Industry Comparison

You are viewing information about the following Industries:

  • Iron & Steel Producers The Iron & Steel Producers industry primarily consists of entities producing iron and steel in mills and foundries. The steel producers segment produces iron and steel products from its own mills. These products include flat-rolled sheets, tin plates, pipes, tubes, and products made of stainless steel, titanium and high alloy steels. Iron and steel foundries, which cast various products, typically purchase iron and steel from other entities. The industry also includes metal service centres and other metal merchant wholesalers, which distribute, import or export ferrous products. Though entities are developing alternative processes, steel production primarily relies on two primary methods: the basic oxygen furnace (BOF), which uses iron ore as an input, and the electric arc furnace (EAF), which uses scrap steel. Many entities in the industry operate on an international scale. Note: With a few exceptions, most entities do not mine their own ore to manufacture steel and iron products. There exists a separate standard for the Metals & Mining (EM-MM) industry.
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  • Wind Technology & Project Developers Wind Technology & Project Developers manufacture wind turbines, blades, towers and other components of wind power systems. Entities that develop, build and manage wind energy projects also are included within this industry scope. Manufacturers also may offer post-sale maintenance and support services. Turbines may be installed onshore or offshore, which can create differences in wind-generating capacity and project development challenges for each type of installation. Most major wind technology entities operate globally.
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Relevant Issues for both Industries (9 of 26)

Why are some issues greyed out? The SASB Standards vary by industry based on the different sustainability-related risks and opportunities within an industry. The issues in grey were not identified during the standard-setting process as the most likely to be useful to investors, so they are not included in the Standard. Over time, as the ISSB continues to receive market feedback, some issues may be added or removed from the Standard. Each company determines which sustainability-related risks and opportunities are relevant to its business. The Standard is designed for the typical company in an industry, but individual companies may choose to report on different sustainability-related risks and opportunities based on their unique business model.

Disclosure Topics

What is the relationship between General Issue Category and Disclosure Topics? The General Issue Category is an industry-agnostic version of the Disclosure Topics that appear in each SASB Standard. Disclosure topics represent the industry-specific impacts of General Issue Categories. The industry-specific Disclosure Topics ensure each SASB Standard is tailored to the industry, while the General Issue Categories enable comparability across industries. For example, Health & Nutrition is a disclosure topic in the Non-Alcoholic Beverages industry, representing an industry-specific measure of the general issue of Customer Welfare. The issue of Customer Welfare, however, manifests as the Counterfeit Drugs disclosure topic in the Biotechnology & Pharmaceuticals industry.
  • Iron & Steel Producers Remove
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    • GHG Emissions The category addresses direct (Scope 1) greenhouse gas (GHG) emissions that a company generates through its operations. This includes GHG emissions from stationary (e.g., factories, power plants) and mobile sources (e.g., trucks, delivery vehicles, planes), whether a result of combustion of fuel or non-combusted direct releases during activities such as natural resource extraction, power generation, land use, or biogenic processes. The category further includes management of regulatory risks, environmental compliance, and reputational risks and opportunities, as they related to direct GHG emissions. The seven GHGs covered under the Kyoto Protocol are included within the category—carbon dioxide (CO2), methane (CH4), nitrous oxide (N2O), hydrofluorocarbons (HFCs), perfluorocarbons (PFCs), sulfur hexafluoride (SF6), and nitrogen trifluoride (NF3).
      • Greenhouse Gas Emissions Iron and steel production generates significant direct greenhouse gas (GHG) emissions, primarily carbon dioxide and methane, from production processes and on-site fuel combustion. Although technological improvements have reduced the GHG emissions per tonne of steel produced, steel production remains carbon-intensive compared to other industries. Regulatory efforts to reduce GHG emissions in response to the risks posed by climate change may result in additional regulatory compliance costs and risks for iron and steel entities because of climate change mitigation policies. Entities can achieve operational efficiencies through the cost-effective reduction of GHG emissions. Capturing such efficiencies can mitigate the potential financial effects of increased fuel costs from regulations that limit—or put a price on—GHG emissions.
    • Air Quality The category addresses management of air quality impacts resulting from stationary (e.g., factories, power plants) and mobile sources (e.g., trucks, delivery vehicles, planes) as well as industrial emissions. Relevant airborne pollutants include, but are not limited to, oxides of nitrogen (NOx), oxides of sulfur (SOx), volatile organic compounds (VOCs), heavy metals, particulate matter, and chlorofluorocarbons. The category does not include GHG emissions, which are addressed in a separate category.
