned the population of Cyprus of 888,000 citizens for 2019 and were scaled down for the 100,000 of the virtual city [47]. The optimum maximum limit of 32% of Renewable Energy Sources in Total Energy Production is derived from the Policy framework of the European Commission in 2014 for 2030 [48].
3.2.15. Waste Water Treatment (WWT)
Urban wastewater management constitutes a challenging topic due to poor synchronization among infrastructure development and population growth. The main concern of Waste Water Treatment is to protect the environment and specifically the surface of waters from organic pollution and the degradation of aquatic life as well as the protection of human health [49]. In real life situations, agglomerations and collection systems provide a much more provable approach regarding the level of treatment of wastewater. Agglomerations, referred to as a sufficiently concentrated area for wastewater to be collected and further conducted to a nearby treatment plant, are usually required to be sufficient for a number of populations equivalent (1 Population Equivalent (P.E) unit is the organic biodegradable load of having a five-day biochemical oxygen demand (BOD5) of 60 g of oxygen per day) [50]. The Urban Waste Water Treatment Directive (WWTD) which is directly linked to zero waste ambitions in the European Green Deal requires all European settlements to provide their cities with agglomerations of the size of 2000 population equivalents or above and equipment (i.e., Collection systems, Wastewater Treatment Plants) sufficient for the waste water [51].
In this section, the indicator of Equation (14) presents only the number of houses connected to the waste water treatment plant with a range of values from 0–100% [52]. This range submerges from data of Eurostat% [53], where, until 2018, Denmark, Latvia, France, Malta, Finland, Austria, and the Netherlands had a 100% of their population connected to a Wastewater Treatment facility, whereas Kosovo maintained only a 0.52% of the population connected to wastewater treatment with the very next being Serbia with 14.12. Due to the fact that the quality of wastewater treatment emerges from the level of treatment (Primary, Secondary, Tertiary) as well as the available infrastructure mentioned above (Agglomerations and collection system), the indicator will be used regarding the following conditions:
3.2.16. Strategies
Seeking to grow a sustainable world has necessarily increased the strategic relevance of waste prevention [54]. To reduce the impact of industrial processes that affect severely the environment, corporate policies must be set in place. The main focus of waste prevention strategies is the reduction of landfill material, resource saving, the protection of human health, and improved quality of life by sustainable economic development [14][18]. Strategies available include circular economy, the European Green Deal, the United Nations Sustainability Goals, Zero Waste Policy, Energy Recovery, Smart Cities, Environmental Management Systems, and R-strategies [12][28][43][55][56][57]. Strategies like these, effectively implemented, will create a social shift in attitude that is vital to the success of any policy or indicator. Table 12 illustrates the user’s available choices [16][43].
Table 12. Strategies for action.
Categories |
Circular Economy |
European Green Deal (EGD) |
United Nations Sustainability Goals (UNSDGs) |
Zero Waste Policy |
Low Carbon Society |
Waste Prevention |
Energy Recovery |
Smart City |
Environmental Management Systems (i.e., ISO14001, EMAS) |
R-strategies |
Corporate policies, such as ISO 14001, EMAS, zero waste, etc., can reduce the impact of industrial processes on the environment by limiting energy requirements, improving waste water treatment processes, and increasing the social acceptance of such initiatives [12][16][28][43][55][56][57].
At the same time, alternative energy scenarios which revolve around renewable energy resources and/or energy recovery ensure the supply of reliable and efficient energy and utilisation [58]. The emissions related to fossil fuels combined with climate change have already forced many countries worldwide to explore strategies for better energy sources compared to the global energy mix [59]. The transition to clean renewable energy and zero emissions can be enabled by a shift to a more circular economy [43].
The concept of a Circular Economy (CE) is powerful tool many social groups including policy makers, urban designers, and academics employ to fundamentally link resource use with waste. CE is recognized by the European Union as an “irreversible global mega trend” and is now an essential strategy for the accomplishment of the goals set in the European Green Deal [43][60]. The shift from a linear to circular approach can result in the implementation of environmental and economic policies in order to achieve waste prevention, reuse, and recycling which directly contributes to clean production and manufacturing. This creates a stronger economy where resources are used in a more sustainable way [12][24].
An important category included in strategic sustainable development are the prevention activities carried out by individuals or groups of people in a social structure. The awareness activities related to waste prevention practices like reuse, recycling, refurbishment, and material recovery are important for the successful transition to a sustainable, environmentally acceptable development. Both domestic and industrial changes can lead to the reduction of greenhouse gas emissions and to the development of new waste treatment concepts [12][61].
The secret to waste prevention plans and to the implementation of strategies like these is social behaviour and acceptance [14]. A broad-based willingness to contribute to sustainable development is the fastest way to meet the standards and targets set by the policy makers and urban developers [18]. While the behavior regarding household waste prevention activities has been explored mostly on a qualitative rather than quantitative level, activities focusing on the reduction of waste and thoughtful use of everyday products are likely to reduce landfill waste [14][62]. It is vital for citizens to understand that waste prevention is everybody’s responsibility and taking thoughtful actions before an item becomes waste is an essential step to meet the sustainability standards [12].
Actions like these are presented in Table 13 where the available categories to assess any prevention activities are introduced, e.g., food waste reduction or participation in home composting, participation in web-platforms related with waste management in household level, etc. [13].
Table 13. Prevention activities.
