Municipal Waste Management in Polish Cities—Is It Really Smart?
Abstract
:1. Introduction
- How much waste is there, and at what rate do smart city residents generate it?
- How much of the municipal waste generated is segregated?
- How much does it cost to collect and process municipal waste?
- Confronting the theoretical assumptions of the SC concept of waste sustainability with the reality of smart cities;
- Complementing the ecological stream of SC considerations with research conclusions on development trends in the size and efficiency of municipal management in smart cities;
- Subjective expansion of previous analyses related to municipal management in SC to include cities operating in developing economies;
- Creating a methodological framework for assessing the quality of urban life in the context of municipal management that takes into account the basic criteria for such assessment and their changes over time;
- Verifying the arguments cited by the critical school of thought on smart cities regarding their consumerism and work against sustainability.
2. Literature Overview
2.1. Smart City Concept and Areas of Smart City Analysis
- Seniors, finding it harder to adopt modern technological solutions [41];
- People with disabilities, with limited ability to use universal smart city solutions [42];
- Less affluent residents who cannot afford to purchase and/or pay for devices and/or services typical of smart cities [43];
- Less developed areas lying outside cities (towns, villages), which cannot offer such attractive living conditions as Smart Cities [44];
- Cities in underdeveloped, emerging and developing economies that face a lack of resources for urban infrastructure development.
2.2. Dimensions of Defining Smart Cities
- (1)
- (2)
- (3)
- Smart mobility: involving the movement of people and goods in a safe, fast, efficient, hassle-free and environmentally friendly manner [62];
- (4)
- (5)
- Smart governance: offering high quality public services, attractive development strategies, public efficiency and public participation;
- (6)
2.3. Waste Management in Smart Cities in Light of Past Research and Experience
3. Materials and Methods
3.1. Research Intentions, Data, and Methods
- The lack of studies on evaluating the effectiveness of urban waste management, while it is the basic behavior of residents in terms of sustainable consumption and the choices and decisions of municipal authorities that determine the final outcome of waste management;
- Lack of analysis showing the level and variation in cost-effectiveness of municipal waste collection;
- Lack of dynamic statistical analysis illustrating trends and changes in urban garbage generation to assess the actual greenness and sustainability of smart city infrastructure;
- The need to conduct holistic, empirical research on urban waste management issues;
- The need to analyze waste management in emerging and developing economies, which have received far less attention in the literature than the best practices in this area that illustrate the functioning of smart cities in developed countries.
- (a)
- The volume of municipal waste generated by one resident, expressed in kg per year:
- (b)
- The average annual rate of change in the volume of waste in the city expressed as %:
- (c)
- Share of mixed waste in total waste expressed in % and illustrating the scale of garbage segregation in the city:
- (d)
- Cost-to-effectiveness ratio calculated as the ratio of the cost of operation of the municipal waste collection system (including the costs of collection, transportation, gathering, recovery and disposal of municipal waste, establishment and maintenance of selective municipal waste collection points and administrative service of the system) per 1 ton of collected waste expressed in PLN/ton:
- The volume of waste per capita in 2021 in kg (destimulant)—the more waste 1 inhabitant produces, the lower the effectiveness of waste management in the context of sustainable consumption and development;
- Average annual rate of change in waste volume per capita in % (destimulant)—the higher the rate of increase in waste volume per capita, the less effective is waste management from the point of view of environmental awareness of the urban community;
- Average share of mixed waste in total waste in % (destimulant)—the higher the share of mixed waste in total waste, the lower the effectiveness of waste management in the context of circular economy and waste recycling;
- Cost efficiency in 2021 in PLN/ton (destimulant)—the higher the cost of waste collection, the lower the efficiency of the public sphere (a parameter important for assessing the economy of the city government);
- Change in cost efficiency relative to 2019 in % (destimulant)—the faster the rate of deterioration of cost efficiency, the worse the city government’s efficiency in waste management.
3.2. Research Sample Characteristics
4. Results
4.1. Quantitative and Efficiency Analysis of Municipal Waste Generation
- The degree of concentration of development (the more dispersed it is, the higher the cost);
- The structure of occupied properties (costs higher for single-family than multi-family developments).
- The structure of occupied properties (the costs are higher for single-family than multi-family developments);
- The structure of the inhabited property (the younger the population the more waste it generates);
- The cost of selective collection and collection of municipal waste (the more fractions of selectively collected waste, the higher the cost of waste management and disposal).
