Assessment of sustainable performance of the top five Brazilian steel industries using the TOPSIS technique with Gaussian AHP

Cunha, Carlos Alberto Soares; Lima, Igor Macedo de; Caldas, Gabriel Brito; Vieira Neto, Julio; Rangel, Luís Alberto Duncan; Lima, Gilson Brito Alves

doi:10.1590/1806-9649-2024v31e9823

Abstract

The Brazilian steel industry holds enormous economic significance, as it produced approximately 32 million steel products in 2022 and exported around 12 million tons to over 100 countries. Based on a 2021 study conducted by the Institute for Applied Economic Research (IPEA), the steel industry contributed 1.9% to the overall national Gross Domestic Product (GDP). Although the steel industry plays a significant role in Brazil's trade balance, it has direct implications on economic, environmental, and social aspects, thereby intersecting with the three fundamental principles of sustainability. This study aims to assess the sustainable performance of the five primary companies by integrating the TOPSIS method with the Gaussian AHP method. The evaluation will be based on indicators derived from the Sustainable Development Goals (GRI) and will utilize sustainability reports from 2019 to 2021. The study demonstrated the feasibility of employing the suggested approach as a means of evaluating the sustainable performance of the five organizations in the steel sector, thus positioning it as a prospective tool for stakeholder analysis.

Keywords:
sustainable performance; Brazilian steel companies; TOPSIS; AHP-Gaussian

Resumo

A indústria siderúrgica brasileira possui importância ímpar para a economia, uma vez que sua produção, em 2022, girou na ordem de 32 milhões de produtos siderúrgicos e suas exportações, para mais de cem países, chegou ao montante de aproximadamente 12 milhões de toneladas. Segundo estudo de 2021 do Instituto de Pesquisa Econômica Aplicada (IPEA), a siderurgia representou 1,9% do PIB Nacional. Apesar da contribuição para a balança comercial brasileira, a siderurgia afeta diretamente as questões ligadas à economia, ao meio ambiente e ao social interagindo, desta forma, com os três pilares da sustentabilidade. Em razão dessa interconexão, o presente estudo tem por objetivo avaliar o desempenho sustentável das cinco principais empresas através da combinação do método TOPSIS com o método AHP-Gaussiano utilizando indicadores estabelecidos pelo Sustainable Development Goals (GRI), oriundo dos relatórios de sustentabilidade dos anos de 2019 a 2021. O estudo demonstrou a possibilidade de utilização do método proposto como forma de avaliar o desempenho sustentável das cinco organizações do setor siderúrgico tornando-se potencial ferramenta de análise por partes interessadas.

Palavras-chave:
desempenho sustentável; siderúrgicas brasileiras; TOPSIS; AHP-Gaussiano

1 Introduction

According to the Brazilian Steel Institute (2023)Brazilian Steel Institute. (2023). Brazil Steel Databook 2023. Rio de Janeiro: Brazilian Steel Institute. Retrieved in 2023, September 23, from https://acobrasil.org.br/site/wp-content/uploads/2023/07/AcoBrasil_Anuario_2023.pdf
https://acobrasil.org.br/site/wp-content... , the country had, in 2022, a producer park with 31 steel mills, being administered by 11 business groups. For production, its installed capacity is around 51 million tons/year of crude steel. Given this potential, the park produced 31.5 million tons of steel products, 11.9 million tons exported to more than 100 countries.

Still in relation to 2022, according to Comex Stat Portal (Brasil, 2023Brasil. Ministry of Industry, Foreign Trade and Services. (2023). Comex Stat Portal, 2023. Retrieved in 2023, September 23, from http://comexstat.mdic.gov.br/pt/geral/105563
http://comexstat.mdic.gov.br/pt/geral/10... ), the export of cast iron, iron and steel registered approximately 16.7 billion dollars. In terms of participation in exports, the Brazilian steel industry generated 5% of the value traded externally. As a result, the sector occupied the fifth position among all Brazilian products intended to other countries and, in addition, according to the IPEA (2021)Institute for Applied Economic Research - IPEA. (2021). IPEAdata. Retrieved in 2023, September 23, from http://www.ipeadata.gov.br/Default.aspx
http://www.ipeadata.gov.br/Default.aspx... study, the steel industry represented 1.9% of the National GDP.

Since the export of products is responsible for a significant portion of the revenues generated externally, the Brazilian trade balance is favored by this sector. With this, it is noted that the national steel industry guarantees a prominent role in commodity exports contributing to the economic development of the country.

However, although the economic axis (revenue generation) is paramount for the development of a country, it can no longer dissociate itself from the other pillars of the Triple Bottom Line (TBL). This is due to the fact that a linear model of production and consumption is unsustainable and leads to resource depletion, waste production and environmental degradation, all of which pose serious risks to people's health and the environment (Hegab et al., 2023Hegab, H., Shaban, I., Jamil, M., & Khanna, N. (2023). Toward sustainable future: Strategies, indicators, and challenges for implementing sustainable production systems. Sustainable Materials and Technologies, 36, e00617. http://dx.doi.org/10.1016/j.susmat.2023.e00617.
http://dx.doi.org/10.1016/j.susmat.2023.... ).

For example, considering the environmental pillar, steel production generates waste and greenhouse gas (GHG) emissions that directly impact the environment. According to the Climate Observatory (2023)Climate Observatory. (2023). The Greenhouse Gas Emissions and Removals Estimation System (SEEG) Portal, 2023. Retrieved in 2023, September 23, from https://plataforma.seeg.eco.br/?_gl=1*1u92vj1*_ga*OTU4MTIzMTYxLjE3MTA4ODE5NTk.*_ga_XZWSWEJDWQ*MTcxMDg4MTk1OC4xLjEuMTcxMDg4MjM2OC4wLjAuMA
https://plataforma.seeg.eco.br/?_gl=1*1u... , GHG emissions have been increasing over fifty years. In 2019, production of 32.6 million tons of steel generated approximately 42 million tons of CO₂ Another important point noted was that, in a decade (2009-2019), steel production varied by 27.69% while gas emission varied by 49.21%.