Categories |
Use of leftovers |
Use of reusable Grocery Bags |
Reusable Coffee Cup Home Composting |
Food Waste Campaign |
Donations where possible (i.e., Toys,Books,clothes etc) |
Book exchanges |
Smart shopping list (buying exact necessities from stores) |
Keeping vegetables and fruits in loosely tied bags |
Reuse of electrical appliances |
Electrical Appliances repair stores to extend life time of devices |
Once we had identified and selected critical KPIs (Section 3), we proceeded to design and develop an interactive Waste Management The main ool suitable for education and informing policy. In its current form, the tool comprises a main menu (Figure 6) and a main scene is the i(Figure 7). The main menu enables users to transition to main playable scene or alternatively allows the user to showcase the credits or exit the game.
The main scene is tehe interactive core of this application. It features an imaginary virtual city with population of 100,000 people that is comprised of nine areas laid out in a 3 × 3 matrix (Figure 7). Each area has unique and distinct parameters that may be randomly defined or tuned related to waste generation and management. When the main scene is loaded, the player camera moves from a close-up view to a top-down perspective to allow an overview of the entire city in a single window. From this top-down view, players are able to select and engage with the various interactive areas and elements of the city.
Upon loading the main scene, each area is automatically assigned with a random population number out of specific options. These options are 1500, 2000, 5000, 6500, 7000, 10,000, 18,000, 20,000, and 30,000 to sum to 100,000. The total population of 100,000 people helps to simplify calculations for the user. The graphics and the building models including houses do not reflect the numbers of the area population assigned but are representative and increase user engagement and relatability. In Figure 7, we see that the population of Area11 was automatically set to 2000 people by the tool. The rest areas were assigned with each area having the value of one of the remaining choices from the options list.
Figure 6. The Waste Management Tool’s main menu allows players to start the simulator, view the credits, or exit the game.
Figure 7. The Main Scene features a top-down view of the city, divided into nine parts. Each part can be highlighted, selected, and clicked to view information about waste management KPIs and policies in that region.
Having selected a specific area of the virtual city, the users may press the “Indicators” button on the right side of their screen. After doing so, a panel with the indicators (Figure 8) for the selected area appears. These indicators are the same KPIs that we have identified and presented in Section 3.
Figure 8. Key performance indicators for each region are shown on a dashboard to provide a high-level, easily interperable overview of waste management performance.
In this panel, the KPIs present new buttons that users can interact with. For illustrative purposes, we will explain how the first two indicators work. Starting with the Waste Compositional Analysis (MSW-C), this KPI is comprised of multiple configurable values each as described in Section 3.2.1. Using the amounts measured at Municipality of Paralimni and scaling up from 18,601 to 100,000 people for our simulator, we created Table 15 to display possible ranges in these categories for internal design purposes only. These amounts are scaled to fit each population option for all areas. The final bounds for each population option are presented in Table 16. These values are stored to an external and accessible file enabling easy customization in the case of new research developments necessitating specific game permutations.
Table 215. Waste Compositional Analysis categories for a population of 100,000 people and possible range in tn for each of the categories (figures per [1113]). This table is used only for designing purposes and its amounts were later scaled to express the upper and lower bounds of each of the area population options.
Categories of Waste |
Scaled Est. Amount (tn) |
Range (tn) |
PMD |
7639 |
5000–10,000 |
Plastic Film |
3588 |
2000–5000 |
Plastics Non-Recyclable |
1835 |
1000–3000 |
Aluminium/Ferrous |
682 |
500–1000 |
Paper |
8572 |
6000–10,000 |
Similar to the area populations, the tool automatically loads the lower and upper bounds for the relevant population number. At the same time, it randomly sets a new value in the respective sliders for each category, creating a unique but broadly-similar city waste footprint for each user. A representative example for Area11 is showcased in Figure 9. Users may then choose to change these values.
Figure 9. Each area’s waste generation and policy parameters can be altered independently.
TNext, we have the Municipal Solid Waste Production KPI (MSW-P). This KPI does not have any user-configurable categories and is completely independent of MSW-C. This value comes from the division of the total amount of waste divided by the population of the area, as shown in Equation (4).
Based on the tool’s randomly-generated amounts (Figure 9) and the population of Area11, (2000), we have the following:
TAs we notice in Figure 10, the result is the same as the calculated one in Equation (15). This result can change in real time when a slider value from MSW-C panel is also changed.
Figure 10. Clicking each metric provides information about how it is calculated, which helps students learn to create effective management policies. These indicators reflect the parameters as identified in Section 3 (note that due to regional differences, the figure shows a comma rather than a period in the numeric text).
These examples are representative of how all models involved in the computation of waste production and management are handled in the game design.
Using these indicators, along with configurable elements thereof, allows individuals to use the game as a means of modelling waste generation and management. Through study and play, users may learn those metrics most affecting waste production and mitigation in order to inform effective policies for diverse scenarios.
With the game created and reflecting the model developed in Section 3, this tool will be used to enable a range of academic studies that will be the subject of future work. Ongoing work will conduct playtesting with diverse constituents, the feedback from which will be fed into a version of the game to be made freely available to researchers (please contact the authors for additional information).
Waste management is a critical and growing challenge, particularly in urban environments. Observational data are some of the best ways to study waste management to devise effective policy and to raise individual awareness that may curb waste production. Existing tools are either oversimplified or too complex for individuals to pick up and play, so we developed a game meeting the opportunity of joining a robust multi-factor waste generation and management model with ease of use and clear, rapid feedback to users. In this educationally-focused tool [64][65][66], students and policymakers may engage with the waste chain of a virtual city, changing model parameters and observing their affect on waste management performance through the use of visible key performance indicators. The game itself is built upon a robustly-defined multi-criteria decision-making problem comprising multiple variables.