Next Article in Journal
Framework for Establishing a Sustainable Medical Facility: A Case Study of Medical Tourism in Jordan
Previous Article in Journal
Lessons from Globalization and the COVID-19 Pandemic for Economic, Environmental and Social Policy
 
 
Font Type:
Arial Georgia Verdana
Font Size:
Aa Aa Aa
Line Spacing:
Column Width:
Background:
Article

Exploring the Factors Affecting the Recycling Behavior of Primary School Students

1
Department of Forestry and Management of Environment and Natural Resources, Democritus University of Thrace, 193 Pantazidou Street, 68200 Orestiada, Greece
2
2nd Elementary School of Skydra, Fintia 1, 58500 Skydra, Greece
*
Author to whom correspondence should be addressed.
Submission received: 1 June 2021 / Revised: 11 June 2021 / Accepted: 17 June 2021 / Published: 23 June 2021

Abstract

:
Education on recycling must be provided during the first school years because environmentally aware students are more likely to become environmentally aware citizens. The aim of the present study is to investigate the factors affecting the recycling behavior of students attending the last grade of primary school in the regional unit of Evros in Greece. To select the sample, multistage sampling was used, and to collect the research data, a questionnaire with closed-ended items was designed. The collected data were analyzed using descriptive statistics, the non-parametric Friedman test, and categorical regression. Our results showed that the students had positive views, attitudes, and behaviors in relation to recycling and were actively involved in it. Categorical regression analysis indicated that the other family members affected students’ recycling behavior to a high degree, whereas students’ parents’ occupation and students’ participation in environmental education programs at school exerted a lower influence on their recycling behavior.

1. Introduction

Our planet faces severe environmental problems which tend to aggravate and lead to catastrophic consequences. Environmental problems are global and concern all people regardless of how they affect each person. Population increase, urbanization, modern lifestyle, consumerism, and economic development reduced natural resources and created the problem of waste management. In relation to the latter, the development of societies increased the volume of waste so that waste management is now a serious issue in every country [1]. Consequently, increased population together with the rising quantities of municipal solid waste resulted in persistent calls for recycling [2]. Sending waste to landfills or incineration poses severe risks to the environment and public health. Municipal governments across the globe stand at the forefront of political innovation, which aims to increase the rate of recycling and to reduce the rate of waste that ends up in landfills [2].
In a time when the lack of natural resources is more concerning than ever, recycling consists of both an environmental and a social need. Recycling is a factor that reduces the volume of waste that end up in landfills every year [3]. It also contributes to the conservation of natural resources and the space where waste is disposed while preventing the risk of pollution due to leakages in landfills and incinerator emissions [4].
All citizens including adults, adolescents, and children can play an important role and contribute to a cleaner planet [3]. As basic pillars of our society, children are not only the citizens of tomorrow but also those who will shape the future [5]. Children should thus develop positive environmental attitudes and behaviors as well as an eco-conscious attitude towards issues such as recycling. At the same time, they should gain a profound understanding of the importance of the natural environment not only for humans but also for all creatures of nature [6].
Environmental education may contribute in this direction because children are mainly those who receive it. Environmental education is described as one of the most appropriate ways to ensure a healthy environment in the future and to create citizens who are actively involved in environmental issues [7]. Environmental education aims to raise students’ awareness about the environment and to foster positive attitudes and behaviors towards environmental problems [8]. Therefore, education can provide to students information on proper waste management [9] as well as affect individuals’ behaviors, encouraging an environmentally friendly lifestyle [4].
The aim of the present study is to investigate the views and the attitudes of primary school students in the Prefecture of Evros in Greece towards recycling. Moreover, it seeks to detect the factors affecting the practice of recycling. It is important that policymakers promote recycling as a social trend and provide adequate public facilities so that citizens can participate in recycling activities without difficulties [10].