4.2. Results of the Application of Multi-Criteria Analysis in the Evaluation of the Efficiency of the Municipal Management of the Analyzed Cities
5. Discussion
- Monitoring of municipal waste levels over time and space;
- Focusing attention on practice and theory, not only on the problem of waste collection in smart cities but also on aspects of preventing waste growth and related to segregation and recycling [87];
- Conducting benchmarking on the cost-effectiveness of waste management (studies show that some cities are able to achieve very low levels of waste management fees) aimed at reducing costs;
- Educating residents about sustainable consumption and greening their purchases, as well as reducing food waste;
- Using a holistic (rather than piecemeal) approach to the waste management process that takes into account both residents as a trash generator and the recyclability of the waste generated;
- Considering monetary penalties for non-ecological behavior and habits.
6. Conclusions
- The amount of waste per capita is increasing in most (11 out of 16) of the surveyed cities, with per capita levels in smart cities being high and growing rapidly over time;
- The average share of mixed waste in total waste is 63.92%, but most (10 out of 16) of the surveyed cities are systematically reducing it; in Warsaw and Wrocław (smart cities according to the Cities in Motion Index 2020) the indicated share is above average and shows no clear downward trend;
- The cost-effectiveness of total collected municipal waste services varies widely and increases significantly over time (the average increase in 2021 compared to 2019 was more than 48%), which illustrates both the increase in input prices and the monopolistic power of municipal waste collection companies;
- In a holistic assessment of waste management effectiveness, the best performing cities were less urbanized and industrialized, i.e., Łódź, Rzeszów and Białystok, and the worst were Lublin and Warsaw and Wrocław, cities recognized as smart in the Cities in Motion Index 2019, suggesting that they have problems at the basic level of municipal waste management.
- Filling the research gap in the area of holistic and dynamic assessment of the effectiveness of waste management in smart and aspiring cities;
- Supplementing previous research with an analysis of the cost-effectiveness of urban waste management;
- Locating the research in the socio-ecological area of the SC concept—less frequently exposed in the literature;
- Analysis of the determinants of waste management in developing economies.
- Verifying the thesis of green and effective waste management in smart cities;
- Providing knowledge about the process of waste collection in cities and the scale of waste segregation;
- Conducting a comparative analysis of 16 Polish cities in waste management providing a basis for benchmarking in this regard;
- Formulating recommendations for improving waste management in cities.
Funding
Data Availability Statement
Conflicts of Interest
References
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City | Inhabitants | Surface | Population Density |
---|---|---|---|
Białystok | 296,000 | 102 km2 | 2902 persons/km² |
Gorzów Wlk. | 120,087 | 86 km2 | 1400 persons/km² |
Gdańsk | 471,000 | 263 km2 | 1787 persons/km² |
Katowice | 292,000 | 165 km2 | 1756 persons/km² |