      • Air Quality Iron and steel production typically generates criteria air pollutants, volatile organic compounds (VOCs) and hazardous air pollutants, which can have significant localised public health impacts. Of particular concern are sulphur oxides, nitrogen dioxide, lead, carbon monoxide and manganese, as well as particles such as soot and dust, released during production. Technological innovation and continuous improvements in steel-making processes have reduced air pollutants significantly from the Iron & Steel Producers industry. However, air pollutants remain a concern because of increased regulatory and public concern about air pollution, as well as expansion of steel production in emerging markets. In emerging markets, regulatory efforts to curb air pollution may constrain iron and steel production. Active management of facility emissions through industry best practices implementation across global operations can facilitate the transition to sustainable steel production, reducing costs and potentially enhancing operational efficiency.
    • Energy Management The category addresses environmental impacts associated with energy consumption. It addresses the company’s management of energy in manufacturing and/or for provision of products and services derived from utility providers (grid energy) not owned or controlled by the company. More specifically, it includes management of energy efficiency and intensity, energy mix, as well as grid reliance. Upstream (e.g., suppliers) and downstream (e.g., product use) energy use is not included in the scope.
      • Energy Management The production of steel requires significant energy, sourced primarily from the direct fossil fuel combustion as well as energy purchased from the grid. Energy-intense production has implications for climate change, and electricity purchases from the grid can result in indirect Scope 2 emissions. The choice between various production processes—electric arc furnaces and integrated basic oxygen furnaces—can influence whether an entity uses fossil fuels or purchases electricity. This decision, together with the choice between using coal versus natural gas or on-site versus grid-sourced electricity, may influence both the costs and reliability of energy supply. Affordable, easily accessible and reliable energy is an important industry competitive factor. Energy costs account for a substantial portion of iron and steel manufacturing costs. How an iron and steel entity manages its energy efficiency, its reliance on various types of energy and associated sustainability risks, and its ability to access alternative sources of energy can influence its profitability.
    • Water & Wastewater Management The category addresses a company’s water use, water consumption, wastewater generation, and other impacts of operations on water resources, which may be influenced by regional differences in the availability and quality of and competition for water resources. More specifically, it addresses management strategies including, but not limited to, water efficiency, intensity, and recycling. Lastly, the category also addresses management of wastewater treatment and discharge, including groundwater and aquifer pollution.
      • Water Management Steel production requires substantial volumes of water. Entities face increasing operational, regulatory and reputational risks associated with water scarcity, costs of water acquisition, regulations on effluents or amount of water used, and competition with local communities and other industries for limited water resources. These risks are particularly likely to affect regions where water is scarce, resulting in water availability constraints and price volatility. Entities unable to secure a stable water supply could face production disruptions, while rising water prices could directly increase production costs. Consequently, entities adopting technologies and processes to decrease reduce water consumption may reduce operating risks and costs by mitigating the operational impacts of regulatory changes, water supply shortages and community-related disruptions.
    • Waste & Hazardous Materials Management The category addresses environmental issues associated with hazardous and non-hazardous waste generated by companies. It addresses a company’s management of solid wastes in manufacturing, agriculture, and other industrial processes. It covers treatment, handling, storage, disposal, and regulatory compliance. The category does not cover emissions to air or wastewater nor does it cover waste from end-of-life of products, which are addressed in separate categories.
      • Waste Management Although waste reclamation rates in steel production are high, the industry generates significant quantities of hazardous wastes. Slag, dusts and sludges constitute the three main industry waste types. These by-products often are recycled internally or sold to other industries. However, process wastes such as electric arc furnace dust, which may be regulated as a hazardous material because of its heavy metal content, can have significant environmental and human health impacts, present a regulatory risk, and result in additional operating costs for entities. Risks related to the long-term impacts of waste disposal may result in significant costs, including those associated with monitoring and managing contaminated off-site disposal properties, for which jurisdictional authorities may hold iron and steel producers responsible for remediation and restoration activities. Entities that reduce waste streams, hazardous waste streams in particular, and recycle or sell non-hazardous by-products, could mitigate regulatory risks and reduce costs while increasing revenues.
    • Employee Health & Safety The category addresses a company’s ability to create and maintain a safe and healthy workplace environment that is free of injuries, fatalities, and illness (both chronic and acute). It is traditionally accomplished through implementing safety management plans, developing training requirements for employees and contractors, and conducting regular audits of their own practices as well as those of their subcontractors. The category further captures how companies ensure physical and mental health of workforce through technology, training, corporate culture, regulatory compliance, monitoring and testing, and personal protective equipment.