2. Theoretical Background

Waste management is a severe issue in today’s consumer society because the volume of waste ending up in landfills follows a rapidly rising trend. Recycling is one of the most sustainable and effective methods to tackle this issue and to mitigate the relevant environmental effects [11]. Recycling mitigates the need for landfills, lowers emissions, and protects the earth’s natural resources. Beside these advantages, it offers economic benefits such as new jobs while saving the energy which would be required for creating new products from raw materials. Recycling, however, can also be beneficial for human society and psychology since it can shape positive environmental attitudes and behaviors and reinforces social participation [12].
Even though recycling programs are a positive step, it is crucial to change individuals’ attitudes and behaviors. In this way, the volume of waste ending up in landfills can be reduced significantly [11]. To that end, steps must be taken in order to ensure that today’s children contribute to the solution of environmental problems. Children should therefore be equipped with the necessary knowledge and develop positive attitudes and behaviors in relation to recycling and other environmental issues [13].
If the main goal is to exert efforts that lead to recycling behaviors, it is necessary to pay more attention to students’ attitudes, behaviors, and awareness about recycling [3]. These are affected by various factors which can be categorized into the following: exogenous motives, endogenous motives, external factors, internal comfort factors, and demographic variables [14].
Exogenous motives involve money rewards and social influence. It was observed that, once money rewards seize, so do recycling behaviors [14]. Hence, rewards can lead to notable recycling behaviors; however, they are temporary. Schultz et al. [15] found that the provision of rewards aimed at eliciting recycling behaviors is more effective when individuals have low environmental concerns. However, the behavior of individuals with high environmental concerns is not affected by rewards, because their recycling behavior is driven by endogenous motives.
Social influence refers to the influence that individuals receive from their family, friends, and neighbors [14]. Interestingly, it plays a significant role in students’ awareness about recycling as well as their recycling behavior [3,11,16,17]. For instance, students whose families do not recycle are indifferent to recycling as they are not encouraged or guided by their families to perform recycling [12,18,19]. Conversely, individuals whose families or friends approve of recycling shape more positive attitudes towards recycling [20,21].
Endogenous motives involve individuals’ satisfaction with participating in actions which benefit society as well as satisfaction with avoiding waste and maintaining natural resources [14]. Along the same line of thought, it was observed that individuals are more motivated to take action when they perceive that recycling leads to desirable outcomes and benefits society [22,23]. In other words, endogenous motives act as factors that prompt individuals to adopt positive recycling behaviors and attitudes. Moreover, they are more likely to be willing to recycle if they perceive recycling as a moral and personal obligation [12,24,25,26] or if they feel that the society values their effort to recycle [12].
In many cases, it is not sufficient to provide recycling motives, as some barriers inhibit recycling. Such barriers involve exogenous comfort factors such as time constraints, space, money, and personal effort [14]. Citizens often perceive that preparing, storing, and carrying recyclable materials requires time, space, money, and personal effort [14,19]. As a result, they regard recycling as a tiring and time-consuming process, which makes them unwilling to recycle [25]. McCarty and Shrum [27] indicated that the inconvenience associated with recycling exerts greater influence on individuals’ behaviors than their beliefs in the importance of recycling. The location of recycling bins is another important factor, as previous research works showed that the amount of recyclable materials is reduced when recycling bins are located in a location which is inconvenient; however, the amount of recyclables is greater if recycling bins are located in more convenient locations [3,28].
Likewise, the lack of recycling bins is a major factor that contributes to students’ reluctance to recycle [18,19,29]. That being said, the installation of recycling bins in convenient locations alone does not suffice to induce recycling. Recycling bins need also to display some information on the proper recycling of packages, which, as shown by Mrema [3], is required by students. Such difficulties can be overcome through environmental awareness, as individuals with pronounced environmental awareness tend to be more committed to recycling [30].
Internal comfort factors including knowledge about recycling programs have a positive effect on recycling attitudes. What prevents recycling is consumers’ lack of knowledge about the importance of recycling and proper ways of recycling; another preventing factor is the perception that recycling is a time-consuming process [14]. In the case of students, the study of Mrema [3] showed that students do not recycle because they do not always know which packages can be recycled, while the study of Bao [31] indicated that students refrain from recycling when they are unaware of the destination of recyclables or the consequences of not recycling. Therefore, students must be knowledgeable about the proper way of recycling and its importance in order to commit to recycling and have awareness about it. Students can have access to such information through posters, leaflets, comics, and animation [3].
Demographic variables were also found to affect students’ recycling behavior and attitudes. These variables may point to the proper techniques which contribute to recycling behaviors [32]. More specifically, female students use recycling bins more often and have more favorable recycling attitudes in comparison to male students [3,29,33,34,35]. Age is another influential factor that shapes recycling attitudes and behaviors, with younger students exhibiting a more positive attitude toward recycling compared to older ones [36].
A more careful analysis of the above factors affecting recycling enables us to conclude that the strongest predictive recycling factors are internal motives. These involve knowledge and awareness about recycling as well as knowledge about recycling programs. Social influence which stems from family, friends, and neighbors can also predict recycling behavior in contrast to financial motives which predict it to a much lower degree. In addition, internal satisfaction with recycling is closely linked to behavior prediction. Individuals who perceive that their actions are impactful and can contribute to the solution of environmental issues are more likely to recycle compared to individuals who regard that their actions have no impact [14].
Moreover, students’ attitudes towards recycling consisted of the topic of many environmental education programs [37]. Beside these programs, subjective and perceived control of behavior exerts a great influence on behavior predictors [7,38]. The development of environmentally aware youngsters is very important, as it can secure a sustainable future [37]. Changes in attitudes can lead to behavioral changes, however, education is not enough to improve or change attitudes. What also matters is the reliability of information sources as well as the way the relevant information is received. It thus becomes apparent that individuals who receive knowledge can change attitudes, whereas behavior changes depend on psychological factors stemming from a complex society system [39]. It is also worthwhile to note that attitudes are not always a reliable behavior predictor, as studies showed that various factors determine the attitude–behavior relationship [40].
The examination of recycling attitudes is without a doubt a crucial step in the effort to create a sustainable society. However, it is equally important to examine potential solutions for wastes recycling. To that end, researchers focused efforts on processes which can contribute to the solution of waste recycling. In specific, porous materials could be synthesized using wastes, and such processes could result in a high degree of recycling. Indicatively, Miricioiu and Niculescu [41] stressed the need to examine the properties of fly ash and analyze it as a possible raw material in order to obtain materials. Pyrolysis, a thermo-chemical treatment, is another interesting method. This treatment may be applied to every organic (that is, carbon-based) product. It may be applied both to pure products but also mixtures. In this process, the material is exposed to very high temperatures in the absence of oxygen. As a result, the material undergoes chemical and physical separation into different molecules [42,43]. This process enables us to obtain products with a different but more superior character than the initial residue. Consequently, pyrolysis is becoming a more significant process for industry because it can give much higher value to common materials and waste. Pyrolysis is widely applied to turn organic materials into liquid, gas, and solid residues [42,43]. Hence, processes such as the ones mentioned above not only reduce the volume of waste but also produce new products, thereby opening the way for a sustainable society with low environmental impact.

3. Materials and Methods

3.1. Study Area

The area of study was the geographical region in which the primary schools of the Prefecture of Evros are located. The Prefecture of Evros along with the Prefectures of Rhodopi, Xanthi, Drama, and Kavala constitute the region of Eastern Macedonia and Thrace—the northernmost administrative unit of Greece. In terms of geographical size, the Prefecture of Evros is the largest prefecture in Thrace that shares borders with Turkey and Bulgaria. The Prefecture of Evros involves the municipalities of Orestiada, Didymoteicho, and Alexandroupolis. In the continental part of the prefecture, there are 64 primary schools without estimating special education schools or schools with zero functionality. Specifically, there are 14 schools in the municipality of Orestiada, eight in the municipality of Didymoteicho, 13 in the municipality of Soufli, and 29 in the municipality of Alexandroupoli.

