Tailoring sustainability indicators to small and medium enterprises for measuring industrial sustainability performance

Azemeraw Tadesse Mengistu (Department of Management and Engineering, University of Padova, Vicenza, Italy)
Roberto Panizzolo (Department of Management and Engineering, University of Padova, Vicenza, Italy)

Measuring Business Excellence

ISSN: 1368-3047

Article publication date: 1 November 2022

Issue publication date: 15 March 2023

2920

Abstract

Purpose

The lack of suitable indicators tailored to manufacturing industries’ needs, particularly to small and medium enterprises (SMEs), has been the major challenge to measure and manage industrial sustainability performance. This paper aims to empirically analyze and select the useful and applicable indicators to measure sustainability performance in the context of SMEs.

Design/methodology/approach

A systematic review was carried out to identify potential sustainability indicators from the literature. A questionnaire was designed based on the identified indicators and then pretested with the selected industrial experts, scholars, and researchers to further refine the indicators before data collection from the Italian footwear SMEs. Fuzzy Delphi method with consistency aggregation method was applied to analyze and select the final indicators.

Findings

The study’s findings show that the selected indicators emphasized measuring progress toward achieving industrial sustainability goals in terms of increasing financial benefits, reducing costs, improving market competitiveness, improving the effectiveness of resources utilization, and promoting the well-being of employees, customers and the community. In doing so, Italian footwear SMEs can contribute to achieving the Sustainable Development Goals (SDGs) by promoting health and well-being, promoting sustainable economic growth, providing productive employment and decent work, and ensuring responsible consumption and production.

Social implications

The results of this study have significant social implications in terms of promoting the well-being of employees, customers, and the community.

Originality/value

By providing empirically supported indicators tailored to measure and manage sustainability performance in the context of SMEs, this paper contributes to the existing knowledge in the field of industrial sustainability performance measurement. Furthermore, it links the selected indicators to their respective SDGs to provide policy implications.

Keywords

Citation

Mengistu, A.T. and Panizzolo, R. (2023), "Tailoring sustainability indicators to small and medium enterprises for measuring industrial sustainability performance", Measuring Business Excellence, Vol. 27 No. 1, pp. 54-70. https://doi.org/10.1108/MBE-10-2021-0126

Publisher

:

Emerald Publishing Limited

Copyright © 2022, Azemeraw Tadesse Mengistu and Roberto Panizzolo.

License

Published by Emerald Publishing Limited. This article is published under the Creative Commons Attribution (CC BY 4.0) licence. Anyone may reproduce, distribute, translate and create derivative works of this article (for both commercial and non-commercial purposes), subject to full attribution to the original publication and authors. The full terms of this licence may be seen at http://creativecommons.org/licences/by/4.0/legalcode


1. Introduction

Sustainable manufacturing has been given growing attention for managing the environmental and social impacts of manufacturing industries properly (Ahmad and Wong, 2019; Singh et al., 2014). Manufacturing industries have a significant role in the sustainable development of society (Beekaroo et al., 2019; Moldavska and Welo, 2019). Since manufacturing industries highly consume natural resources and moreover generate emissions and wastes, they should be considered to address sustainability issues (Hendiani et al., 2020). Sustainable manufacturing has also become a key factor for manufacturing firms to stay relevant in the current competitive business environment (Singh et al., 2019). Consequently, there is a need for transformation from the traditional manufacturing practices that focus on economic benefits to the state-of-the-art manufacturing that consider environmental and social responsibility in addition to pursuing the economic benefits (Shuaib et al., 2014; Singh et al., 2019). Adopting sustainability practices in manufacturing industries requires a holistic approach at different application scope that varies from the production line to the plant, the firm, and the supply chain (Huang and Badurdeen, 2018). Industrial sustainability considers the adoption of sustainability practices at the firm level (Trianni et al., 2017).

Industrial sustainability has become an essential topic of discussion (Cagno et al., 2019) and gains significant consideration among industrial decision-makers, policymakers, and scholars (Neri et al., 2018; Trianni et al., 2017). Manufacturing industries are the main driving force for the economic growth and social development of a country (Galal and Moneim, 2015; Zeng et al., 2008). However, they are considered to be one of the main contributors to environmental and social concerns (Zeng et al., 2008). Consequently, they are duly required to improve sustainability performance and to be transparent on their sustainability practices (Trianni et al., 2019). Various stakeholders have put pressures on them to adopt sustainability practices (Huang and Badurdeen, 2018; Ocampo et al., 2016; Zarte et al., 2019) to address the growing concerns of environmental and social impacts (Beekaroo et al., 2019; Samuel et al., 2013; Wang et al., 2018). The stakeholders of industrial sustainability include governments, investors, political groups, trade associations, suppliers, employees, customers and communities (Paramanathan et al., 2004). Moreover, sustainability is adopted to get a competitive advantage (Tseng et al., 2009; Veleva et al., 2001; Wang et al., 2018). To effectively adopt sustainability in industries, measuring its performance is crucial (Cagno et al., 2019; Trianni et al., 2019). The adoption of industrial sustainability considers actions that are taken at the levels of material, product, process, plant, and production system (Tonelli et al., 2013).

The term industrial sustainability was coined by the Institute for Manufacturing at the University of Cambridge, and it defines industrial sustainability as “conceptualization, design and manufacture of goods and services that meet the needs of the present generation while not diminishing economic, social and environmental opportunity in the long-term” (Paramanathan et al., 2004). Moreover, Zeng et al. (2008) defined industrial sustainability as “development that meets the needs of economic growth, social development, environmental protection and results in industrial advantage for the short- and long-term future of the region.” From the concept of sustainability, there is a common understanding that sustainability considers economic, environmental, and social aspects (Paramanathan et al., 2004; Zeng et al., 2008). Elkington (1997) proposed the triple bottom line (TBL) approach that consists of three interrelated (economic, environmental, and social) dimensions of sustainability. TBL provides a comprehensive approach for measuring sustainability performance in manufacturing industries considering the three dimensions (Ahmad and Wong, 2019). To adequately address industrial sustainability, it is crucial to adopt a holistic approach based on TBL (Cagno et al., 2019). Manufacturing industries have a significant impact on the three dimensions of sustainability (Ahmad et al., 2019b; Ghadimi et al., 2012). Subsequently, they should simultaneously consider economic, environmental, and social dimensions while producing their products and services (Eastwood and Haapala, 2015; Haapala et al., 2013; Lacasa et al., 2016; Watanabe et al., 2016).