Thus, the fact that GHG emissions are characteristic of the sector in terms of environmental impact and in the face of the problems that the steel industry entails, the concern with waste generation has become the current agenda of several scientific research in responses to environmental impacts (Rossoni et al., 2021Rossoni, A., Rossoni, H. A. V., & Rodrigues, A. B. (2021). Potencial reutilização dos resíduos provenientes da indústria de ferrossílicio: revisão sistemática e aprofundada da literatura. Revista Ibero-Americana de Ciências Ambientais, 12(10), 385-398. http://dx.doi.org/10.6008/CBPC2179-6858.2021.010.0031.
http://dx.doi.org/10.6008/CBPC2179-6858.... ).

Another concern occurs in the social field, whose theme lies mainly in the health care of the people who inhabit the surroundings where the steel mills are located. As an example of the need for a social look, one has the specific case of Taranto - a city in southern Italy, where one of the largest steel mills in Europe is located. Due to the activities of the plant, a higher risk of mortality from lung cancer, respiratory diseases and pleural mesothelioma was reported. In addition, the record of excess incidence of cancer appeared among the younger population (Gianicolo et al., 2021Gianicolo, E. A. L., Cervino, M., Russo, A., Singer, S., Blettner, M., & Mangia, C. (2021). Environmental assessment of interventions to restrain the impact of industrial pollution using a quasi-experimental design: limitations of the interventions and recommendations for public health policy. BMC Public Health, 21(1), 1856. http://dx.doi.org/10.1186/s12889-021-11832-3 PMid:34649551.
http://dx.doi.org/10.1186/s12889-021-118... ). Therefore, one cannot forget to worry about what is outside the organization.

In addition, social issues go beyond simple concern for community health. They can also be embraced internally by the company through gender and race diversity and the empowerment of the workforce, the promotion of the development of local suppliers, as well as improving relationships with the community. All this, in the organization, cannot be executed alone. In the literature, new research and practices in sustainability propose an integrated concept in which “social issues” are indistinguishable and inseparable from economic or environmental issues (Peterson, 2016Peterson, N. (2016). Introduction to the special issue on social sustainability: Integration, context, and governance. Sustainability, 12(1), 3-7. http://dx.doi.org/10.1080/15487733.2016.11908148
http://dx.doi.org/10.1080/15487733.2016.... ).

Since the pillars must be interconnected, knowing the status quo of the three dimensions of sustainability of an organization is the first step to propose strategies and actions that stimulate sustainable development in the search for competitive advantage (Falsarella & Jannuzzi, 2020Falsarella, O. M., & Jannuzzi, C. S. C. (2020). Organizational and competitive intelligence and big data: a systemic vision for the organizations’sustainable management. Perspectivas em Ciência da Informação, 25(1), 179-204. http://dx.doi.org/10.1590/1981-5344/3497
http://dx.doi.org/10.1590/1981-5344/3497... ).

One of the ways to know the status quo of an organization is through sustainability reports, because these arise as a tool for promoting performance (Guedes et al., 2020Guedes, É. C., Ribeiro, R. R., & Jeunon, E. E. (2020). Análise da utilização dos indicadores do Global Reporting Initiative (GRI) nos relatórios de sustentabilidade de empresas com atuação em Minas Gerais. Revista Sinapse Múltipla, 9(2), 150-151.) and as a means of dissemination of sustainable actions (Souza et al., 2023Souza, M. M., Oliveira, A. L. R., & Souza, M. F. (2023). Location of agricultural warehouses based on spatial multicriteria analysis. Revista de Economia e Sociologia Rural, 62(1), e268622. http://dx.doi.org/10.1590/1806-9479.2022.268622
http://dx.doi.org/10.1590/1806-9479.2022... ). The main report model, adopted by several organizations, is the one provided by the Global Reporting Initiative (GRI) (Oliveira et al., 2022Oliveira, R. S. G., Forapani, G., & Pereira, P. D. S. (2022). Responsabilidade Social Universitária: analisando organizações educacionais no contexto de capitalismo neoliberal a partir dos relatórios de sustentabilidade da Global Reporting Initiative. In XI Encontro de Estudos Organizacionais da ANPAD (pp. 1-11). Maringá: Associação Nacional de Pós-Graduação e Pesquisa em Administração - ANPAD. ).

Created in 1997 in Amsterdam (Netherlands). GRI is a non-profit organization, the result of a joint effort by the Coalition for Environmentally Responsible Economies (CERES) and the United Nations Environmental Program (UNEP), it aims to help governments and organizations understand the impacts of business on sustainable development (Campos et al., 2013Campos, L. M. D. S., Sehnem, S., Oliveira, M. D. A. S., Rossetto, A. M., Coelho, A. L. D. A. L., & Dalfovo, M. S. (2013). Relatório de sustentabilidade: perfil das organizações brasileiras e estrangeiras segundo o padrão da Global Reporting Initiative. Gestão & Produção, 20(4), 913-926. http://dx.doi.org/10.1590/S0104-530X2013005000013.
http://dx.doi.org/10.1590/S0104-530X2013... ). The first version of the GRI guidelines was published in 2000 (Vieira et al., 2020Vieira, I. L., Silva, E. R., Martini, L. C. Jr, & Mattos, U. A. O. (2020). Pontos positivos e negativos dos relatórios de sustentabilidade no modelo global reporting initiative: revisão da literatura nacional e internacional. Revista Gestão Industrial, 16(2), 21-46. http://dx.doi.org/10.3895/gi.v16n2.10549.
http://dx.doi.org/10.3895/gi.v16n2.10549... ) and, in 2015, the version adapted to Sustainable Development Goals (GRI, 2021Global Reporting Initiative - GRI. (2021). News Center of GRI, 2021. All eyes on a sustainable COVID recovery. Retrieved in 2023, September 23, from https://www.globalreporting.org/news/news-center/all-eyes-on-a-sustainable-covid-recovery/
https://www.globalreporting.org/news/new... ) appears.