3.2. Data Collection

In order to achieve the aim of the study, a structured questionnaire was designed after the relevant literature was reviewed. Specifically, the literature on recycling published in national and international scientific journals and scholar works was examined. A structured questionnaire was considered the most appropriate research instrument because it can collect a large volume of information from respondents with different characteristics. Moreover, data collected through questionnaires can be analyzed quickly and easily.

3.3. Questionnaire Design

The questionnaire was designed based on relevant research works [3,25,35,44,45,46]. Then, the questionnaire was pilot tested in order to examine its accuracy. Based on the results of the pilot test, the questionnaire was revised slightly, leading to the final version of the questionnaire.
An introductory note on the top of the first page served to provide necessary information about the study. Here, it was stated that the survey was explicitly conducted by the Democritus University of Thrace and, more specifically, by the Department of Forestry and Management of the Environment and Natural Resources. This clarification served to avoid possible misconceptions or doubts. For the same reason, the name and the contact details of the professor who is responsible for the survey were provided. The introductory note concluded by stating the objective of the survey and guaranteeing anonymity and confidentiality to the participants.
The questionnaire included 24 items and was four pages long. All questions were closed-ended and offered respondents a list of possible pre-defined answers to choose from. It took approximately 15 min to complete the questionnaire. The items were formulated to be understandable by students attending the last grade of primary school. The items collected information on respondents’ demographics, perceptions, knowledge, habits, and behavior regarding recycling and the environment.

3.4. Sampling

As already mentioned, the continental part of the Prefecture of Evros, which involves five municipalities, was chosen as the study site. A multistage sampling technique was used for this study. In the first stage, the participation of all municipalities in the study was decided, and, in the second stage, a random sample of schools in each municipality was selected. A sample of 17 schools was selected according to the multistage sampling technique. Next, with the method of census, all students attending the last grade of primary school were censused. According to this census, the sample comprised 402 students who attended the last grade in the primary schools in the Prefecture of Evros. Questionnaires were administered to students with the consent of each school’s headmaster, class teacher, and parents. Questionnaires were completed from September 2020 to October 2020.

3.5. Data Analysis

To analyze the collected data, descriptive statistics, the non-parametric Friedman test, and categorical regression were performed. The non-parametric Friedman test compares the values of three or more correlated groups of variables. The distribution of the Friedman test is Chi-square distribution with degrees of freedom (df) df = k − 1, where k is the number of teams or samples. This test classifies the values of variables for every subject separately and calculates the mean rank of classification values for each variable [47]. Categorical regression is an extension of the principles of classical linear regression and logarithmic analysis. Through scaling, it assigns values to each category of variables in such a way that they are optimum in terms of regression and reflect the characteristics of the original variables. Categorical regression scales nominal, ordinal, and numerical variables in an optimum manner, quantifying their categories so that the squared correlation between the quantified dependent variable and the linear combination of the quantified independent variables is maximized. The interpretations are related to the transformed variables, but they are also related to the original variables due to the relation that exists between the original variables and the transformed ones [48].

4. Results

First, results regarding respondents’ demographic characteristics and their participation in environmental education programs are presented. Then, students’ and students’ parents’ views and attitudes towards environmental issues as well as their recycling behavior are described. Finally, results are presented in two main categories; that is, students were divided into students who recycle and students who do not recycle. This segmentation is used in the following items to detect how students’ responses differentiate according to their statement on recycling.

4.1. Demographic Characteristics

Students were asked whether they recycled. Of students who reported recycling, male students outnumbered slightly their female peers. However, the percentage of male students was higher (by 54.5%) in the group of students who reported not recycling (Table 1).
Students’ family background was examined. As it can be seen in Table 2, most parents of students who recycle, whose students reported recycling, were employees. More specifically, 54.8% of fathers were public employees and 18.2% were private employees, while 36% of mothers were public employees and 19.6% were private employees. Moreover, an appreciable share of parents was freelancers: 14.3% of fathers and 13.1% of mothers. In addition, 9.5% of fathers were farmers, 16.1% of mothers were housewives, and 12.2% of mothers were unemployed. A similar distribution of parental occupations was observed in the group of students who do not recycle. In particular, 60.6% of students’ fathers were employees with 53% being employed in the public sector and 7.6% being employed in the private sector. In addition, 42.4% of students’ mothers were employees (22.7% were private employees and 19.7% were private employees). Moreover, 21.2% of students’ fathers and 22.7% of students’ mothers were freelancers. Finally, 13.6% of fathers were farmers and 19.7% of mothers were housewives (Table 2).
In the group of students who reported recycling, it can be seen that the parents had a high education level, as 43.6% of fathers and 55.6% of mothers were degree qualified (Table 3). In addition, the percentage of parents who were high school graduates was significant, with fathers accounting for 49.4% and mothers 39.3%. Only few parents were primary school and middle school graduates.
In comparison to the parents of students who recycle, the parents of students who do not recycle had a lower education level. Specifically, 53.1% of fathers and 48.5% of mothers were high school graduates, while substantial shares of parents were university or tertiary education graduates. Finally, as few as 10.6% of fathers and 3% of mothers were primary school graduates (Table 3).

4.2. Environmental Behavior

Students were then asked how often they recycle. As Figure 1 shows, 83.6% of students recycle often and very often whereas only 16.4% reported recycling rarely or never.
Students were also asked how often their families recycle. In Figure 2, it can be seen that, in the group of students who recycle, 95.3% of respondents stated that their family recycles often or very often. Only 4.5% stated that their families recycled seldom and 0.3% not at all. In the group of students who do not recycle, 57.6% stated that their families rarely recycled, 34.9% stated that their families recycled often or very often, and 7.6% stated that their families never recycled.

4.3. Students’ Participation in Environmental Education Programs

Then, students were asked whether they attended any environmental education programs and, as shown in Figure 3, the majority of students had done so, while the percentage of those who reported having attended such programs was higher by nine percentage units for students who recycle compared to students who do not recycle.
Students were asked also whether they attended an environmental education program focused explicitly on recycling. According to Figure 4, students who attended such programs recycle more often than the students who did not attend them.