Although small and medium enterprises (SMEs) are contributing significantly to the economic growth of the country through innovation, production volume, and employment generation (Sajan et al., 2017), they are less likely to address sustainability issues compared to large manufacturing industries (Mitchell et al., 2020). Unlike large manufacturing industries, it is more difficult for SMEs to focus explicitly on sustainability since they have limited resources (Hsu et al., 2017; Singh et al., 2014; Trianni et al., 2019; Winroth et al., 2016) and lack the awareness and expertise required to effectively adopt sustainability (Singh et al., 2014; Trianni et al., 2019). Consequently, measuring sustainability performance in SMEs has been a major challenge (Trianni et al., 2019). Furthermore, there has been a trend that SMEs primarily focus on the economic dimensions of sustainability, and they mainly address the environmental and social dimensions for compliance with regulations imposed by stakeholders (Choi and Lee, 2017; Trianni et al., 2019).

There is still a need for suitable indicators tailored to different manufacturing industry contexts, especially to the context of SMEs, to effectively measure and manage industrial sustainability performance (Singh et al., 2014; Winroth et al., 2016). The lack of useful and applicable indicators has been the major challenge for measuring sustainability performance in manufacturing industries (Ahmad and Wong, 2019; Ocampo et al., 2016). Contextual factors such as industry type, firm size and geographical area affect the use of indicators in measuring industrial sustainability performance (Cagno et al., 2019; Trianni et al., 2019). Thus, tailoring useful and applicable indicators to the industry context is essential to effectively measure sustainability performance in manufacturing industries (Medini et al., 2015). In other words, it is essential to use a manageable number of indicators that are simple and easy to apply (Veleva and Ellenbecker, 2001). Furthermore, by analyzing and selecting indicators that are suitable to the industry context (Ahmad and Wong, 2019; Hsu et al., 2017), the effectiveness of industrial sustainability performance measurement can be increased (Cagno et al., 2019; Trianni et al., 2019).

From the literature analysis, it is observed that the previous studies primarily focused on large manufacturing industries than SMEs. Automotive (Ghadimi et al., 2012; Lee et al., 2014; Moldavska and Welo, 2019; Singh et al., 2018; Vinodh et al., 2016), food (Ahmad and Wong, 2019; Harik et al., 2015; Yakovleva and Flynn, 2004), and electronics (Huang and Badurdeen, 2017; Li et al., 2012; Shuaib et al., 2014) were the industrial sectors mostly used by previous research for conducting case studies. In this study, the Italian footwear SMEs were considered to conduct the empirical study since they are less researched. The footwear sector is one of the industrial sectors driving the economic growth and social development of Italy. According to Assocalzaturifici (2020), the sector had about 74,890 employees, a yearly turnover of about 14.3bn euros by 2019, and consumes a variety of input materials such as leather, synthetic, rubber, and textiles for production. These figures imply the economic, environmental, and social (TBL) implications of the sector that have a significant potential to address sustainability issues. However, the lack of suitable indicators is the major challenge of sustainability performance measurement of footwear firms, particularly SMEs. This study applied fuzzy Delphi method (FDM) with consistency aggregation method (CAM) to analyze and select useful and applicable indicators for measuring industrial sustainability in the SMEs. In the use of FDM based on CAM, all the experts’ opinions are incorporated in one investigation to comprehensively consider the uncertainty and ambiguity of the experts to achieve a group consensus. Thus, the results obtained become objective and rational.

The rest of the work in this paper is divided into three sections. The research methodology applied in this study is described in Section 2. The results of the analysis are discussed in Section 3. Finally, our conclusions and future research work are described in Section 4.

2. Methodology

To achieve the aim of this paper (i.e. to select and prioritize suitable indicators tailored to SMEs for measuring their sustainability performance), the following methodological approach, as seen in Figure 1, was applied to carry out the empirical study for analyzing and selecting the useful and applicable indicators for measuring sustainability performance in the context of the Italian footwear SMEs. The main steps applied to select and prioritize indicators include conducting a systematic review to identify the potential sustainability indicators (step 1), designing a questionnaire (step 2), collecting data (step 3), and analyzing the data using FDM based on CAM (step 4).

2.1 Identification of potential sustainability indicators

A systematic review was conducted to explore indicators within published peer-reviewed articles that are relevant to sustainability performance measurement of manufacturing industries. For this purpose, Scopus and Web of Science (WoS) were selected as search databases since they provide an extensive coverage of peer-reviewed journal articles (Ahi and Searcy, 2015). Two sets of keywords linked to the research topic of this paper were used for the search: “industrial sustainability” or “sustainable manufactur*” or “sustainable firm*” or “sustainable enterpri*” or “sustainable industr*” or “sustainable factory” or “sustainable production*” or “sustainable organi*” or “sustainable compan*” in the first set and “indicator*” or “metric*” or “performance measure*” in the second set. By applying the following approach to screen and select papers shown in Figure 2, a total of 1,456 papers were initially obtained using the keywords search in both Scopus and WoS databases published until 2020. Out of which, 59 papers were selected to identify and analyze the indicators.

A content analysis was conducted to identify the consistently and frequently used indicators (Ahi and Searcy, 2015; Ahmad et al., 2019a). A total of 1,013 indicators (277 for economic, 402 environmental and 334 social dimensions) were explored. The majority (about 85%) of them appeared only once in the reviewed literature. This figure shows a lack of consistency in the use of indicators (i.e. lack of consensus on a single set of indicators) to measure sustainability performance in different industry contexts, and this invites an ongoing research debate on industrial sustainability performance measurement. On the other hand, few indicators (14 for economic, 18 for environmental and 12 for social dimensions) were consistently and frequently used to measure industrial sustainability.

2.2 Questionnaire design

Based on the consistently and frequently used indicators, a questionnaire was developed. Then, the pre-testing (i.e. pilot testing) of the questionnaire was conducted with selected industry experts, scholars, and researchers (Forza, 2002; Padilla-Rivera et al., 2021). The pre-testing was carried out to check clarity (language clarity, context clarity and content clarity), time (as much as possible to finish filling the questionnaire within a few minutes), redundancy (possibility of redundant questions), and relevance (being connected to the objective of the study). The feedback of the pretest was used to modify, add, and delete indicators so as to improve the questionnaire and increase its convergence (Padilla-Rivera et al., 2021).

2.3 Data collection

A total of 48 valid responses were obtained after distributing the questionnaire to Italian footwear firms via email and linkedIn. In other words, experts’ opinions on the sustainability indicators were collected from 48 Italian footwear SMEs. To get empirical evidence from the users of the final selected indicators and increase the reliability of the results, the data collection focused on industry experts. Table 1 summarizes the position and work experience of the experts.

As can be seen in Table 2, Chief Executive Officer/General Manager represents the highest percentage (44%) of the industry experts. Most of the industry experts (49%) have over 20 years of work experience.