Since the 2015 GRI version presents guidelines that dialogue with the 17 Sustainable Development Goals (SDGs), established by the United Nations (UN), these have become the voluntary communication structure of environmental and social performance of the best known companies worldwide (Caiado et al., 2017Caiado, R. G. G., Lima, G. B. A., Gaviáo, L. O., Quelhas, O. L. G., & Paschoalino, F. F. (2017). Sustainability analysis in electrical energy companies by similarity technique to ideal solution. Revista IEEE América Latina, 15(4), 675-681. http://dx.doi.org/10.1109/TLA.2017.7896394
http://dx.doi.org/10.1109/TLA.2017.78963... ).

However, considering the amount of information presented in the sustainability reports of steel organizations addressed in this study, which translate into numerous indicators (criteria) of sustainability (economic, environmental and social), it is necessary to use a multicriteria model to support the decision that orders organizations from the best to the worst performance.

According to the literature, the quantities of available Multi-Criteria Decision Making (MCDM) tools that support techniques to help decision makers are numerous. The best known are AHP, TOPSIS, ELECTRE, PROMETHEE, VIKOR and others. However, in order to seek the best alternative for each criterion through a simple mathematical formulation, as well as the ease of its computational process and the characteristic that the best alternative is through the ordering of criteria, Technique for Order Preference by Similarity to Ideal Solution (TOPSIS) (Hamurcu & Eren, 2023Hamurcu, M., & Eren, T. (2023). Multicriteria decision making and goal programming for determination of electric automobile aimed at sustainable green environment: a case study. Environment Systems & Decisions, 43(2), 211-231. http://dx.doi.org/10.1007/s10669-022-09878-8. PMid:36118127.
http://dx.doi.org/10.1007/s10669-022-098... ) will be adopted.

The TOPSIS method will aim to prioritize and select the organization that had the best sustainable performance considering the various indicators contained in the company reports. However, instead of using the traditional Analytic Hierachy Process (AHP) method to define the criteria weights, the AHP-Gaussian will be used in view of the fact that it stands out for its ability to save the cognitive effort of the decision-maker in assigning weights to the criteria (Pereira et al., 2023Pereira, R. C. A., Silva, O. S. Jr, Mello Bandeira, R. A., Santos, M., Souza Rocha, C. Jr, Castillo, C. D. S., Gomes, C. F. S., Moura Pereira, D. A., & Muradas, F. M. (2023). Evaluation of smart sensors for subway electric motor escalators through AHP-Gaussian method. Sensors (Basel), 23(8), 1. http://dx.doi.org/10.3390/s23084131 PMid:37112474.
http://dx.doi.org/10.3390/s23084131... ), eliminating the subjectivity of the analyses.

Given the presented, the objective of this article is to evaluate the sustainable performance of the five largest Brazilian steel companies, through the application of the TOPSIS method for sorting combined with the AHP-Gaussian method for assigning the weights of the criteria. To achieve the objective, the criteria for sustainability evaluation were identified - the common criteria selected in the GRI reports of the years 2019 and 2021; the construction of the spreadsheets with the values of the criteria; the performance decision matrices were constructed; standardized performance decision matrices; Calculated weights by standardized Gaussian factor; Calculated best (PIS) and worst solution for each year; Calculated distances to PIS and NIS; Calculated relative distances and nearby per year; and finally, obtained the classifications of companies per year. As a result of the evaluation, the relevance of the research lies in the practical application of these methods, providing valuable information that can contribute to the improvement of sustainability in the steel industry. In addition, it is noteworthy that the approach of this study meets the growing demands of society for sustainable practices.

In addition to this introduction, the article includes a theoretical framework where sustainable development is presented - which contains the concept and importance of this theme nowadays; the TOPSIS method, whose technique has as characteristic to evaluate the performance of the alternatives through the similarity with the ideal solution, thus ordering from the best to the worst solution; the AHP-Gaussian method, whose main characteristic is to obtain the weights of the criteria by means of quantitative criteria; the materials and methods adopted in the study related to the development of the work; analysis and discussion of the results; and conclusion.

2 Theoretical framework

2.1 Sustainable development

The concept of sustainable development, which aims to balance economic progress, environmental preservation and social well-being, is crucial in the current context. The concept has been widely discussed and analyzed in several academic papers that present the importance of sustainable development in the balance between economic progress, environmental preservation and social well-being, in addition to the concepts, definitions and elements of sustainability and optimization (Sadollah et al., 2020Sadollah, A., Nasir, M., & Geem, Z. W. (2020). Sustainability and optimization: from conceptual fundamentals to applications. Sustainability (Basel), 12(5), 1. http://dx.doi.org/10.3390/su12052027
http://dx.doi.org/10.3390/su12052027... ).

Industry plays a significant role in this equation, as it is a major engine of economic transformation, but also a significant generator of environmental and social impacts. The work of Luken & Castellanos-Silveria (2011)Luken, R., & Castellanos-Silveria, F. (2011). Industrial transformation and sustainable development in developing countries. Sustainable Development (Bradford), 19(3), 167-175. http://dx.doi.org/10.1002/sd.434
http://dx.doi.org/10.1002/sd.434... examined the relationship between industrial transformation and the positive and negative impacts of industry on sustainable development in developing countries, providing information on the dual role of the industry in promoting economic progress, while generating environmental and social impacts.