4.4. Students’ Views on the Environment

Respondents were asked to what degree they agreed that waste creates environmental and health issues. Both groups of students who reported recycling and not recycling perceived that waste creates problems in the natural environment and in human health (Figure 5).
Then, respondents were asked whether they agreed that recycling contributes to the solution of environmental issues. As it can be seen in Figure 6, students in both groups perceived that recycling helps tackle environmental problems. Only 0.9% and 0.6% of each group thought that recycling makes a minor or no contribution to such issues.
Students’ opinions on whether students should receive more information on recycling were then examined. In the group of students who recycle, 89.3% perceived that students have to be informed to a higher degree about recycling. As few as 1.8% did not regard the provision of more information as important (Figure 7).
In the group of students who do not recycle, 78.8% perceived that more recycling-related information is required. In addition, 16.7% seemed to be somewhat confused about this matter, as they neither agreed nor disagreed. Finally, only 4.5% regarded that more information on recycling should not be provided (Figure 7).

4.5. Environmental Attitudes

The non-parametric Friedman test was applied in order to detect any statistical differences among the daily practices of both student groups (those who recycle and those who do not recycle) (Table 4). For the students who recycle, switching off air-conditioners when leaving the house was the practice that ranked first (with a mean rank of 9.27). This was followed by the practice of turning off the water tap while brushing teeth (mean rank 8.89). The lowest ranked practices were keeping the windows closed on hot summer days (4.99), using pressure cookers at home (4.94), and avoiding drying clothes on heaters (mean rank 3.75).
Almost the same results were recorded for the group of students who do not recycle. As shown in Table 4, switching off air-conditioner when leaving the house was the highest ranked daily practice (mean rank 9.04) followed by turning off the tap while brushing teeth (mean rank 8.64). As with the previous group, the lowest ranked daily practices were using pressure cookers (mean rank 4.83) and avoiding drying clothes on heaters (mean rank 4.17).

4.6. Factors Affecting Students’ Recycling Behavior

Categorical regression was performed in order to investigate the factors that affect students’ recycling behavior. In this analysis, “Performing recycling” was the dependent variable, and the variables explaining better the research objectives were used as the independent variables. The application of the test on some categorical regression models showed a multicollinearity problem in Pratt’s relative importance measures and tolerance measures. More specifically, some independent variables presented high correlation, high negative coefficient values in Pratt’s relative importance index, and low tolerance values. Since these independent variables made the model unstable, it was necessary to remove them. The removal of these variables was performed by taking into account the value of the F-statistic, as this determines if the removal of an independent variable with the inclusion of the others reduces the predictive abilities of the model. It is also worthwhile to note that these independent variables were not removed simultaneously, but each time only one independent variable was removed based on the value of the F-statistic. Many tests were performed, however, here, we present only the most significant Pratt’s relative importance coefficients, β standardized coefficients, transformation diagrams, and relevant descriptions. Finally, all these analyses showed that the following independent variables account for students’ recycling behavior the best.
The analysis with these variables gave a coefficient of multiple determination R2 = 0.484 as well as F = 14.081, which is statistically important. The standardized regression coefficients (Betas) of the independent variables showed that “Performing recycling” was mostly affected by the following variables: “Participation in environmental education programs focusing on recycling”, “Participation in environmental education programs”, “Desire for more information related to recycling”, “Students’ mother’s occupation”. In addition, the F value of each independent variable indicated that the removal of variables with high F value made the model weak. However, the removal of the variable “Students’ fathers’ occupation” had a negligible effect on the predictive ability of the model. Moreover, the relative importance measures of the independent variables denote that the variables “The other members of students’ family perform recycling” (85.3%) followed by “Participation in environmental education programs focusing on recycling” (5.8%) made the greatest contribution to the dependent variable (Table 5). Variables’ transformation plots (Figure 8) combined with the signs of the standardized coefficient enabled us to infer that:
  • The more the members of students’ family recycle, the more the students themselves recycle;
  • Students who attended environmental education programs focusing on recycling recycle more that students who attended other kinds of environmental education programs.