A reliability analysis was conducted to check the consistency or repeatability of the questionnaire items (i.e. the indicators). The internal consistency method was applied for testing the reliability (Forza, 2002). Cronbach’s alpha, which is the most common test for internal consistency, was used to assess the reliability of the data. Cronbach’s alpha (α) was calculated in IBM SPSS software (Version 26). The values of α were 0.710, 0.936 and 0.854 for economic, environmental and social dimensions, respectively, which are higher than the minimum acceptable value (0.7).

2.4 Data analysis: Fuzzy Delphi method

Fuzzy Delphi method (FDM) was applied to analyze the experts’ opinions and select the most useful and applicable indicators for measuring industrial sustainability in Italian footwear SMEs. FDM integrates the traditional Delphi method and fuzzy theory to address the drawbacks of the traditional Delphi method (Tsai et al., 2020). The use of fuzzy theory combined with the traditional Delphi method can solve the vagueness and ambiguity of expert judgments to improve efficiency and quality (Lee et al., 2018; Padilla-Rivera et al., 2021). In FDM, the linguistic variables (qualitative) converted into fuzzy membership functions (quantitative) for analysis of the indicators (Tsai et al., 2020). Triangular fuzzy number, trapezoidal fuzzy number, and Gaussian fuzzy number are the membership functions that have been used by previous research (Hsu et al., 2010). For this study, the triangular fuzzy number was applied as a fuzzy membership function (Hsu et al., 2010; Zhang, 2017). FDM avoids the drawbacks of the traditional Delphi method such as low convergence of experts’ opinions (Ma et al., 2011), high cost and considerable time for collecting experts’ opinions (Ma et al., 2011; Padilla-Rivera et al., 2021; Tsai et al., 2020) due to the several rounds of a survey applied in the traditional Delphi method (Zhang, 2017). In FDM, all the experts’ opinions are incorporated in one investigation (Kuo and Chen, 2008; Ma et al., 2011) to comprehensively consider the uncertainty and ambiguity of the experts (Zhang, 2017) to achieve a consensus (Kuo and Chen, 2008). Thus, this method is considered to be robust (Padilla-Rivera et al., 2021) and can create a better effect of data analysis (Ma et al., 2011), and the results obtained are objective and rational (Zhang, 2017). More specifically, consistency aggregation method (CAM) was applied. In this method, the fuzzy individual expert’s opinions are aggregated into a group consensus opinion for each indicator. To incorporate all the experts’ opinions, both similarity and difference among the experts were considered to apply CAM (Lin et al., 2019; Lu et al., 2006). CAM was adopted through the following steps:

  • Extract experts’ opinions: Collect and organize the assessment scores given by each expert for each sustainability indicator from the returned questionnaire.

  • Convert the experts’ opinions into triangular fuzzy numbers: Translate the linguistic variables used by the experts to assess the sustainability indicators into triangular fuzzy numbers (Zhang, 2017) as shown in Table 2. The linguistic variables are used to express the experts’ opinions on the importance (i.e., usefulness and applicability) of the indicator.

That is the triangular fuzzy numbers of the expert opinion is defined as EPi = (ai, bi, ci), for i = 1, 2,…, n.

where EPi is expert opinion of the ith expert in the form of minimum (a), optimum (b) and maximum (c), and n is total number of experts.

  • Determine similarity (S) between each pair of experts’ opinions: The degree of similarity between each pair of experts’ opinions was calculated as the proportion of intersection area (IntsArea) relative to the union area of each pair of experts’ opinions EPi = (ai, bi, ci) and EPj = (aj, bj, cj) as follows:

    (1) S(EPi, EPj)= IntsArea (EPi, EPj)Area(EPi)+Area(EPj)IntsArea (EPi, EPj), for i=1, 2,, n

For the same experts’ opinions S(EPi, EPj) = 1, and if IntsArea(EPi,EPj) = 0, S(EPi, EPj) = 0.

S(EPi, EPj) = S(EPj, EPi) (i.e. S(EP1, EP2) = S(EP2, EP1)).
  • Determine difference (D) between each pair of experts’ opinions: Calculate the distance between each pair of experts’ opinions EPi = (ai, bi, ci) and EPj = (aj, bj, cj) as shown below:

    (2) D(EPi, EPj)= 12|bibj|, for i=1, 2,, n

For identical experts’ opinions, D(EPi, EPj) = 0.

Then, convert the absolute distance (D) into normalized distance (ND) using the following formula:

(3) ND(EPi, EPj)= D(EPi, EPj)Max[D(EPi,EPj)] 
  • Determine consistency degree (r) between each pair of experts: For i = 1, 2,…, n, the consistency degree of each pair of experts EPi was calculated as follows:

    (4) r(EPi, EPj)= βS(EPi, EPj)+(1β)ND(EPi, EPj)

For this study, considering equal importance for the similarity and difference among the experts, β = 0.5 was taken.

  • Determine degree of importance (e) for each expert: The degree of importance (relative importance) of each expert (ei) is calculated based on their years of work experience. For this purpose, the following values of importance are assigned for the years of work experience categorized in this study. Accordingly, 5 for over 20 years of experience, 4 for 15 to 20 years, 3 for 10 to 15 years, 2 for 5 to 10 years and 1 for below 5 years. Table 3 summarizes the degree of importance (relative importance) of each expert (ei).

  • Determine the weighted consistency degree (C) of each expert: For i = 1, 2,…, n, calculate the weighted consistency degree of each expert Ei as seen below:

    (5) C(Ei)=i=1nr(EPi, EPj)*ei

  • Determine the aggregation weight (w) of each expert: For i = 1, 2,…, n, the aggregation weight of each expert Ei was calculated as follows:

    (6) w(Ei)= C(Ei)i=1nC(Ei)

  • Determine the aggregate fuzzy opinion (R) for each indicator (k): For k = 1, 2,…, N, calculate the fuzzy opinion as shown below:

    (7) Rk=k=1Nw(Ei)(.)EPi

which implies the following:

(8) Rk=[(w(E1)*a1+w(E2)*a2++w(En)*an),(w(E1)*b1+w(E2)*b2++ w(En)*bn),(w(E1)*c1+w(E2)*c2++w(En)*cn)]Rk=(ak,bk,ck),fork=1,2,,N,whereNisnumberofindicators.
  • Defuzzification: Determine the final score of each indicator. The center of gravity method was applied to defuzzify the aggregate fuzzy opinion of the indicator (Rk) as follows:

    (9) Sk= ak+bk+ck3

where Sk is a final defuzzified score, which indicates the aggregate importance of each indicator (i).

  • Select indicators: The final sustainability indicators were selected by setting a threshold value (T).

If Sk ≥ T, the indicator is selected.

If Sk < T, the indicator is not selected.

Setting the threshold value depends on the fuzzy linguistic scale and user preference (Padilla-Rivera et al., 2021; Zhang, 2017). If the users want more indicators, they can take a small value of the threshold and vice versa (Zhang, 2017). In this study, a threshold value (T = 6.2) was taken for a nine-fuzzy linguistic scale to select the indicators.