Kielce | 192,500 | 110 km2 | 1686 persons/km² |
Kraków | 782,000 | 327 km2 | 2450 persons/km² |
Lublin | 338,000 | 147 km2 | 2270 persons/km² |
Łódź | 670,642 | 293 km2 | 2287 persons/km² |
Olsztyn | 170,622 | 83 km2 | 1932 persons/km² |
Opole | 127,839 | 149 km2 | 858 persons/km² |
Poznań | 532,000 | 262 km2 | 2031 persons/km² |
Rzeszów | 198,609 | 129 km2 | 1539 persons/km² |
Szczecin | 396,472 | 301 km2 | 1319 persons/km² |
Toruń | 197,812 | 116 km2 | 1511 persons/km² |
Warsaw | 517,000 | 517 km2 | 3466 persons/km² |
Wrocław | 643,000 | 293 km2 | 2298 persons/km² |
Cities | Years | |||
---|---|---|---|---|
2019 | 2020 | 2021 | Average Rate of Changes [%] | |
Białystok | 344.8 | 365.8 | 367.8 | 3.29% |
Gdańsk | 423.3 | 350.0 | 434.9 | 1.36% |
Gorzów Wlk. | 379.4 | 407.4 | 381.0 | 0.21% |
Katowice | 440.6 | 472.8 | 436.7 | −0.44% |
Kielce | 353.3 | 351.0 | 388.1 | 4.81% |
Kraków | 430.9 | 451.3 | 464.0 | 3.77% |
Lublin | 377.0 | 385.0 | 405.0 | 3.69% |
Łódź | 437.6 | 389.9 | 395.0 | −4.99% |
Olsztyn | 392.5 | 370.9 | 362.9 | −3.85% |
Opole | 418.9 | 430.6 | 449.3 | 3.56% |
Poznań | 400.1 | 392.1 | 416.6 | 2.04% |
Rzeszów | 450.2 | 422.8 | 421.2 | −3.27% |
Szczecin | 419.1 | 392,4 | 414.9 | −0.50% |
Toruń | 388.0 | 405.4 | 391.9 | 0.51% |
Warsaw | 374.9 | 394.4 | 414.9 | 5.20% |
Wrocław | 545.8 | 481.5 | 570.9 | 2.27% |
Arithmetic mean | 411.0 | 404.0 | 419.7 | 1.10% |
Coefficient of variation | 11.6% | 9.7% | 11.7% | 281.0% |
Cities | Years | |||
---|---|---|---|---|
2019 | 2020 | 2021 | Trend | |
Białystok | 53.37% | 50.82% | 53.70% | increase/decrease |
Gdańsk | 63.48% | 46.49% | 54.56% | increase/decrease |
Gorzów Wlk. | 75.36% | 65.95% | 63.52% | falling |
Katowice | 72.08% | 66.67% | 69.11% | increase/decrease |
Kielce | 73.57% | 68.86% | 65.42% | falling |
Kraków | 65.98% | 54.75% | 53.02% | falling |
Lublin | 60.45% | 56.59% | 55.33% | falling |
Łódź | 65.57% | 62.55% | 61.24% | falling |
Olsztyn | 76.13% | 71.56% | 68.61% | falling |
Opole | 62.25% | 58.85% | 55.13% | falling |
Poznań | 67.30% | 64.45% | 60.25% | falling |
Rzeszów | 69.75% | 51.30% | 51.80% | increase/decrease |
Szczecin | 74.76% | 70.46% | 67.82% | falling |
Toruń | 76.58% | 69.88% | 66.83% | falling |
Warsaw | 80.69% | 64.98% | 66.64% | increase/decrease |
Wrocław | 68.28% | 61.81% | 63.46% | increase/decrease |
Arithmetic mean | 69.10% | 61.62% | 61.03% | 63.92% |
Coefficient of variation | 10.35% | 12.53% | 10.17% | 10.28% |
Cities | Years | |||
---|---|---|---|---|
2019 | 2020 | 2021 | Change Compared to 2019 [in %] | |
Białystok | 515.71 | 499.16 | 672.21 | 30.35% |
Gdańsk | 590.36 | 920.94 | 759.17 | 28.59% |
Gorzów Wlk. | 503.99 | 629.50 | 715.48 | 41.96% |
Katowice | 410.16 | 489.90 | 599.68 | 46.21% |
Kielce | 454.65 | 662.43 | 615.10 | 35.29% |
Kraków | 494.79 | 637.09 | 717.15 | 44.94% |
Lublin | 539.62 | 973.26 | 1635.45 | 203.07% |
Łódź | 286.90 | 243.90 | 241.90 | −15.68% |
Olsztyn | 635.28 | 690.86 | 887.17 | 39.65% |
Opole | 479.26 | 701.74 | 748.72 | 56.22% |
Poznań | 486.39 | 1233.99 | 835.72 | 71.82% |
Rzeszów | 488.64 | 748.29 | 718.22 | 46.98% |
Szczecin | 435.36 | 717.60 | 856.38 | 96.71% |
Toruń | 275.09 | 265.61 | 383.85 | 39.54% |
Warsaw | 1220.53 | 1776.41 | 1297.17 | 6.28% |
Wrocław | 563.73 | 659.20 | 595.29 | 5.60% |
Arithmetic mean | 523.78 | 740.62 | 767.42 | 48.60% |
Coefficient of variation | 39.85% | 49.76% | 42.32% | 100.37% |