5. Discussion

The present study sought to examine the views and the attitudes towards recycling among students attending the last grade of primary school. The main findings revealed students’ participation in recycling and their positive views and attitudes towards recycling while highlighting the crucial role of family in students’ recycling behavior.
In this study, the respondents reported recycling on a frequent basis. This finding correlates with the study of Embong et al. [49] who indicated that students recycle on a weekly and monthly basis. However, Kalaitzoglou [29] and Sobri and Rahman [19] found that students’ participation in recycling is moderate, and Naquin et al. [50] indicated that the number of students who recycle regularly is minor. The different levels of recycling may be attributed to students’ age; that is, the respondents in this study were primary school students, whereas the respondents in the study of Kalaitzoglou [29] were middle school students. Age can be greatly influential when it comes to recycling, as primary school students were found to express a higher willingness to recycle in comparison to middle school students [50].
Regarding students’ recycling behavior, it was shown that family is a rather important factor. This is in line with the findings of Clay [11], Long et al. [16], Mrema [3], and Schwab et al. [17] who detected that the influence of family on recycling matters can raise students’ awareness about recycling and instigate recycling behaviors. Therefore, students perform recycling when their family does so as well. This conclusion can be supported by the studies of Matthies et al. [20] and Seacat and Northrup [21], who indicated that students shape favorable attitudes towards recycling when their family supports recycling. Conversely, students who rarely or never recycle belong to families who did not adopt recycling behaviors in their daily lives [12,18,19].
The effect of demographic variables on recycling behaviors is another worthwhile point to discuss. Gender presented no discernible effect on recycling, as male students outnumbered only slightly their female counterparts in the group of students who recycle and in the group of students who rarely or never recycle. This resonates with Eagles and Demare [51] and Yilmaz et al. [52], who found that gender does not differentiate the environmental attitudes and behaviors of primary school students. That being said, the studies of Mrema [3], Ugulu [34], Kalaitzoglou [29], and Psarra [35] concluded that female students participate more actively in recycling compared to their male peers.
The occupation of students’ parents was another interesting variable and, specifically, it was shown that most parents of students who recycle or rarely/never recycle were either employed in the public or the private sector. Significantly fewer parents were freelancers and farmers. Hence, it seems that the occupation of students’ parents does not play a significant role in students’ recycling attitude and behavior. This, however, does not resonate with the study of Malandrakis and Chatzakis [53], who indicated an important effect of parental occupation on their children’s attitudes and behaviors. In addition, this study found that students’ parents who recycle are more educated compared to those parents whose children are not committed to recycling.
It was also remarkable that students in this study perceived that they should be more informed about recycling, thereby expressing a pronounced interest in recycling and thus the environment. Students would like to receive relevant recycling information through participating in environmental education programs which would be focused on recycling. This perhaps reveals students’ high appreciation of environmental education programs with most respondents having participated in such programs. Their participation is what might enable them to recognize the important role of environmental education in recycling and choose it as the most appropriate means to receive information on recycling. In addition, students’ participation in environmental education programs may explain most students’ commitment to recycling. Environmental education is crucial both in recycling and in other environmental issues and especially contributes to the education of primary school students. Primary school students are in the best age to learn and become aware of recycling which, in turn, can lead them to develop proper environmental attitudes and adopt pro-environmental behaviors later as adults. The importance of age was previously confirmed by Eagles and Demare [51], who indicated that attitudes are shaped until the beginning of adolescence, while changes in behavior are more possible in younger individuals. The positive effect of environmental education was also shown by Bradely et al. [54], who observed that the students who attended environmental education not only increased their environmental knowledge but also developed positive attitudes towards the environment.
In addition, this study showed that the respondents follow pro-environmental daily practices. Hence, it could be stated that pro-environmental behavior can predict the engagement of individuals in recycling. The conclusion that students follow practices which aim at environmental protection resonates with Naquin et al. [50], who also observed that primary school students wish to perform environmentally friendly practices.
Even though the relevant literature confirms many of the findings presented in this study, the findings can be generalized only to primary school students in the Prefecture of Evros. However, they are not generalizable to all Greek primary school students. Hence, it is recommended to conduct similar studies in other Greek regions and urban centers in order to learn more about the factors affecting students’ recycling behavior.

6. Conclusions

With regard to the findings presented and discussed in this paper, certain conclusions may be drawn. First, family is a highly influential recycling factor; students whose family members recycle were found to recycle to a greater degree compared to those students whose family members do not recycle on a frequent basis. Therefore, decision makers involved in efforts aiming at improving the recycling behavior of students should also include students’ parents. However, it is difficult to arrive at any conclusions regarding the finding that the education level of parents has a discernible effect on the recycling behavior of students, with students whose parents are more educated having adopted more consistent recycling behaviors. A future qualitative study could perhaps point to the way that parents’ education level affects the recycling behavior of children. In addition, students’ positive attitudes toward environmental education programs and their stated desire for recycling information allow us to infer that students respond positively to environmental education programs focusing explicitly on recycling and providing relevant useful information and guidelines. Finally, students who follow pro-environmental practices in their everyday life are more actively engaged in recycling in comparison to those who do not follow pro-environmental practices. Hence, this study confirmed previous findings showing that environmental awareness can induce individuals to adopt recycling behaviors.

Author Contributions

Conceptualization, G.T.; Methodology, G.T. and E.A.; Software, E.A. and G.T.; Validation, A.P.; Formal Analysis, G.T. and E.A.; Investigation, E.A.; Data Curation, G.T. and E.A.; Writing—Original Draft Preparation, E.A. and E.K.; Writing—Review and Editing, E.K.; Visualization, G.T. and A.P.; Supervision, G.T. All authors have read and agreed to the published version of the manuscript.

Funding

This research received no external funding.

Institutional Review Board Statement

The study was conducted according to the guidelines of the Declaration of Helsinki, and approved by the Ethics Committee of the Democritus University of Thrace (protocol code: 49253/385 and date of approval 22 May 2020).

Informed Consent Statement

Informed consent was obtained from all subjects involved in the study.

Data Availability Statement

The data presented in this study are available on request from the authors.

Acknowledgments

This research did not receive any specific grant from funding agencies in the public, commercial, or not-for-profit sectors. The authors would like to thank the anonymous reviewers for providing their valuable comments. Moreover, we would like to thank all parties involved in the Democritus University of Thrace and in primary schools in the Prefecture of Evros for supporting this study. Finally, we are grateful to all the primary school students who participated in this study.

Conflicts of Interest

The authors declare no conflict of interest.