According to Usman & Hammar (2021)Usman, M., & Hammar, N. (2021). Dynamic relationship between technological innovations, financial development, renewable energy, and ecological footprint: fresh insights based on the STIRPAT model for Asia Pacific Economic Cooperation countries. Environmental Science and Pollution Research International, 28(12), 15519-15536. http://dx.doi.org/10.1007/s11356-020-11640-z PMid:33241498.
http://dx.doi.org/10.1007/s11356-020-116... , in order to achieve sustainable development, it is necessary to understand the driving factors of economic growth, such as technological progress, trade openness and financial development. The challenges to achieving sustainability in the steel industry are substantial due to the various environmental impacts associated with steel production. These impacts include greenhouse gas emissions, natural resource consumption and waste generation (Milford et al., 2013Milford, R. L., Pauliuk, S., Allwood, J. M., & Müller, D. B. (2013). The roles of energy and material efficiency in meeting steel industry CO2 targets. Environmental Science & Technology, 47(7), 3455-3462. http://dx.doi.org/10.1021/es3031424 PMid:23470090.
http://dx.doi.org/10.1021/es3031424... ).

Schoeman et al. (2020)Schoeman, Y., Oberholster, P., & Somerset, V. (2020). Value stream mapping as a supporting management tool to identify the flow of industrial waste: a case study. Sustainability (Basel), 13(1), 91. http://dx.doi.org/10.3390/su13010091
http://dx.doi.org/10.3390/su13010091... claim that the sustainability of the steel industry is undermined by the negative consequences of waste generation, such as environmental degradation and economic spending to mitigate environmental impacts. In addition, the sustainability of the steel industry is challenged by the need to adopt principles of sustainable development and ensure that performance is aligned with these principles (Bucur et al., 2017Bucur, A., Dobrotă, G., Oprean-Stan, C., & Tănăsescu, C. (2017). Economic and qualitative determinants of the world steel production. Metals, 7(5), 9. http://dx.doi.org/10.3390/met7050163
http://dx.doi.org/10.3390/met7050163... ).

The environmental impacts generated by the steel industry are really significant (Toktarova et al., 2020Toktarova, A., Karlsson, I., Rootzén, J., Göransson, L., Odenberger, M., & Johnsson, F. (2020). Pathways for low-carbon transition of the steel industry: a swedish case study. Energies, 13(15), 1. http://dx.doi.org/10.3390/en13153840
http://dx.doi.org/10.3390/en13153840... ). He & Wang (2017)He, K., & Wang, L. (2017). A review of energy use and energy-efficient technologies for the iron and steel industry. Renewable & Sustainable Energy Reviews, 70, 1022-1039. http://dx.doi.org/10.1016/j.rser.2016.12.007
http://dx.doi.org/10.1016/j.rser.2016.12... concluded that substantial consumption of natural resources, such as water and energy, and the generation of solid waste by industry present urgent challenges that require immediate attention and action from the sector. In the social context, the presence of steel mills has been associated with public health and well-being issues. Studies in areas close to these industries have pointed out health problems related to air and water pollution, directly impacting the quality of life of local communities (Touzi & Horchani-Naifer, 2023Touzi, N., & Horchani-Naifer, K. (2023). A study on the preparation and characterization of pigment quality from iron-containing waste materials. Environmental Science and Pollution Research. (Preprint). ).

Understanding these impacts is essential to promote effective actions toward sustainability in the steel industry. Strategies that address both environmental and social issues are necessary to mitigate these adverse effects. The steel industry has responded to environmental challenges by adopting strategies and initiatives to promote sustainability. Investments in cleaner technologies, emission reduction policies and environmental management practices have been implemented to mitigate adverse impacts (Duan et al., 2021Duan, Y., Han, Z., Zhang, H., & Wang, H. (2021). Research on the applicability and impact of CO2 emission reduction policies on China’s steel industry. International Journal of Climate Change Strategies and Management, 13(3), 352-374. http://dx.doi.org/10.1108/IJCCSM-02-2021-0020
http://dx.doi.org/10.1108/IJCCSM-02-2021... ).

These efforts demonstrate the industry’s commitment to addressing environmental challenges and promoting sustainable practices. In a competitive market it is necessary to carry out such actions to measure sustainable performance. The sustainable performance of organizations can be measured with different techniques and approaches. Multiple criteria decision making is an important technique that presents a systematic approach to help decision-makers in this field (Stojčić et al., 2019Stojčić, M., Zavadskas, E., Pamučar, D., Stević, Ž., & Mardani, A. (2019). Application of MCDM methods in sustainability engineering: a literature review 2008-2018. Symmetry, 1(3), 350. http://dx.doi.org/10.3390/sym11030350
http://dx.doi.org/10.3390/sym11030350... ). An example of multi-criteria decision methodology is TOPSIS, and with this technique it is possible to eliminate subjectivity in the analysis and provide a more objective and accurate evaluation of the sustainable performance of steel companies (Azimifard et al., 2018Azimifard, A., Moosavirad, S. H., & Ariafar, S. (2018). Selecting sustainable supplier countries for Iran’s steel industry at three levels by using AHP and TOPSIS methods. Resources Policy, 57, 30-44. http://dx.doi.org/10.1016/j.resourpol.2018.01.002.
http://dx.doi.org/10.1016/j.resourpol.20... ).

2.2 The TOPSIS method

The Technique Method to evaluate the Performance of Alternatives through similarity with the ideal solution (TOPSIS) was developed by Hwang & Yoon (1981)Hwang, C.-L., & Yoon, K. (1981). Multiple attribute decision making. Berlin, Heidelberg: Springer Berlin Heidelberg. http://dx.doi.org/10.1007/978-3-642-48318-9.
http://dx.doi.org/10.1007/978-3-642-4831... . In this method, the Decision Matrix is composed of alternatives and criteria, according to Equation 1.