3. Results and discussion

In this section, the results of the analysis are presented with their discussion. In subsection 3.1, the potential sustainability indicators identified after conducting literature analysis and pre-testing and the final selected sustainability indicators are presented. The results are discussed in subsection 3.2.

3.1 Results

After conducting the systematic review and pre-testing the questionnaire with the selected industry experts, scholars and researcher, 40 potential sustainability indicators were identified and presented in Table 4. This study applied FDM based on CAM to incorporate experts’ opinions with fuzzy logic for selecting the final suitable indicators. Through FDM, it is possible to analyze a group consensus by addressing the uncertainty and ambiguity of experts’ judgment when evaluating each indicator (Padilla-Rivera et al., 2021). Table 5 summarizes the results of the analysis based on the FDM.

For the selection of indicators, the final defuzzified scores (Table 5) are compared with the threshold value (T = 6.2). As a result, 25 indicators were selected and prioritized to measure sustainability performance in Italian footwear SMEs as shown in Figure 3. This does not mean that the unselected indicators are irrelevant, but they have, compared to the selected indicators, a lower priority to the SMEs. From the 25 selected indicators, product quality (8.091) was the top prioritized indicator for measuring the economic sustainability dimension followed by on-time delivery (7.978), profit (7.325), revenue (6.856), research & development (R&D) expenditure (6.747), labor cost (6.488), and material cost (6.380). Material consumption (6.944) followed by recycled material use (6.740), energy efficiency (6.688), and energy consumption (6.285) were found to be the most appropriate indicators for measuring the environmental sustainability dimension. Customer satisfaction (8.221) was given the top priority followed by working conditions (7.885), customer complaints (7.813), occupational health and safety (7.713), work-related injuries (7.644), employee satisfaction (7.630), customer health and safety (7.607), fair salary (7.352), employment/job opportunity (7.088) and training and development (7.020), working hours (6.833), lost working days (6.324), and employee turnover (6.323) for measuring the social sustainability dimension in the Italian footwear SMEs.

3.2 Discussion

From the empirical analysis, the results show that a few number of indicators (n = 25) were selected and prioritized to effectively measure and manage sustainability performance in Italian footwear SMEs. To measure the economic dimension of industrial sustainability, indicators linked to financial benefits (profit and revenue), costs (labor cost and material cost) and market competitiveness (R&D expenditure, on-time delivery, lead time, and product quality) were given high priority. On-time delivery, lead time, and product quality are crucial to ensure market competitiveness and financial performance of SMEs in the short run. Moreover, SMEs need to allocate reasonable expenditure to conduct R&D activities for promoting innovation for producing sustainable products and enhancing market competitiveness in the long run.

Although water consumption (Ahmad and Wong, 2019; Cagno et al., 2019; Demartini et al., 2018; Vitale et al., 2019) and greenhouse gas (GHG) emissions (Abedini et al., 2020; Beekaroo et al., 2019; Cagno et al., 2019; Zarte et al., 2019) were frequently used by previous studies for measuring the environmental sustainability, this empirical study revealed that these indicators are less prioritized. This is due to the production process of footwear SMEs is not water-intensive unlike other industrial sectors such as food and beverage and produces fewer emissions. On the other hand, material consumption, recycled material use, energy efficiency, and energy consumption were prioritized over the other indicators of the environmental dimension. Different input materials are used by footwear industries to produce a range of products (Staikos and Rahimifard, 2007). Among which, leather, synthetics, plastic, rubber, and textiles are the most common input materials that are consumed by the footwear production process (Sellitto Miguel and Almeida Francieli Aparecida, 2019). The footwear industry has placed a significant effort in improving material efficiency and eliminating the use of hazardous materials during the production (Staikos and Rahimifard, 2007). The Italian footwear SMEs gave more attention to material consumption to measure their progress in terms of material efficiency improvement, hazardous materials reduction, and the use of eco-friendly and biodegradable materials. Subsequently, they can minimize waste generation by improving material efficiency. The safety of their products to the customers can be improved by reducing the use of hazardous materials in the production phase. Moreover, reducing the use of hazardous materials, increasing the use of eco-friendly and biodegradable materials, and promoting the use of recycled materials are crucial in minimizing growing concerns from environmental and social impacts of the end-of-life (EOL) products in the post-use phase. It is also essential for SMEs to measure their progress in energy saving and cost reduction using energy efficiency as one of the prioritized indicators.

In the social dimension of industrial sustainability, indicators that promote sustainability performance measurement related to employees, customers, and community were selected. The footwear industry is one of the industrial sectors that have low technology and are labor intensive (Scott, 2006). Since it is a labor-intensive industry, improving the well-being of the employees is required in the Italian footwear SMEs. To measure the progress towards this goal, working conditions, occupational health and safety, work-related injuries, fair salary, training and development, and employee satisfaction were the top prioritized indicators. SMEs also need to measure the progress in improving the well-being of their customers. To achieve this goal, customer satisfaction, customer complaints, and customer health and safety were found as more relevant indicators. High priority was given to employment/job opportunity to measure the progress toward community development. Moreover, working hours and lost working days were key indicators to measure performance associated with the working time management of employees.

Along with increasing pressure from stakeholders on footwear industries to be more transparent about their sustainability practices and improve sustainability performance, there is a growing interest in measuring and evaluating industrial sustainability performance. However, as SMEs have limited resources, they need to use a manageable number of suitable indicators to measure and report their sustainability performance effectively. The selected and prioritized indicators can be used to effectively measure and manage the sustainability performance of SMEs. Moreover, these indicators can also be applied to define, implement, evaluate and monitor policies to enhance sustainable manufacturing by considering economic, environmental, and social aspects while producing products and services, ensuring economic growth, conserving natural resources, minimizing negative environmental and social impacts, and meeting the requirements of stakeholders. Eventually, they can contribute to achieving the following Sustainable Development Goals (SDGs) such as promoting health, and well-being (SDG 3), promoting sustainable economic growth, productive employment and decent work (SDG 8), and ensuring sustainable consumption and production (SDG 12). Table 6 presents the link between the selected indicators and the SDGs.

4. Conclusions

This paper selected and prioritized sustainability indicators in the contexts of SMEs using fuzzy Delphi method (FDM) based on consistency aggregation method (CAM). The method combines the qualitative method (gathering experts’ opinions using the questionnaire) and quantitative method (fuzzy analysis considering the ambiguity and subjectivity associated with the experts’ opinions) to analyze and select the useful and applicable indicators for measuring industrial sustainability in the Italian footwear SMEs.