References

  1. Pham, L. Design a Solid Waste Management Course for Primary School Focus on Reduce-Reuse-Recycle: Project: WastED–Export of Education, Waste Management-Target Market: Vietnam; University of Applied Sciences: Cape Town, South Africa, 2014. [Google Scholar]
  2. Liu, Y.; Park, S.; Yi, H.; Feiock, R. Evaluating the employment impact of recycling performance in Florida. Waste Manag. 2020, 101, 283–290. [Google Scholar] [CrossRef] [PubMed]
  3. Mrema, K. An Assessment of Students’ Environmental Attitudes and Behaviors and the Effectiveness of Their School Recycling Programs; Dalhousie University: Halifax, NS, Canada, 2008. [Google Scholar]
  4. Vining, J.; Ebreo, A. An evaluation of the public response to a community recycling education program. Soc. Nat. Resour. 1989, 2, 23–36. [Google Scholar] [CrossRef]
  5. Avan, C.; Aydinli, B.; Bakar, F.; Alboga, Y. Preparing Attitude Scale to Define Students’ Attitudes about Environment, Recycling, Plastic and Plastic Waste. Int. Electron. J. Environ. Educ. 2011, 3, 179–191. [Google Scholar] [CrossRef]
  6. Deniz, K.Ö. Preschool Children’s Attitudes towards Selected Environmental Issues; Technical University: Cape Town, South Africa, 2008. [Google Scholar]
  7. Gotch, C.; Hall, T. Understanding nature-related behaviors among children through a theory of reasoned action approach. Environ. Educ. Res. 2004, 10, 157–177. [Google Scholar] [CrossRef]
  8. Gökçe, N.; Kaya, E.; Aktay, S.; Özden, M. Elementary students’ attitudes towards environment. Elem. Educ. Online 2007, 6, 452–468. [Google Scholar]
  9. Kolbe, K.D. Knowledge, Attitudes and Behaviour regarding Waste Management in a Grammar and a Comprehensive School in England—Results from a School Questionnaire. J. Teach. Educ. Sustain. 2015, 17, 58–71. [Google Scholar] [CrossRef] [Green Version]
  10. Halder, P.; Singh, H. Predictors of recycling intentions among the youth: A developing country perspective. Recycling 2018, 3, 38. [Google Scholar] [CrossRef] [Green Version]
  11. Clay, S. Increasing university recycling: Factors influencing recycling behaviour among students at Leeds University. Earth Environ. 2005, 1, 186–228. [Google Scholar]
  12. Busteed, M.; Palkhiwala, K.; Roma, M.; Shah, B. Recycling Attitudes and Behaviors of Students at Carlos Pascua Zúñiga High School; Research Project Report. Carlos Pascua Zuniga High School; Worcester Polytechnic Institute: Worcester, MA, USA, 2009. [Google Scholar]
  13. Williams, H. Examining the Effects of Recycling Education on the Knowledge, Attitudes, and Behaviors of Elementary School Students; Illinois Wesleyan University: Bloomington, IL, USA, 2011. [Google Scholar]
  14. Hornik, J.; Cherian, J.; Madansky, M.; Narayana, C. Determinants of recycling behavior: A synthesis of research results. J. Soc. Econ. 1995, 24, 105–127. [Google Scholar] [CrossRef]
  15. Schultz, P.W.; Oskamp, S.; Mainieri, T. Who recycles and when? A review of personal and situational factors. J. Environ. Psychol. 1995. [Google Scholar] [CrossRef]
  16. Long, J.; Harré, N.; Atkinson, Q.D. Understanding Change in Recycling and Littering Behavior Across a School Social Network. Am. J. Community Psychol. 2014, 53, 462–474. [Google Scholar] [CrossRef] [PubMed]
  17. Schwab, N.; Harton, H.C.; Cullum, J.G. The Effects of Emergent Norms and Attitudes on Recycling Behavior. Environ. Behav. 2014, 4, 403–422. [Google Scholar] [CrossRef]
  18. Prabawa-Sear, K.; Baudains, C. Asking the participants: Students’ views on their environmental attitudes, behaviours, motivators and barriers. Aust. J. Environ. Educ. 2011, 27, 219–228. [Google Scholar] [CrossRef] [Green Version]
  19. Sobri, N.A.; Rahman, H.A. Knowledge, attitude and practices on recycling activity among primary school students in Hulu Langat, Selangor, Malaysia. Indian J. Environ. Prot. 2016, 36, 792–800. [Google Scholar]
  20. Matthies, E.; Selge, S.; Klöckner, C.A. The role of parental behaviour for the development of behaviour specific environmental norms—The example of recycling and re-use behaviour. J. Environ. Psychol. 2012, 32, 277–284. [Google Scholar] [CrossRef]
  21. Seacat, J.D.; Northrup, D. An information-motivation-behavioral skills assessment of curbside recycling behavior. J. Environ. Psychol. 2010, 30, 393–401. [Google Scholar] [CrossRef]
  22. Aoki, M. An Analysis of Determinants of Consumer’s Recycling Behavior. In AP—Asia Pacific Advances in Consumer Research; Association for Consumer Research; Yong-Uon, H., Youjae, Y., Duluth, M.N., Eds.; 2005; Volume 6, pp. 322–325. Available online: https://acrwebsite.org/assets/PDFs/Proceedings/APACRVol11.pdf (accessed on 30 May 2021).
  23. Boyes, E.; Stanisstreet, M. Environmental Education for Behaviour Change: Which actions should be targeted? Int. J. Sci. Educ. 2012, 34, 1591–1614. [Google Scholar] [CrossRef]
  24. Largo-Wight, E.; Bian, H.; Lange, L. An Empirical test of an expanded version of the theory of planned behavior in predicting recycling behavior on campus. Am. J. Health Educ. 2012, 43, 66–73. [Google Scholar] [CrossRef]
  25. Almatari, A.Y.; Iahad, N.A.; Balaid, A.S. Factors influencing students’ intention to recycle. J. Inf. Syst. Res. Innov. 2013, 5, 1–8. [Google Scholar]
  26. Poškus, M.S. Atliekų Rūšiavimo Prognozavimas Į Planuoto Elgesio Teoriją Įtraukus Moralės Normas. Psichol. Vilniaus. Univ. 2016, 52, 22–32. [Google Scholar] [CrossRef] [Green Version]
  27. McCarty, J.A.; Shrum, L.J. The recycling of solid wastes: Personal values, value orientations, and attitudes about recycling as antecedents of recycling behavior. J. Bus. Res. 1994, 30, 53–62. [Google Scholar] [CrossRef]