A = [\begin{matrix} x_{11} & \dots & x_{1 n} \\ ⋮ & ⋱ & ⋮ \\ x_{m 1} & \dots & x_{m n} \end{matrix}], where i = 1, \dots, m; j = 1, \dots, n

(1)

The alternatives A₁, A₂, ... A_m are viable alternatives and C₁, C₂, ... C_m are the respective criteria. Also, in Matrix A, x_ij indicates the performance of the Alternative A_ij according to C_j (criterion j). Moreover, according to Hwang & Yoon (1981)Hwang, C.-L., & Yoon, K. (1981). Multiple attribute decision making. Berlin, Heidelberg: Springer Berlin Heidelberg. http://dx.doi.org/10.1007/978-3-642-48318-9.
http://dx.doi.org/10.1007/978-3-642-4831... , considering that Matrix A has several dimensions (unit of measurement), it is necessary to normalize it, that is, transform all x_ij values into dimensionless values that allow the comparison. As a first step to construct the normalized decision matrix, Equations 2 and 3 (Behzadian et al., 2012Behzadian, M., Khanmohammadi Otaghsara, S., Yazdani, M., & Ignatius, J. (2012). A state-of the-art survey of TOPSIS applications. Expert Systems with Applications, 39(17), 13051-13069. http://dx.doi.org/10.1016/j.eswa.2012.05.056.
http://dx.doi.org/10.1016/j.eswa.2012.05... ) are used.

r_{i j} = \frac{x_{i j}}{\sqrt{(\sum x_{i j)}^{2}}}, with i = 1, \dots, m and j = 1, \dots, n

(2)

V_{i j} = w_{j} \times r_{i j}, where w_{j} is the weight for each criterion j

(3)

For the calculation of weights for each criterion, TOPSIS uses an objective method based on entropy (Pegden et al., 1995Pegden, C. D., Shannon, R. E., & Sadowski, R. P. (1995). Introduction to simulation using SIMAN. New York: McGraw-Hill.). Entropy, in turn, aims to describe the amount of information of the decision matrix. However, as it will be described later, the weights will be calculated using the Gaussian AHP method.

Continuing the characteristic mathematical model of TOPSIS (Pegden et al., 1995Pegden, C. D., Shannon, R. E., & Sadowski, R. P. (1995). Introduction to simulation using SIMAN. New York: McGraw-Hill.), the ideal solutions are calculated according to Equations 4 and 5.

A^{+} = (v_{1}^{+}, \dots, v_{m}^{+}), in which v_{j}^{+} = {m a x (v_{i j}) i f j \in J_{1}; m i n (v_{i j}), i f j \in J_{2}}

(4)

A^{-} = (v_{1}^{-}, \dots, v_{m}^{-}), in which v_{j}^{-} = {m i n (v_{i j}) i f j \in J_{1}; m a x (v_{i j}), i f j \in J_{2}}

(5)

Where A⁺ are the ideal positive solutions and A^- are the ideal negative solutions, with J₁ and J₂ being, respectively, the best option and the worst option for the established alternatives.

The next step is to calculate Euclidean distances between A⁺ and A^-through Equations 6 and 7.

d^{+} = \sqrt{\sum_{j = 1}^{n} w_{j} (d_{i j}^{+}) ²}, with d_{i j}^{+} = p_{j}^{+} - p_{i j}, being i = 1, \dots, m

(6)

d^{-} = \sqrt{\sum_{j = 1}^{n} w_{j} (d_{i j}^{-}) ²}, with d_{i j}^{-} = p_{j}^{-} - p_{i j}, being i = 1, \dots, m

(7)

Calculated the distances, the next step is to calculate the relative proximity x_i for Each A_i with respect to the ideal solution positive A⁺, according to Equation 8.

ξ_{i} = \frac{d_{i}^{-}}{d_{i}^{+} + d_{i}^{-}}

(8)

Finally, through relative proximity, the alternatives are classified (ranked). With this, the best alternatives are those that have the highest value of x_i and, thus they should be chosen and ordered from the best to the worst performance.

2.3 The Gaussian AHP method

The Analytic Hierarchy Process (AHP) method was developed in the 70 by Saaty (1980)Saaty, T. L. (1980). The Analytic Hierarchy Process (AHP): Planning, Priority Setting, Resource Allocation. New York: McGraw-Hill International Book Co. and its objective is to analyze the criteria through the opinion and feelings of experts, considering the comparison peer to peer. In this comparison, values of judgment are used to represent a scale (Souza et al., 2023Souza, M. M., Oliveira, A. L. R., & Souza, M. F. (2023). Location of agricultural warehouses based on spatial multicriteria analysis. Revista de Economia e Sociologia Rural, 62(1), e268622. http://dx.doi.org/10.1590/1806-9479.2022.268622
http://dx.doi.org/10.1590/1806-9479.2022... ) and this is done through the fundamental Saaty scale, where the criteria receive the value of 1, considered equally important, to the value of 9, for extremely important (Paz et al., 2022Paz, T. D. S. R., Santos, M., & Gomes, C. F. S. (2022). Performance sustentável das empresas do setor de saúde: análise a partir da abordagem VFT e dos métodos AHP-Gaussiano e WASPAS. In XLII Encontro Nacional de Engenharia de Produção (pp. 1-12). Foz do Iguaçu: ENEGEP. http://dx.doi.org/10.14488/ENEGEP2022_TN_ST_390_1938_45066.).

Thus, the AHP is a method that synthesizes knowledge, experience and point of view of the specialist (Souza et al., 2023Souza, M. M., Oliveira, A. L. R., & Souza, M. F. (2023). Location of agricultural warehouses based on spatial multicriteria analysis. Revista de Economia e Sociologia Rural, 62(1), e268622. http://dx.doi.org/10.1590/1806-9479.2022.268622
http://dx.doi.org/10.1590/1806-9479.2022... ), through peer comparisons, where the priorities evaluated capture subjective and objective measures that demonstrate the intensity of one domain from one alternative over another (Saaty & Vargas, 2012 apud Souza et al., 2023Souza, M. M., Oliveira, A. L. R., & Souza, M. F. (2023). Location of agricultural warehouses based on spatial multicriteria analysis. Revista de Economia e Sociologia Rural, 62(1), e268622. http://dx.doi.org/10.1590/1806-9479.2022.268622
http://dx.doi.org/10.1590/1806-9479.2022... ). Thus, it is evident that the AHP method requires a cognitive effort from experts to analyze the degree of importance of criteria (Paz et al., 2022Paz, T. D. S. R., Santos, M., & Gomes, C. F. S. (2022). Performance sustentável das empresas do setor de saúde: análise a partir da abordagem VFT e dos métodos AHP-Gaussiano e WASPAS. In XLII Encontro Nacional de Engenharia de Produção (pp. 1-12). Foz do Iguaçu: ENEGEP. http://dx.doi.org/10.14488/ENEGEP2022_TN_ST_390_1938_45066.).