Our findings revealed that the selected indicators promote measuring and managing the progress towards achieving industrial sustainability goals in terms of increasing financial benefits, reducing costs, and market competitiveness for the economic sustainability dimension; improving the effectiveness of resources utilization for the environmental sustainability dimension; and promoting employees, customers, and the community for the social sustainability dimension. Therefore, SMEs need to focus and allocate their limited resources on effectively applying the selected indicators to measure and manage their sustainability performance. In doing so, they can contribute to achieving the SDGs by promoting health and well-being, promoting sustainable economic growth, providing productive employment, and decent work, and ensuring responsible consumption and production.

This paper has significant academic, practical, and policy implications. It will be a good theoretical base for future research in industrial sustainability performance measurement, primarily for the sustainability performance measurement of footwear industry. It provides a comprehensive methodological approach ranging from literature analysis to empirical analysis of sustainability indicators. Eventually, it can contribute to the existing theory and knowledge in the field of industrial sustainability performance measurement. From a practical viewpoint, it provides empirically supported indicators tailored to the context of SMEs to effectively measure and manage their sustainability performance. The methodological approach applied to tailor the indicators can easily be adapted to different manufacturing industry contexts. It also has policy implications by linking the selected indicators to industrial sustainability goals and their respective SDGs and can serve as a significant input for the policymakers in the field of industrial sustainability.

The scope of this paper was limited at the firm level to analyze TBL sustainability indicators. However, to get a more comprehensive view of sustainability by including the environment and social impacts of EOL products, it would be better to include additional indicators including governance indicators for measuring and managing sustainability performance at the supply chain level. Hence, it will be interesting for the future research to expand the approach applied in this paper to the entire supply chain consisting of supply, production, distribution, use, and post-use.

Figures

Methodological approach for selecting and prioritizing indicators

Figure 1

Methodological approach for selecting and prioritizing indicators

Approach used for screening and selecting papers

Figure 2

Approach used for screening and selecting papers

Final selected indicators

Figure 3

Final selected indicators

Profile of the experts by frequency

Variable Position Frequency (#) (%)
Position Chief Executive Officer/General Manager 21 44
Production Manager 7 15
Operation Manager 9 19
Expert/Professional Employee of Sustainability 6 13
Others 5 10
Work experience Over 20 years 23 49
15 to 20 years 4 9
10 to 15 years 10 21
5 to 10 years 6 13
Below 5 years 4 9

Linguistic variables with their corresponding fuzzy scales and triangular fuzzy numbers

Fuzzy scales Linguistic variables Triangular fuzzy no. (a,b,c)
1 Not important (NI) (1,1,3)
3 Slightly important (SI) (1,3,5)
5 Moderately important (MI) (3,5,7)
7 Important (I) (5,7,9)
9 Very important (VI) (7,9,9)

Degrees of importance of the experts

Expert Value Relative importance Expert Value Relative importance Expert Value Relative importance
E1 5 0.0276 E17 3 0.0166 E33 1 0.0055
E2 2 0.0110 E18 5 0.0276 E34 1 0.0055
E3 5 0.0276 E19 2 0.0110 E35 5 0.0276
E4 5 0.0276 E20 5 0.0276 E36 3 0.0166
E5 4 0.0221 E21 3 0.0166 E37 3 0.0166
E6 5 0.0276 E22 3 0.0166 E38 5 0.0276
E7 5 0.0276 E23 5 0.0276 E39 5 0.0276
E8 5 0.0276 E24 5 0.0276 E40 1 0.0055
E9 5 0.0276 E25 3 0.0166 E41 1 0.0055
E10 4 0.0221 E26 5 0.0276 E42 3 0.0166
E11 2 0.0110 E27 5 0.0276 E43 4 0.0221
E12 5 0.0276 E28 4 0.0221 E44 5 0.0276
E13 5 0.0276 E29 3 0.0166 E45 5 0.0276
E14 2 0.0110 E30 4 0.0221 E46 5 0.0276
E15 3 0.0166 E31 2 0.0110 E47 5 0.0276
E16 5 0.0276 E32 2 0.0110 E48 3 0.0166

Indicators identified after literature analysis and pre-testing

Indicators for economic dimension Indicators for environmental dimension Indicators for social dimension
Profit Water consumption Employment/Job opportunity
Revenue Recycled water use Fair salary
R&D expenditure Energy consumption Employee turnover
Material cost Renewable energy use Employee satisfaction
Labor cost Energy efficiency Occupational health and safety
Energy cost Energy intensity Training and development
Maintenance cost Material consumption Working conditions
Packaging cost Recycled material use Work-related injuries
Inventory cost Packaging material consumption Working hours
Product quality Land use Lost working days
Lead time GHG emissions Customer health and safety
On-time delivery Wastewater discharge Customer satisfaction
Solid waste disposal Customer complaints
Recyclable waste Corruption

Aggregate fuzzy opinion and defuzzified score

Sustainability dimensions Indicators (k) Aggregate fuzzy opinion Defuzzified score (Sk) Selected
Min (lk) Optimum (mk) Max (uk)
Economic Profit 5.613 7.613 8.749 7.325 Y
Revenue 4.962 6.962 8.642 6.856 Y
R&D expenditure 4.978 6.965 8.297 6.747 Y
Material cost 4.463 6.448 8.229 6.380 Y
Labor cost 4.618 6.618 8.230 6.488 Y
Energy cost 4.024 6.024 7.871 5.973
Maintenance cost 3.645 5.561 7.469 5.559
Packaging cost 3.150 5.097 7.071 5.106
Inventory cost 3.422 5.316 7.289 5.342
Product quality 6.642 8.642 8.987 8.091 Y
Lead time 6.167 8.167 8.885 7.740 Y
On-time delivery 6.480 8.480 8.972 7.978 Y
Environmental Water consumption 2.852 4.265 5.954 4.357
Recycled water use 2.909 4.193 5.939 4.347
Energy consumption 4.435 6.376 8.043 6.285 Y
Renewable energy use 4.162 6.121 7.674 5.986
Energy efficiency 4.945 6.912 8.209 6.688 Y
Energy intensity 3.795 5.722 7.505 5.674
Material consumption 5.186 7.186 8.460 6.944 Y
Recycled material use 4.943 6.928 8.351 6.740 Y
Packaging material consumption 4.337 6.251 7.949 6.179
Land use 2.652 4.332 6.143 4.376
GHG emissions 3.406 5.250 6.755 5.137
Wastewater discharge 2.844 4.534 6.247 4.542
Solid waste disposal 3.880 5.834 7.575 5.763
Recyclable waste 3.946 5.897 7.419 5.754
Social Employment/Job opportunity 5.245 7.245 8.774 7.088 Y
Fair salary 5.642 7.642 8.773 7.352 Y
Employee turnover 4.465 6.448 8.056 6.323 Y
Employee satisfaction 5.993 7.993 8.902 7.630 Y
Occupational health and safety 6.133 8.133 8.873 7.713 Y
Training and development 5.161 7.161 8.737 7.020 Y
Working conditions 6.376 8.376 8.903 7.885 Y
Work-related injuries 6.029 8.029 8.873 7.644 Y
Working hours 5.001 7.001 8.497 6.833 Y
Lost working days 4.449 6.449 8.074 6.324 Y
Customer health and safety 6.001 7.994 8.824 7.607 Y
Customer satisfaction 6.838 8.838 8.988 8.221 Y
Customer complaints 6.252 8.252 8.934 7.813 Y
Corruption 4.544 6.278 7.669 6.164