Cities | Variables | ||||
---|---|---|---|---|---|
Waste Volume per Capita in 2021 in kg (Destimulant) | Average Annual Rate of Change in Waste Volume per Capita in % (Destimulant) | Average Share of Mixed Waste in Total Waste in % (Destimulant) | Cost Effectiveness in 2021 in PLN/t (Destimulant) | Change in Cost Efficiency Compared to 2019 in % (Destimulant) | |
Białystok | 367.80 | 3.29% | 52.63% | 672.21 | 30.35% |
Gdańsk | 434.90 | 1.36% | 54.84% | 759.17 | 28.59% |
Gorzów Wlk. | 381.00 | 0.21% | 68.28% | 715.48 | 41.96% |
Katowice | 436.70 | −0.44% | 69.29% | 599.68 | 46.21% |
Kielce | 388.10 | 4.81% | 69.28% | 615.10 | 35.29% |
Kraków | 464.00 | 3.77% | 57.92% | 717.15 | 44.94% |
Lublin | 405.00 | 3.69% | 57.46% | 1635.45 | 203.07% |
Łódź | 395.00 | −4.99% | 63.12% | 241.90 | −15.68% |
Olsztyn | 362.90 | −3.85% | 72.10% | 887.17 | 39.65% |
Opole | 449.30 | 3.56% | 58.74% | 748.72 | 56.22% |
Poznań | 416.60 | 2.04% | 64.00% | 835.72 | 71.82% |
Rzeszów | 421.20 | −3.27% | 57.62% | 718.22 | 46.98% |
Szczecin | 414.90 | −0.50% | 71.02% | 856.38 | 96.71% |
Toruń | 391.90 | 0.51% | 71.10% | 383.85 | 39.54% |
Warsaw | 414.90 | 5.20% | 70.77% | 1297.17 | 6.28% |
Wrocław | 570.90 | 2.27% | 64.52% | 595.29 | 5.60% |
maximum | 570.90 | 5.20% | 72.10% | 1635.45 | 203.07% |
Minimum | 362.90 | −4.99% | 52.63% | 241.90 | −15.68% |
Range | 208.00 | 10.19% | 19.47% | 1393.55 | 218.76% |
Cities | Variables | ||||
---|---|---|---|---|---|
Waste Volume per Capita in 2021 in kg (Destimulant) | Average Annual Rate of Change in Waste Volume per Capita in % (Destimulant) | Average Share of Mixed Waste in Total Waste in % (Destimulant) | Cost Effectiveness in 2021 in PLN/t (Destimulant) | Change in Cost Efficiency Compared to 2019 in % (Destimulant) | |
Białystok | 0.9764 | 0.1874 | 1.0000 | 0.6912 | 0.7896 |
Gdańsk | 0.6538 | 0.3768 | 0.8863 | 0.6288 | 0.7976 |
Gorzów Wlk. | 0.9130 | 0.4897 | 0.1963 | 0.6602 | 0.7365 |
Katowice | 0.6452 | 0.5535 | 0.1445 | 0.7433 | 0.7171 |
Kielce | 0.8788 | 0.0383 | 0.1446 | 0.7322 | 0.7670 |
Kraków | 0.5139 | 0.1403 | 0.7283 | 0.6590 | 0.7229 |
Lublin | 0.7976 | 0.1482 | 0.7521 | 0.0000 | 0.0000 |
Łódź | 0.8457 | 1.0000 | 0.4611 | 1.0000 | 1.0000 |
Olsztyn | 1.0000 | 0.8881 | 0.0000 | 0.5370 | 0.7471 |
Opole | 0.5846 | 0.1609 | 0.6859 | 0.6363 | 0.6713 |
Poznań | 0.7418 | 0.3101 | 0.4159 | 0.5739 | 0.6000 |
Rzeszów | 0.7197 | 0.8312 | 0.7437 | 0.6582 | 0.7135 |
Szczecin | 0.7500 | 0.5594 | 0.0556 | 0.5591 | 0.4862 |
Toruń | 0.8606 | 0.4603 | 0.0515 | 0.8981 | 0.7476 |
Warsaw | 0.7500 | 0.0000 | 0.0681 | 0.2427 | 0.8996 |
Wrocław | 0.0000 | 0.2875 | 0.3894 | 0.7464 | 0.9027 |
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Jonek-Kowalska, I. Municipal Waste Management in Polish Cities—Is It Really Smart? Smart Cities 2022, 5, 1635-1654. https://doi.org/10.3390/smartcities5040083
Jonek-Kowalska I. Municipal Waste Management in Polish Cities—Is It Really Smart? Smart Cities. 2022; 5(4):1635-1654. https://doi.org/10.3390/smartcities5040083
Chicago/Turabian StyleJonek-Kowalska, Izabela. 2022. "Municipal Waste Management in Polish Cities—Is It Really Smart?" Smart Cities 5, no. 4: 1635-1654. https://doi.org/10.3390/smartcities5040083
APA StyleJonek-Kowalska, I. (2022). Municipal Waste Management in Polish Cities—Is It Really Smart? Smart Cities, 5(4), 1635-1654. https://doi.org/10.3390/smartcities5040083