      • Workforce Health & Safety Iron and steel production processes can present significant risks to employees and contractors working in iron and steel plants. Given the high temperatures and heavy machinery involved, worker injuries and fatalities are a matter of serious concern to iron and steel producers. Given the hazardous work environment, the industry has relatively high fatality rates requiring a strong safety culture and comprehensive health and safety policies. Although accident rates in the industry are in decline, worker injuries and fatalities can result in regulatory penalties, negative publicity, low worker morale and productivity, and increased healthcare and compensation costs.
    • Product Design & Lifecycle Management The category addresses incorporation of environmental, social, and governance (ESG) considerations in characteristics of products and services provided or sold by the company. It includes, but is not limited to, managing the lifecycle impacts of products and services, such as those related to packaging, distribution, use-phase resource intensity, and other environmental and social externalities that may occur during their use-phase or at the end of life. The category captures a company’s ability to address customer and societal demand for more sustainable products and services as well as to meet evolving environmental and social regulation. It does not address direct environmental or social impacts of the company’s operations nor does it address health and safety risks to consumers from product use, which are covered in other categories.
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    • Supply Chain Management The category addresses management of environmental, social, and governance (ESG) risks within a company’s supply chain. It addresses issues associated with environmental and social externalities created by suppliers through their operational activities. Such issues include, but are not limited to, environmental responsibility, human rights, labour practices, and ethics and corruption. Management may involve screening, selection, monitoring, and engagement with suppliers on their environmental and social impacts. The category does not address the impacts of external factors – such as climate change and other environmental and social factors – on suppliers’ operations and/or on the availability and pricing of key resources, which is covered in a separate category.
      • Supply Chain Management Iron ore and coal are critical raw material inputs to the steel production process. Iron ore mining and coal production are resource-intensive processes. Mineral extraction often has substantial environmental and social impacts adversely affecting local communities, workers and ecosystems. Community protests, legal or regulatory action, or increased regulatory compliance costs or penalties can disrupt mining operations. Iron and steel entities could face supply disruptions as a result, or in some cases, also may be subject to regulatory penalties associated with the environmental or social impact of the mining entity supplier. Minimising such risks through appropriate supplier screening, monitoring and engagement, iron and steel producers may manage their direct critical raw materials suppliers proactively to ensure they are not engaged in illegal or otherwise environmentally or socially damaging practices.
    • Materials Sourcing & Efficiency The category addresses issues related to the resilience of materials supply chains to impacts of climate change and other external environmental and social factors. It captures the impacts of such external factors on operational activity of suppliers, which can further affect availability and pricing of key resources. It addresses a company’s ability to manage these risks through product design, manufacturing, and end-of-life management, such as by using of recycled and renewable materials, reducing the use of key materials (dematerialization), maximizing resource efficiency in manufacturing, and making R&D investments in substitute materials. Additionally, companies can manage these issues by screening, selection, monitoring, and engagement with suppliers to ensure their resilience to external risks. It does not address issues associated with environmental and social externalities created by operational activity of individual suppliers, which is covered in a separate category.
      None
  • Wind Technology & Project Developers Remove
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    • GHG Emissions The category addresses direct (Scope 1) greenhouse gas (GHG) emissions that a company generates through its operations. This includes GHG emissions from stationary (e.g., factories, power plants) and mobile sources (e.g., trucks, delivery vehicles, planes), whether a result of combustion of fuel or non-combusted direct releases during activities such as natural resource extraction, power generation, land use, or biogenic processes. The category further includes management of regulatory risks, environmental compliance, and reputational risks and opportunities, as they related to direct GHG emissions. The seven GHGs covered under the Kyoto Protocol are included within the category—carbon dioxide (CO2), methane (CH4), nitrous oxide (N2O), hydrofluorocarbons (HFCs), perfluorocarbons (PFCs), sulfur hexafluoride (SF6), and nitrogen trifluoride (NF3).
      None
    • Air Quality The category addresses management of air quality impacts resulting from stationary (e.g., factories, power plants) and mobile sources (e.g., trucks, delivery vehicles, planes) as well as industrial emissions. Relevant airborne pollutants include, but are not limited to, oxides of nitrogen (NOx), oxides of sulfur (SOx), volatile organic compounds (VOCs), heavy metals, particulate matter, and chlorofluorocarbons. The category does not include GHG emissions, which are addressed in a separate category.