To avoid the use of the expert “resource”, the AHP-Gaussian method emerged, whose main characteristic is to obtain the weights of the criteria from the decision matrix by means of quantitative criteria. Thus, the peer-to-peer evaluation of the degree of importance of the criteria will no longer be carried out by specialists used in the traditional AHP method, being the weights of the criteria obtained through the decision matrix (Santos & Costa, 2021Santos, M., & Costa, I. P. (2021). Multicriteria decision-making in the selection of warships: a new approach to the ahp method. International Journal of the Analytic Hierarchy Process, 13(1), 147-169. http://dx.doi.org/10.13033/ijahp.v13i1.833
http://dx.doi.org/10.13033/ijahp.v13i1.8... ).

Thus, according to Santos & Costa (2021)Santos, M., & Costa, I. P. (2021). Multicriteria decision-making in the selection of warships: a new approach to the ahp method. International Journal of the Analytic Hierarchy Process, 13(1), 147-169. http://dx.doi.org/10.13033/ijahp.v13i1.833
http://dx.doi.org/10.13033/ijahp.v13i1.8... , for the calculation of weights (Gaussian factor), the sequence of Figure 1 should be respected:

Figure 1
Sequence for calculating the Gaussian Factor (adapted from Santos & Costa (2021)Santos, M., & Costa, I. P. (2021). Multicriteria decision-making in the selection of warships: a new approach to the ahp method. International Journal of the Analytic Hierarchy Process, 13(1), 147-169. http://dx.doi.org/10.13033/ijahp.v13i1.833
http://dx.doi.org/10.13033/ijahp.v13i1.8... .

Turning the steps into equations, the first step will be to establish the Normalized Decision Matrix. As seen before, this will be done through Equations 1 to 3. The other stages can then be represented mathematically according to Equations 9, 10 and 11.

{y_{i} = a v e r a g e}_{a l t e r n . i n w h i c h c r i t e r i o n} = \frac{\sum a l t e r n a t i v e s o f e a c h c r i t e r i o n}{n u m b e r o f a l t e r n a t i v e s}, w h e r e i = 1, \dots, m

(9)

σ_{i} = \sqrt{\frac{\sum_{i = 1}^{n} {(x_{i} - y_{i})}^{2}}{n - 1}}

(10)

G a u s s i a n F a c t o r ({G F}_{i}) = \frac{σ_{i}}{y_{i}}

(11)

3 Materials and methods

The methodology adopted in this research focused on a quantitative approach to evaluate the sustainable performance of the five largest steel mills in Brazil. The collection of information was carried out through documentary research, using data from statistical yearbook, and sustainability reports aligned to the GRI standard to obtain the criteria for analysis.

The population considered in the analysis covered the main steel companies operating in Brazil and the sample was selected based on the representativeness of these organizations in terms of crude steel production. The five companies chosen, classified in terms of decreasing production in 2022, were responsible for 82.26% of the national production, standing out as representative in the sector (according to Instituto Aço Brasil). Table 1 shows the total volume produced by company.

Dimension	Criterion	Measures	Unit
Economic	CE1	EBITDA	R$ (BILLION)
	CE2	Net Revenue	R$ (BILLION)
	CE3	Net Profit	R$ (BILLION)
	CE4	Steel Sale Volume	TON (MILLION)
Social	CS1	Frequency rate of accidents with loss of time	%
	CS2	Number of direct jobs generated	THOUSAND
	CS3	Number of women employed	THOUSAND
	CS4	Investment in social	R$ (MILLION)
Environmental	CA1	Total direct energy consumption	GJ (MILLION)
	CA2	Direct and indirect emissions of greenhouse gases	tCO2 (MILLION)
	CA3	Water consumption	THOUSAND MEGALITERS

2019	CE1	CE2	CE3	CE4	CS1	CS2	CS3	CS4	CA1	CA2	CA3
S1	4.006	32.455	1.230	10.000	0.360	16.594	1.778	22.697	209.143	15.809	410.820
S2	7.251	30.064	2.245	5.100	3.010	24.869	3.433	30.730	103.982	11.180	108.435
S3	5.710	39.640	1.300	12.090	5.830	17.276	2.213	1.770	151.202	13.839	80.938
S4	1.973	14.949	0.377	4.105	1.260	15.852	1.131	13.500	65.820	7.790	62.480
S5	6.019	40.212	2.485	12.511	0.840	19.863	1.589	26.038	276.500	18.700	198.600

2020	CE1	CE2	CE3	CE4	CS1	CS2	CS3	CS4	CA1	CA2	CA3
S1	5.083	33.070	1.235	9.300	0.180	19.915	2.048	28.278	187.765	13.414	351.123
S2	11.500	25.436	4.290	4.651	2.460	23.577	3.380	52.400	100.500	11.301	99.396
S3	7.690	43.815	2.400	11.461	0.860	17.122	2.294	3.321	146.365	13.019	51.429
S4	3.194	16.088	1.292	3.723	1.160	12.109	0.982	23.955	69.100	6.470	58.840
S5	7.860	45.038	4.475	11.360	0.820	15.059	1.355	57.229	249.909	17.300	178.600

2021	CE1	CE2	CE3	CE4	CS1	CS2	CS3	CS4	CA1	CA2	CA3
S1	20.189	69.002	12.841	12.500	0.195	16.816	2.051	133.170	217.743	17.158	384.016
S2	22.000	47.900	13.600	4.603	1.968	26.161	4.425	105.000	112.333	13.770	98.476
S3	23.222	78.345	15.600	12.722	0.900	21.695	3.710	12.698	152.011	11.970	49.915
S4	12.830	33.737	10.060	4.765	2.130	14.125	1.283	75.400	76.270	7.312	65.120
S5	31.630	86.809	23.561	12.065	0.790	14.927	1.493	93.334	288.354	19.200	157.000