Link between the selected indicators and their respective SDGs

Sustainability
dimensions
Indicators Sustainable Development Goals (SDGs)
SDG 3 SDG 8 SDG 12
Economic Product quality   X  
On-time delivery   X  
Lead time   X  
Profit   X  
Revenue   X  
R&D expenditure   X X
Labor cost   X  
Material cost   X  
Environmental Material consumption     X
Recycled material use     X
Energy efficiency     X
Energy consumption     X
Social Customer satisfaction X    
Working conditions X X  
Customer complaints X    
Occupational health and safety X    
Work-related injuries X    
Employee satisfaction X X  
Customer health and safety X    
Fair salary   X  
Employment/Job opportunity   X  
Training and development   X  
Working hours X X X
Lost working days X X X
Employee turnover X X X

References

Abedini, A., Li, W., Badurdeen, F. and Jawahir, I.S. (2020), “A metric-based framework for sustainable production scheduling”, Journal of Manufacturing Systems, Vol. 54, pp. 174-185, doi: 10.1016/j.jmsy.2019.12.003.

Ahi, P. and Searcy, C. (2015), “An analysis of metrics used to measure performance in green and sustainable supply chains”, Journal of Cleaner Production, Vol. 86, pp. 360-377, doi: 10.1016/j.jclepro.2014.08.005.

Ahmad, S. and Wong, K.Y. (2019), “Development of weighted triple-bottom line sustainability indicators for the Malaysian food manufacturing industry using the Delphi method”, Journal of Cleaner Production, Vol. 229, pp. 1167-1182, doi: 10.1016/j.jclepro.2019.04.399.

Ahmad, S., Wong, K.Y. and Rajoo, S. (2019a), “Sustainability indicators for manufacturing sectors: a literature survey and maturity analysis from the triple-bottom line perspective”, Journal of Manufacturing Technology Management, Vol. 30 No. 2, pp. 312-334, doi: 10.1108/JMTM-03-2018-0091.

Ahmad, S., Wong, K.Y. and Zaman, B. (2019b), “A comprehensive and integrated Stochastic-Fuzzy method for sustainability assessment in the Malaysian food manufacturing industry”, Sustainability, Vol. 11 No. 4, doi: 10.3390/su11040948.

Assocalzaturifici (2020), The Italian Footwear Industry – 2019 Preliminary Results, Confindustria Moda Research Centre, Milan.

Beekaroo, D., Callychurn, D.S. and Hurreeram, D.K. (2019), “Developing a sustainability index for Mauritian manufacturing companies”, Ecological Indicators, Vol. 96, pp. 250-257, doi: 10.1016/j.ecolind.2018.09.003.

Cagno, E., Neri, A., Howard, M., Brenna, G. and Trianni, A. (2019), “Industrial sustainability performance measurement systems: a novel framework”, Journal of Cleaner Production, Vol. 230, pp. 1354-1375, doi: 10.1016/j.jclepro.2019.05.021.

Choi, S. and Lee, J.Y. (2017), “Development of a framework for the integration and management of sustainability for small- and medium-sized enterprises”, International Journal of Computer Integrated Manufacturing, Vol. 30 No. 11, pp. 1190-1202, doi: 10.1080/0951192X.2017.1305506.

Demartini, M., Pinna, C., Aliakbarian, B., Tonelli, F. and Terzi, S. (2018), “Soft drink supply chain sustainability: a case based approach to identify and explain best practices and key performance indicators”, Sustainability, Vol. 10 No. 10, doi: 10.3390/su10103540.

Eastwood, M.D. and Haapala, K.R. (2015), “A unit process model based methodology to assist product sustainability assessment during design for manufacturing”, Journal of Cleaner Production, Vol. 108, pp. 54-64, doi: 10.1016/j.jclepro.2015.08.105.

Elkington, J. (1997), Cannibals with Forks: The Triple Bottom Line of 21st Century Business, Capstone, Oxford.

Forza, C. (2002), “Survey research in operations management: a process‐based perspective”, International Journal of Operations & Production Management, Vol. 22 No. 2, pp. 152-194, doi: 10.1108/01443570210414310.

Galal, N.M. and Moneim, A.F.A. (2015), “A mathematical programming approach to the optimal sustainable product mix for the process industry”, Sustainability, Vol. 7 No. 10, pp. 13085-13103, doi: 10.3390/su71013085.

Ghadimi, P., Azadnia, A.H., Yusof, N.M. and Saman, M.Z.M. (2012), “A weighted fuzzy approach for product sustainability assessment: a case study in automotive industry”, Journal of Cleaner Production, Vol. 33, pp. 10-21, doi: 10.1016/j.jclepro.2012.05.010.

Haapala, K.R., Zhao, F., Camelio, J., Sutherland, J.W., Skerlos, S., Dornfeld, D., … Rickli, J.L. (2013), “A review of engineering research in sustainable manufacturing”, Journal of Manufacturing Science and Engineering, Vol. 135 No. 4, p. 041013, doi: 10.1115/1.4024040.

Harik, R., El Hachem, W., Medini, K. and Bernard, A. (2015), “Towards a holistic sustainability index for measuring sustainability of manufacturing companies”, International Journal of Production Research, Vol. 53 No. 13, pp. 4117-4139, doi: 10.1080/00207543.2014.993773.

Hendiani, S., Liao, H., Bagherpour, M., Tvaronavičienė, M., Banaitis, A. and Antucheviciene, J. (2020), “Analyzing the status of sustainable development in the manufacturing sector using multi-expert multi-criteria fuzzy decision-making and integrated triple bottom lines”, International Journal of Environmental Research and Public Health, Vol. 17 No. 11, p. 3800, doi: 10.3390/ijerph17113800.

Hsu, C.H., Chang, A.Y. and Luo, W. (2017), “Identifying key performance factors for sustainability development of SMEs – integrating QFD and fuzzy MADM methods”, Journal of Cleaner Production, Vol. 161, pp. 629-645, doi: 10.1016/j.jclepro.2017.05.063.