  28. Ludwig, T.D.; Gray, T.W.; Rowell, A. Increasing recycling in academic buildings: A systematic replication. J. Appl. Behav. Anal. 1998, 31, 683–686. [Google Scholar] [CrossRef] [Green Version]
  29. Kalaitzoglou, Ν. Secondary School Students’ Opinions, Attitudes and Knowledges towards Recycling and Energy Saving, in Prefecture of Evros; Democritus University of Thrace: Komotini, Greece, 2018. [Google Scholar]
  30. Miranda, R.; Blanco, A. Environmental awareness and paper recycling. Cellul. Chem. Technol. 2010, 44, 431–439. [Google Scholar]
  31. Bao, R. Waste and Recycling Attitudes and Behavior of Students in Turku; University of Turku: Turku, Finland, 2011. [Google Scholar]
  32. Wright, Y.L. Relating Recycling: Demographics, Attitudes, Knowledge and Recycling Behavior among UC Berkeley Students. UC Berkeley Stud. Recycl. 2011. Available online: https://nature.berkeley.edu/classes/es196/projects/2011final/WrightY_2011.pdf (accessed on 30 May 2021).
  33. Karasmanaki, E.; Galatsidas, S.; Tsantopoulos, G. An Investigation of Factors Affecting the Willingness to Invest in Renewables among Environmental Students: A Logistic Regression Approach. Sustainability 2019, 11, 5012. [Google Scholar] [CrossRef] [Green Version]
  34. Ugulu, I. A quantitative investigation on recycling attitudes of gifted/talented students. Biotechnol. Biotechnol. Equip. 2015, 29, S20–S26. [Google Scholar] [CrossRef]
  35. Psarra M Exploration and Presentation of Evros Prefecture Secondary Education Students’ Knowledge and Views on Environmental Issues; Democritus University of Thrace: Komotini, Greece, 2018.
  36. Juárez-Lugo, C.-S. Predictors of recycling behavior among primary school students in Mexico. Psyecology 2010, 1, 91–103. [Google Scholar] [CrossRef]
  37. Tuncer, G.; Ertepinar, H.; Tekkaya, C.; Sungur, S. Environmental attitudes of young people in Turkey: Effects of school type and gender. Environ. Educ. Res. 2005, 11, 215–233. [Google Scholar] [CrossRef]
  38. Mahmud, S.N.D.; Osman, K. The determinants of recycling intention behavior among the Malaysian school students: An application of Theory of Planned Behaviour. In Proceedings of the Procedia—Social and Behavioral Sciences, Cairo, Egypt, 29–31 October 2010. [Google Scholar]
  39. Zorpas, A.A.; Voukkali, I.; Loizia, P. Effectiveness of waste prevention program in primary students’ schools. Environ. Sci. Pollut. Res. 2017, 24, 14304–14311. [Google Scholar] [CrossRef] [PubMed]
  40. Smith, S.M.; Haugtvedt, C.P.; Petty, R.E. Attitudes and recycling: Does the measurement of affect enhance behavioral prediction? Psychol. Mark. 1994, 11, 359–374. [Google Scholar] [CrossRef]
  41. Miricioiu, M.G.; Niculescu, V.-C. Fly Ash, from Recycling to Potential Raw Material for Mesoporous Silica Synthesis. Nanomaterials 2020, 10, 474. [Google Scholar] [CrossRef] [PubMed] [Green Version]
  42. Constantinescu, M.; Bucura, F.; Ionete, E.I.; Ion-Ebrasu, D.; Sandru, C.; Zaharioiu, A.; Marin, F.; Miricioiu, M.G.; Niculescu, V.C.; Oancea, S.; et al. From plastic to fuel—New challenges. Mater. Plast. 2019, 56, 721–729. [Google Scholar] [CrossRef]
  43. Constantinescu, M.; Bucura, F.; Ionete, R.-E.; Niculescu, V.-C.; Ionete, E.I.; Zaharioiu, A.; Oancea, S.; Miricioiu, M.G. Comparative Study on Plastic Materials as a New Source of Energy. Mater. Plast. 2019, 56, 41–46. [Google Scholar] [CrossRef]
  44. Lefkeli, S.; Manolas, E.; Ioannou, K.; Tsantopoulos, G. Socio-Cultural Impact of Energy Saving: Studying the Behaviour of Elementary School Students in Greece. Sustainability 2018, 10, 737. [Google Scholar] [CrossRef] [Green Version]
  45. Zerinou, I.; Karasmanaki, E.; Ioannou, K.; Andrea, V.; Tsantopoulos, G. Energy Saving: Views and Attitudes among Primary School Students and Their Parents. Sustainability 2020, 12, 6206. [Google Scholar] [CrossRef]
  46. Paraschidou, A. Comparative Research of Students’ and Parents’ Views and Attitudes towards Recycling. The Case of Primary Education in the Municipality of Orestiada. Master’s Thesis, Democritus University of Thrace, Orestiada, Greece, 2018. [Google Scholar]
  47. Freund, R.J.; Wilson, W.J.; Mohr, D.L. Data and Statistics. In Statistical Methods; Academic Press: Cambridge, MA, USA, 2012. [Google Scholar]
  48. Siardos, G. Methods of Multivariate Statistical Analysis. Examination of the Association between Variables; Part I; Ziti: Thessaloniki, Greece, 1999. [Google Scholar]
  49. Embong, A.M.; Mohd Hashim, H.; Noor, A.M.; Yaacob, R.A.I.R.; Seng, L.K.; Malik, N.A. Assessing the understanding and practices of 3R’s among the secondary school students. In Proceedings of the 13th International Conference on Environment and Electrical Engineering (EEEIC), Wroclaw, Poland, 1–3 November 2013; pp. 6–11. [Google Scholar]
  50. Naquin, M.; Cole, D.; Bowers, A.; Walkwitz, E. Environmental Health Knowledge, Attitudes and Practices of Students in Grades Four through Eight. ICHPER-SD J. Res. 2011, 6, 45–50. [Google Scholar]
  51. Eagles, P.F.J.; Demare, R. Factors Influencing Children’s Environmental Attitudes. J. Environ. Educ. 1999, 30, 33–37. [Google Scholar] [CrossRef]
  52. Yilmaz, O.; Boone, W.J.; Andersen, H.O. Views of elementary and middle school Turkish students toward environmental issues. Int. J. Sci. Educ. 2004, 26, 1527–1546. [Google Scholar] [CrossRef]
  53. Malandrakis, G.; Chatzakis, S. Environmental Attitudes, Knowledge, and Alternative Conceptions of Primary School Children in Greece. Appl. Environ. Educ. Commun. 2014, 13, 15–27. [Google Scholar] [CrossRef]