2019	CE1	CE2	CE3	CE4	CS1	CS2	CS3	CS4	CA1	CA2	CA3
S1	0.337	0.443	0.322	0.474	0.053	0.387	0.366	0.471	0.526	0.506	0.856
S2	0.610	0.410	0.588	0.242	0.446	0.580	0.706	0.638	0.261	0.358	0.226
S3	0.480	0.541	0.341	0.573	0.865	0.403	0.455	0.037	0.380	0.443	0.169
S4	0.166	0.204	0.099	0.194	0.187	0.370	0.233	0.280	0.165	0.249	0.130
S5	0.506	0.549	0.651	0.593	0.125	0.463	0.327	0.540	0.695	0.598	0.414

2020	CE1	CE2	CE3	CE4	CS1	CS2	CS3	CS4	CA1	CA2	CA3
S1	0.299	0.429	0.179	0.476	0.061	0.495	0.421	0.329	0.513	0.469	0.849
S2	0.676	0.330	0.623	0.238	0.827	0.586	0.695	0.609	0.275	0.395	0.240
S3	0.452	0.568	0.349	0.586	0.289	0.426	0.471	0.039	0.400	0.455	0.124
S4	0.188	0.209	0.188	0.190	0.390	0.301	0.202	0.278	0.189	0.226	0.142
S5	0.462	0.584	0.650	0.581	0.276	0.374	0.279	0.665	0.683	0.605	0.432

2021	CE1	CE2	CE3	CE4	CS1	CS2	CS3	CS4	CA1	CA2	CA3
S1	0.396	0.467	0.363	0.555	0.062	0.390	0.319	0.640	0.525	0.530	0.884
S2	0.432	0.324	0.385	0.204	0.626	0.607	0.688	0.504	0.271	0.425	0.227
S3	0.456	0.530	0.441	0.565	0.286	0.503	0.576	0.061	0.366	0.370	0.115
S4	0.252	0.228	0.285	0.212	0.678	0.327	0.199	0.362	0.184	0.226	0.150
S5	0.621	0.587	0.667	0.536	0.251	0.346	0.232	0.448	0.695	0.593	0.362

Gaussian	CE1	CE2	CE3	CE4	CS1	CS2	CS3	CS4	CA1	CA2	CA3
Mean	0.420	0.429	0.400	0.415	0.335	0.441	0.417	0.393	0.406	0.431	0.359
Standard Deviation	0.172	0.140	0.223	0.186	0.331	0.086	0.180	0.238	0.211	0.134	0.298
Gaussian Factor	0.410	0.325	0.557	0.449	0.988	0.194	0.432	0.606	0.519	0.312	0.832
Normalized Gaussian Factor	0.073	0.058	0.099	0.080	0.176	0.035	0.077	0.108	0.092	0.055	0.148

Gaussian	CE1	CE2	CE3	CE4	CS1	CS2	CS3	CS4	CA1	CA2	CA3
Mean	0.431	0.427	0.428	0.414	0.381	0.435	0.403	0.403	0.408	0.429	0.348
Standard Deviation	0.132	0.148	0.145	0.189	0.262	0.118	0.217	0.216	0.204	0.143	0.315
Gaussian Factor	0.307	0.347	0.338	0.455	0.689	0.271	0.540	0.536	0.500	0.334	0.905
Normalized Gaussian Factor	0.059	0.066	0.065	0.087	0.132	0.052	0.103	0.103	0.096	0.064	0.173

Gaussian	CE1	CE2	CE3	CE4	CS1	CS2	CS3	CS4	CA1	CA2	CA3
Mean	0.415	0.424	0.398	0.414	0.369	0.436	0.413	0.384	0.412	0.430	0.357
Standard Deviation	0.185	0.159	0.228	0.189	0.283	0.110	0.191	0.256	0.195	0.137	0.301
Gaussian Factor	0.445	0.376	0.574	0.455	0.768	0.251	0.461	0.668	0.474	0.319	0.841
Normalized Gaussian Factor	0.079	0.067	0.102	0.081	0.136	0.045	0.082	0.119	0.084	0.057	0.149

Steel mill	Gross Steel Production (10³t)
S1	10,694
S2	6,496
S3	4,424
S4	3,773
S5	2,655

Impacts	(+)	(+)	(+)	(+)	(-)	(+)	(+)	(+)	(-)	(-)	(-)
2020	CE1	CE2	CE3	CE4	CS1	CS2	CS3	CS4	CA1	CA2	CA3
PIS	0.053	0.039	0.066	0.047	0.008	0.026	0.057	0.079	0.016	0.013	0.019
NIS	0.015	0.014	0.018	0.015	0.113	0.013	0.017	0.005	0.057	0.034	0.127

Impacts	(+)	(+)	(+)	(+)	(-)	(+)	(+)	(+)	(-)	(-)	(-)
2019	CE1	CE2	CE3	CE4	CS1	CS2	CS3	CS4	CA1	CA2	CA3
PIS	0.044	0.032	0.065	0.047	0.009	0.020	0.054	0.069	0.015	0.014	0.019
NIS	0.012	0.012	0.010	0.016	0.152	0.013	0.018	0.004	0.064	0.033	0.127

Impacts	(+)	(+)	(+)	(+)	(-)	(+)	(+)	(+)	(-)	(-)	(-)
2021	CE1	CE2	CE3	CE4	CS1	CS2	CS3	CS4	CA1	CA2	CA3
PIS	0.036	0.039	0.043	0.049	0.008	0.031	0.071	0.066	0.018	0.014	0.020
NIS	0.015	0.015	0.018	0.018	0.089	0.017	0.021	0.006	0.067	0.038	0.153