Hsu, Y.-L., Lee, C.-H. and Kreng, V.B. (2010), “The application of fuzzy Delphi method and fuzzy AHP in lubricant regenerative technology selection”, Expert Systems with Applications, Vol. 37 No. 1, pp. 419-425, doi: 10.1016/j.eswa.2009.05.068.

Huang, A. and Badurdeen, F. (2017), “Sustainable manufacturing performance evaluation at the enterprise level: index- And value-based methods”, Smart and Sustainable Manufacturing Systems, Vol. 1 No. 1, pp. 178-203, doi: 10.1520/SSMS20170004.

Huang, A. and Badurdeen, F. (2018), “Metrics-based approach to evaluate sustainable manufacturing performance at the production line and plant levels”, Journal of Cleaner Production, Vol. 192, pp. 462-476, doi: 10.1016/j.jclepro.2018.04.234.

Kuo, Y.-F. and Chen, P.-C. (2008), “Constructing performance appraisal indicators for mobility of the service industries using fuzzy Delphi method”, Expert Systems with Applications, Vol. 35 No. 4, pp. 1930-1939, doi: 10.1016/j.eswa.2007.08.068.

Lacasa, E., Santolaya, J.L. and Biedermann, A. (2016), “Obtaining sustainable production from the product design analysis”, Journal of Cleaner Production, Vol. 139, pp. 706-716, doi: 10.1016/j.jclepro.2016.08.078.

Lee, J.Y., Kang, H.S. and Noh, S.D. (2014), “MAS2: an integrated modeling and simulation-based life cycle evaluation approach for sustainable manufacturing”, Journal of Cleaner Production, Vol. 66, pp. 146-163, doi: 10.1016/j.jclepro.2013.11.029.

Lee, C.-H., Wu, K.-J. and Tseng, M.-L. (2018), “Resource management practice through eco-innovation toward sustainable development using qualitative information and quantitative data”, Journal of Cleaner Production, Vol. 202, pp. 120-129, doi: 10.1016/j.jclepro.2018.08.058.

Li, T., Zhang, H., Yuan, C., Liu, Z. and Fan, C. (2012), “A PCA-based method for construction of composite sustainability indicators”, The International Journal of Life Cycle Assessment, Vol. 17 No. 5, pp. 593-603, doi: 10.1007/s11367-012-0394-y.

Lin, C.J., Belis, T.T. and Kuo, T.C. (2019), “Ergonomics-based factors or criteria for the evaluation of sustainable product manufacturing”, Sustainability, Vol. 11 No. 18, p. 4955, doi: 10.3390/su11184955.

Lu, C., Lan, J. and Wang, Z. (2006), “Aggregation of fuzzy opinions under group decision-making based on similarity and distance”, Journal of Systems Science and Complexity, Vol. 19 No. 1, pp. 63-71, doi: 10.1007/s11424-006-0063-y.

Ma, Z., Shao, C., Ma, S. and Ye, Z. (2011), “Constructing road safety performance indicators using fuzzy Delphi method and grey Delphi method”, Expert Systems with Applications, Vol. 38 No. 3, pp. 1509-1514, doi: 10.1016/j.eswa.2010.07.062.

Medini, K., Da Cunha, C. and Bernard, A. (2015), “Tailoring performance evaluation to specific industrial contexts – application to sustainable mass customisation enterprises”, International Journal of Production Research, Vol. 53 No. 8, pp. 2439-2456, doi: 10.1080/00207543.2014.974844.

Mitchell, S., O’Dowd, P. and Dimache, A. (2020), “Manufacturing SMEs doing it for themselves: developing, testing and piloting an online sustainability and eco-innovation toolkit for SMEs”, International Journal of Sustainable Engineering, Vol. 13 No. 3, pp. 159-170, doi: 10.1080/19397038.2019.1685609.

Moldavska, A. and Welo, T. (2019), “A holistic approach to corporate sustainability assessment: incorporating sustainable development goals into sustainable manufacturing performance evaluation”, Journal of Manufacturing Systems, Vol. 50, pp. 53-68, doi: 10.1016/j.jmsy.2018.11.004.

Neri, A., Cagno, E., Di Sebastiano, G. and Trianni, A. (2018), “Industrial sustainability: modelling drivers and mechanisms with barriers”, Journal of Cleaner Production, Vol. 194, pp. 452-472, doi: 10.1016/j.jclepro.2018.05.140.

Ocampo, L.A., Clark, E.E. and Promentilla, M.A.B. (2016), “Computing sustainable manufacturing index with fuzzy analytic hierarchy process”, International Journal of Sustainable Engineering, Vol. 9 No. 5, pp. 305-314, doi: 10.1080/19397038.2016.1144828.

Padilla-Rivera, A., do Carmo, B.B.T., Arcese, G. and Merveille, N. (2021), “Social circular economy indicators: selection through fuzzy Delphi method”, Sustainable Production and Consumption, Vol. 26, pp. 101-110, doi: 10.1016/j.spc.2020.09.015.

Paramanathan, S., Farrukh, C., Phaal, R. and Probert, D. (2004), “Implementing industrial sustainability: the research issues in technology management”, R&D Management, Vol. 34 No. 5, pp. 527-537. doi: 10.1111/j.1467-9310.2004.00360.x.

Sajan, M.P., Shalij, P.R., Ramesh, A. and Biju, A.P. (2017), “Lean manufacturing practices in Indian manufacturing SMEs and their effect on sustainability performance”, Journal of Manufacturing Technology Management, Vol. 28 No. 6, pp. 772-793, doi: 10.1108/JMTM-12-2016-0188.

Samuel, V.B., Agamuthu, P. and Hashim, M.A. (2013), “Indicators for assessment of sustainable production: a case study of the petrochemical industry in Malaysia”, Ecological Indicators, Vol. 24, pp. 392-402, doi: 10.1016/j.ecolind.2012.07.017.

Scott, A.J. (2006), “The changing global geography of low-technology, labor-intensive industry: clothing, footwear, and furniture”, World Development, Vol. 34 No. 9, pp. 1517-1536., doi: 10.1016/j.worlddev.2006.01.003.

Sellitto Miguel, A. and Almeida Francieli Aparecida, D. (2019), “Strategies for value recovery from industrial waste: case studies of six industries from Brazil”, Benchmarking: An International Journal, Vol. 27 No. 2, pp. 867-885, doi: 10.1108/BIJ-03-2019-0138.

Shuaib, M., Seevers, D., Zhang, X., Badurdeen, F., Rouch, K.E. and Jawahir, I.S. (2014), “Product sustainability index (ProdSI): a metrics-based framework to evaluate the total life cycle sustainability of manufactured products”, Journal of Industrial Ecology, Vol. 18 No. 4, pp. 491-507, doi: 10.1111/jiec.12179.