  54. Bradley, J.C.; Waliczek, T.M.; Zajicek, J.M. Relationship Between Environmental Knowledge and Environmental Attitude of High School Students. J. Environ. Educ. 1999, 30, 17–21. [Google Scholar] [CrossRef]
Figure 1. Percentages regarding performing recycling.
Figure 1. Percentages regarding performing recycling.
World 02 00021 g001
Figure 2. Percentages regarding the frequency with which students’ families recycle.
Figure 2. Percentages regarding the frequency with which students’ families recycle.
World 02 00021 g002
Figure 3. Percentages of students’ participation in environmental education programs.
Figure 3. Percentages of students’ participation in environmental education programs.
World 02 00021 g003
Figure 4. Percentages of students who have attended environmental education programs focusing on recycling.
Figure 4. Percentages of students who have attended environmental education programs focusing on recycling.
World 02 00021 g004
Figure 5. Percentages of students’ level of agreement with the statement that waste creates environmental and health problems.
Figure 5. Percentages of students’ level of agreement with the statement that waste creates environmental and health problems.
World 02 00021 g005
Figure 6. Percentages of students’ views on the contribution of recycling to the solution of environmental issues.
Figure 6. Percentages of students’ views on the contribution of recycling to the solution of environmental issues.
World 02 00021 g006
Figure 7. Percentages of students’ views on the provision of more information on recycling.
Figure 7. Percentages of students’ views on the provision of more information on recycling.
World 02 00021 g007
Figure 8. Transformation plots of dependent and independent variables.
Figure 8. Transformation plots of dependent and independent variables.
World 02 00021 g008aWorld 02 00021 g008b
Table 1. Percentages of students’ gender.
Table 1. Percentages of students’ gender.
Recycling (%)Not Recycling (%)
Male50.354.5
Female49.745.5
Total100.0100.0
Table 2. Percentages of students’ parental occupation.
Table 2. Percentages of students’ parental occupation.
Recycling (%)Not Recycling (%)
Father OccupationMother OccupationFather OccupationMother Occupation
Public employee54.836.053.022.7
Private employee18.219.67.619.7
Freelancer14.313.121.222.7
Household0.016.10.019.7
Farmer9.52.71.67.6
Unemployed1.812.21.57.6
Pensioner1.50.33.00.0
Total100.0100.0100.0100.0
Table 3. Percentages of students’ parental education level.
Table 3. Percentages of students’ parental education level.
Recycling (%)Not Recycling (%)
Education Level of FatherEducation Level of MotherEducation Level of FatherEducation Level of Mother
Primary school graduate0.60.30.01.5
Middle school graduate6.54.810.61.5
High school graduate32.726.545.536.4
Technical/vocational high school graduate 16.712.87.612.1
Technical Institute graduate 6.312.513.67.6
University graduate 29.532.419.734.8
Masters degree holder5.49.23.06.1
PhD holder2.41.50.00.0
Total100.0100.0100.0100.0
Table 4. The application of the non-parametric Friedman test for students’ daily practices.
Table 4. The application of the non-parametric Friedman test for students’ daily practices.
RecyclingNot Recycling
Mean Rank
Opening the fridge door only after deciding what to eat 6.316.23
Using a pressure cooker at home4.944.83
Switching of the lights when leaving a room8.387.95
Closing shutters in winter 8.138.33
Unplugging phone chargers when not using them 7.016.48
Avoiding drying clothes on heaters 3.754.17
Parents not using electric stove during at midday in summer5.126.05
Keeping the windows closed on hot summer days 4.995.55
Ventilating the house only at night on hot summer days 7.747.90
Turing off the tap while brushing teeth 8.898.64
Turning off the water tap while lathering in the shower 8.578.44
Having a bath without filling the tub to have a bubble bath 7.927.39
Switching off the air-conditioner when leaving the house 9.279.04
N = 336
Chi-square = 975.574, df = 12, p < 0.001
N = 66
Chi-square = 141.689, df = 12, p < 0.001
Table 5. Factors affecting students’ recycling behavior.
Table 5. Factors affecting students’ recycling behavior.
Independent VariablesBetaFSig.Pratt Index of Relative Importance
Students’ fathers’ occupation0.0593.5090.0040.000
Students’ mothers’ occupation0.1058.7090.0000.025
Education level of father0.0740.3860.7630.014
Education level of mother0.0400.1740.9140.007
Participation in environmental education programs 0.1383.2330.0730.027
Participation in environmental education programs focusing on recycling0.1613.9990.0460.058
The other members of students’ family perform recycling0.630144.7880.0000.853
Desire for more information related to recycling0.1253.6940.0260.050
Environmental attitudes0.0471.1190.2910.019
Publisher’s Note: MDPI stays neutral with regard to jurisdictional claims in published maps and institutional affiliations.

Share and Cite

MDPI and ACS Style

Altikolatsi, E.; Karasmanaki, E.; Parissi, A.; Tsantopoulos, G. Exploring the Factors Affecting the Recycling Behavior of Primary School Students. World 2021, 2, 334-350. https://0-doi-org.brum.beds.ac.uk/10.3390/world2030021

AMA Style

Altikolatsi E, Karasmanaki E, Parissi A, Tsantopoulos G. Exploring the Factors Affecting the Recycling Behavior of Primary School Students. World. 2021; 2(3):334-350. https://0-doi-org.brum.beds.ac.uk/10.3390/world2030021

Chicago/Turabian Style

Altikolatsi, Eleni, Evangelia Karasmanaki, Androniki Parissi, and Georgios Tsantopoulos. 2021. "Exploring the Factors Affecting the Recycling Behavior of Primary School Students" World 2, no. 3: 334-350. https://0-doi-org.brum.beds.ac.uk/10.3390/world2030021

Article Metrics

Back to TopTop