Company	CE1	CE2	CE3	CE4	CS1	CS2	CS3	CS4	CA1	CA2	CA3	SUM
S1	0.00040	0.00004	0.00106	0.00009	0.00000	0.00004	0.00068	0.00032	0.00111	0.00020	0.01151	0.01546
S2	0.00000	0.00006	0.00004	0.00078	0.00477	0.00000	0.00000	0.00000	0.00008	0.00004	0.00020	0.00597
S3	0.00009	0.00000	0.00095	0.00000	0.02030	0.00004	0.00037	0.00420	0.00039	0.00012	0.00003	0.02649
S4	0.00105	0.00040	0.00300	0.00101	0.00055	0.00005	0.00132	0.00149	0.00000	0.00000	0.00000	0.00886
S5	0.00006	0.00000	0.00000	0.00000	0.00016	0.00002	0.00085	0.00011	0.00239	0.00037	0.00176	0.00571

Company	CE1	CE2	CE3	CE4	CS1	CS2	CS3	CS4	CA1	CA2	CA3	SUM
S1	0.00016	0.00019	0.00049	0.00050	0.02030	0.00000	0.00010	0.00219	0.00024	0.00003	0.00000	0.02420
S2	0.00105	0.00014	0.00235	0.00001	0.00540	0.00005	0.00132	0.00420	0.00160	0.00018	0.00868	0.02498
S3	0.00053	0.00038	0.00057	0.00091	0.00000	0.00000	0.00029	0.00000	0.00085	0.00007	0.01033	0.01393
S4	0.00000	0.00000	0.00000	0.00000	0.01417	0.00000	0.00000	0.00069	0.00239	0.00037	0.01151	0.02914
S5	0.00062	0.00040	0.00300	0.00101	0.01690	0.00001	0.00005	0.00295	0.00000	0.00000	0.00427	0.02920

Company	CE1	CE2	CE3	CE4	CS1	CS2	CS3	CS4	CA1	CA2	CA3	SUM
S1	0.00089	0.00011	0.00230	0.00008	0.00000	0.00002	0.00050	0.00159	0.00074	0.00019	0.01169	0.01811
S2	0.00000	0.00029	0.00001	0.00079	0.01093	0.00000	0.00000	0.00004	0.00005	0.00009	0.00030	0.01251
S3	0.00031	0.00000	0.00094	0.00000	0.00097	0.00005	0.00033	0.00552	0.00032	0.00017	0.00000	0.00862
S4	0.00149	0.00063	0.00222	0.00102	0.00202	0.00016	0.00163	0.00210	0.00000	0.00000	0.00001	0.01128
S5	0.00029	0.00000	0.00000	0.00000	0.00086	0.00009	0.00116	0.00000	0.00173	0.00046	0.00210	0.00669

Company	CE1	CE2	CE3	CE4	CS1	CS2	CS3	CS4	CA1	CA2	CA3	SUM
S1	0.00008	0.00022	0.00000	0.00053	0.01093	0.00007	0.00032	0.00118	0.00020	0.00006	0.00000	0.01360
S2	0.00149	0.00007	0.00205	0.00001	0.00000	0.00016	0.00163	0.00457	0.00118	0.00014	0.00824	0.01954
S3	0.00044	0.00058	0.00030	0.00102	0.00538	0.00003	0.00049	0.00000	0.00057	0.00007	0.01169	0.02056
S4	0.00000	0.00000	0.00000	0.00000	0.00355	0.00000	0.00000	0.00081	0.00173	0.00046	0.01111	0.01766
S5	0.00047	0.00063	0.00230	0.00100	0.00566	0.00001	0.00004	0.00552	0.00000	0.00000	0.00387	0.01949

Company	CE1	CE2	CE3	CE4	CS1	CS2	CS3	CS4	CA1	CA2	CA3	SUM
S1	0.00007	0.00025	0.00003	0.00093	0.00660	0.00001	0.00015	0.00353	0.00027	0.00002	0.00000	0.01186
S2	0.00011	0.00004	0.00004	0.00000	0.00005	0.00021	0.00254	0.00207	0.00165	0.00011	0.01300	0.01983
S3	0.00014	0.00040	0.00010	0.00099	0.00267	0.00008	0.00152	0.00000	0.00099	0.00020	0.01779	0.02489
S4	0.00000	0.00000	0.00000	0.00000	0.00000	0.00000	0.00000	0.00096	0.00240	0.00055	0.01621	0.02012
S5	0.00047	0.00057	0.00061	0.00083	0.00317	0.00000	0.00001	0.00158	0.00000	0.00000	0.00821	0.01546

Company	D⁺ (2019)	D^- (2019)	D⁺ (2020)	D^- (2020)	D⁺ (2021)	D^- (2021)
S1	0.12434	0.15557	0.13456	0.11661	0.14642	0.10892
S2	0.07725	0.15806	0.11183	0.13980	0.08996	0.14082
S3	0.16275	0.11803	0.09283	0.14338	0.07267	0.15777
S4	0.09412	0.17071	0.10621	0.13291	0.11314	0.14183
S5	0.07558	0.17088	0.08178	0.13961	0.09050	0.12433

Company	R2019	R2020	R2021
S1	0.55580	0.46427	0.42656
S2	0.67171	0.55557	0.61020
S3	0.42035	0.60701	0.68464
S4	0.64459	0.55583	0.55626
S5	0.69334	0.63060	0.57874

Brasil

Brasil

Assessment of sustainable performance of the top five Brazilian steel industries using the TOPSIS technique with Gaussian AHP

Avaliação do desempenho sustentável das cinco maiores siderúrgicas brasileiras utilizando a técnica TOPSIS com AHP-Gaussiano

Abstract

Resumo

1 Introduction

2 Theoretical framework

2.1 Sustainable development

2.2 The TOPSIS method

2.3 The Gaussian AHP method

3 Materials and methods

4 Analysis and discussion of results

5 Conclusion

Statement on Data Availability

Acknowledgements

References

Publication Dates

History