Singh, R.K., Modgil, S. and Tiwari, A.A. (2019), “Identification and evaluation of determinants of sustainable manufacturing: a case of Indian cement manufacturing”, Measuring Business Excellence, Vol. 23 No. 1, pp. 24-40, doi: 10.1108/MBE-08-2018-0056.

Singh, S., Olugu, E.U. and Fallahpour, A. (2014), “Fuzzy-based sustainable manufacturing assessment model for SMEs”, Clean Technologies and Environmental Policy, Vol. 16 No. 5, pp. 847-860, doi: 10.1007/s10098-013-0676-5.

Singh, S., Olugu, E.U., Musa, S.N. and Mahat, A.B. (2018), “Fuzzy-based sustainability evaluation method for manufacturing SMEs using balanced scorecard framework”, Journal of Intelligent Manufacturing, Vol. 29 No. 1, pp. 1-18, doi: 10.1007/s10845-015-1081-1.

Staikos, T. and Rahimifard, S. (2007), “An end-of-life decision support tool for product recovery considerations in the footwear industry”, International Journal of Computer Integrated Manufacturing, Vol. 20 No. 6, pp. 602-615, doi: 10.1080/09511920701416549.

Tonelli, F., Evans, S. and Taticchi, P. (2013), “Industrial sustainability: challenges, perspectives, actions”, International Journal of Business Innovation and Research, Vol. 7 No. 2, pp. 1751-0252, doi: 10.1504/IJBIR.2013.052576.

Trianni, A., Cagno, E. and Neri, A. (2017), “Modelling barriers to the adoption of industrial sustainability measures”, Journal of Cleaner Production, Vol. 168, pp. 1482-1504, doi: 10.1016/j.jclepro.2017.07.244.

Trianni, A., Cagno, E., Neri, A. and Howard, M. (2019), “Measuring industrial sustainability performance: empirical evidence from Italian and German manufacturing small and medium enterprises”, Journal of Cleaner Production, Vol. 229, pp. 1355-1376, doi: 10.1016/j.jclepro.2019.05.076.

Tsai, H.-C., Lee, A.-S., Lee, H.-N., Chen, C.-N. and Liu, Y.-C. (2020), “An application of the fuzzy Delphi method and fuzzy AHP on the discussion of training indicators for the regional competition, Taiwan national skills competition, in the trade of joinery”, Sustainability, Vol. 12 No. 10, p. 4290, doi: 10.3390/su12104290.

Tseng, M.L., Divinagracia, L. and Divinagracia, R. (2009), “Evaluating firm's sustainable production indicators in uncertainty”, Computers & Industrial Engineering, Vol. 57 No. 4, pp. 1393-1403, doi: 10.1016/j.cie.2009.07.009.

Veleva, V. and Ellenbecker, M. (2001), “Indicators of sustainable production: framework and methodology”, Journal of Cleaner Production, Vol. 9 No. 6, pp. 519-549, doi: 10.1016/S0959-6526(01)00010-5.

Veleva, V., Bailey, J. and Jurczyk, N. (2001), “Using sustainable production indicators to measure progress in ISO 14001, EHS system and EPA achievement track”, Corporate Environmental Strategy, Vol. 8 No. 4, pp. 326-338, doi: 10.1016/S1066-7938(01)00138-5.

Vinodh, S., Ben Ruben, R. and Asokan, P. (2016), “Life cycle assessment integrated value stream mapping framework to ensure sustainable manufacturing: a case study”, Clean Technologies and Environmental Policy, Vol. 18 No. 1, pp. 279-295, doi: 10.1007/s10098-015-1016-8.

Vitale, G., Cupertino, S., Rinaldi, L. and Riccaboni, A. (2019), “Integrated management approach towards sustainability: an Egyptian business case study”, Sustainability, Vol. 11 No. 5, p. 1244, doi: 10.3390/su11051244.

Wang, C., Wang, L. and Dai, S. (2018), “An indicator approach to industrial sustainability assessment: the case of China’s Capital economic circle”, Journal of Cleaner Production, Vol. 194, pp. 473-482, doi: 10.1016/j.jclepro.2018.05.125.

Watanabe, E.H., da Silva, R.M., Tsuzuki, M.S.G., Junqueira, F., dos Santos Filho, D.J. and Miyagi, P.E. (2016), “A framework to evaluate the performance of a new industrial business model”, IFAC-PapersOnLine, Vol. 49 No. 31, pp. 61-66, doi: 10.1016/j.ifacol.2016.12.162.

Winroth, M., Almstrom, P. and Andersson, C. (2016), “Sustainable production indicators at factory level”, Journal of Manufacturing Technology Management, Vol. 27 No. 6, pp. 842-873., doi: 10.1108/JMTM-04-2016-0054.

Yakovleva, N. and Flynn, A. (2004), “Innovation and sustainability in the food system: a case of chicken production and consumption in the UK”, Journal of Environmental Policy & Planning, Vol. 6 Nos 3/4, pp. 227-250, doi: 10.1080/1523908042000344096.

Zarte, M., Pechmann, A. and Nunes, I.L. (2019), “Indicator framework for sustainable production planning and controlling”, International Journal of Sustainable Engineering, Vol. 12 No. 3, pp. 149-158., doi: 10.1080/19397038.2019.1566410.

Zeng, S.X., Liu, H.C., Tam, C.M. and Shao, Y.K. (2008), “Cluster analysis for studying industrial sustainability: an empirical study in shanghai”, Journal of Cleaner Production, Vol. 16 No. 10, pp. 1090-1097., doi: 10.1016/j.jclepro.2007.06.004.

Zhang, J. (2017), “Evaluating regional low-carbon tourism strategies using the fuzzy Delphi- analytic network process approach”, Journal of Cleaner Production, Vol. 141, pp. 409-419, doi: 10.1016/j.jclepro.2016.09.122.

Acknowledgements

The authors gratefully acknowledge the advice and contributions from Prof. Cipriano Forza, a member of the faculty of the PhD program in Management Engineering at the University of Padova. The authors would also like to thank the Cassa di Risparmio di Padova e Rovigo (CARIPARO) Foundation for its financial support.

Corresponding author

Azemeraw Tadesse Mengistu can be contacted at: azemerawtadesse.mengistu@phd.unipd.it

About the authors

Azemeraw Tadesse Mengistu is based at Department of Management and Engineering, University of Padova, Vicenza, Italy. Azemeraw Tadesse Mengistu (https://orcid.org/0000-0002-3108-461X) is a researcher at the University of Padova, Vicenza, Italy.

Roberto Panizzolo is based at Department of Management and Engineering, University of Padova, Vicenza, Italy. Roberto Panizzolo (https://orcid.org/0000-0001-7807-8332) is a researcher at the University of Padova, Vicenza, Italy.

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