      None
    • Energy Management The category addresses environmental impacts associated with energy consumption. It addresses the company’s management of energy in manufacturing and/or for provision of products and services derived from utility providers (grid energy) not owned or controlled by the company. More specifically, it includes management of energy efficiency and intensity, energy mix, as well as grid reliance. Upstream (e.g., suppliers) and downstream (e.g., product use) energy use is not included in the scope.
      None
    • Water & Wastewater Management The category addresses a company’s water use, water consumption, wastewater generation, and other impacts of operations on water resources, which may be influenced by regional differences in the availability and quality of and competition for water resources. More specifically, it addresses management strategies including, but not limited to, water efficiency, intensity, and recycling. Lastly, the category also addresses management of wastewater treatment and discharge, including groundwater and aquifer pollution.
      None
    • Waste & Hazardous Materials Management The category addresses environmental issues associated with hazardous and non-hazardous waste generated by companies. It addresses a company’s management of solid wastes in manufacturing, agriculture, and other industrial processes. It covers treatment, handling, storage, disposal, and regulatory compliance. The category does not cover emissions to air or wastewater nor does it cover waste from end-of-life of products, which are addressed in separate categories.
      None
    • Employee Health & Safety The category addresses a company’s ability to create and maintain a safe and healthy workplace environment that is free of injuries, fatalities, and illness (both chronic and acute). It is traditionally accomplished through implementing safety management plans, developing training requirements for employees and contractors, and conducting regular audits of their own practices as well as those of their subcontractors. The category further captures how companies ensure physical and mental health of workforce through technology, training, corporate culture, regulatory compliance, monitoring and testing, and personal protective equipment.
      • Workforce Health & Safety Many wind turbine manufacturers offer operations and maintenance (O&M) services for wind farm owners or operators together with product sales. These activities may include installation, maintenance, monitoring and repairing turbine installations. The wind farm O&M segment maintains a high safety standard because the work is inherently hazardous. Hazards include physical hazards such as falls from heights and moving mechanical parts, as well as electrical hazards. The quality of O&M services therefore is critical for the safety of wind farm operations, with the potential to affect entity reputations and demand for products and services. Operational downtime and effects on wind farm insurance costs because of accidents may add to wind farm operating costs. Wind farm owners or developers therefore may consider turbine and service provider safety records in requests for tender. Entities that improve turbine and O&M safety may reduce operating costs and extraordinary expenses.
    • Product Design & Lifecycle Management The category addresses incorporation of environmental, social, and governance (ESG) considerations in characteristics of products and services provided or sold by the company. It includes, but is not limited to, managing the lifecycle impacts of products and services, such as those related to packaging, distribution, use-phase resource intensity, and other environmental and social externalities that may occur during their use-phase or at the end of life. The category captures a company’s ability to address customer and societal demand for more sustainable products and services as well as to meet evolving environmental and social regulation. It does not address direct environmental or social impacts of the company’s operations nor does it address health and safety risks to consumers from product use, which are covered in other categories.
      • Ecological Impacts of Project Development Wind farm development involves siting, land acquisition, permitting and engagement with local stakeholders to manage environmental and community impacts. Offshore developments may affect the marine ecosystem, and both on and offshore wind farms may have adverse effects on local animal populations, some of which may be endangered. Obtaining environmental and construction permits for projects may be delayed or prevented if regulators or community members have concerns about the ecological impacts of the development. Wind project approval directly affects equipment manufacturers through demand for turbines. Although manufacturers typically do not control the project approval process, research and development investments may minimise ecological impacts, resulting in long-term benefits. These measures could facilitate project approvals and give wind technology manufacturers a competitive advantage, potentially increasing their market share over time.
    • Supply Chain Management The category addresses management of environmental, social, and governance (ESG) risks within a company’s supply chain. It addresses issues associated with environmental and social externalities created by suppliers through their operational activities. Such issues include, but are not limited to, environmental responsibility, human rights, labour practices, and ethics and corruption. Management may involve screening, selection, monitoring, and engagement with suppliers on their environmental and social impacts. The category does not address the impacts of external factors – such as climate change and other environmental and social factors – on suppliers’ operations and/or on the availability and pricing of key resources, which is covered in a separate category.
      None
    • Materials Sourcing & Efficiency The category addresses issues related to the resilience of materials supply chains to impacts of climate change and other external environmental and social factors. It captures the impacts of such external factors on operational activity of suppliers, which can further affect availability and pricing of key resources. It addresses a company’s ability to manage these risks through product design, manufacturing, and end-of-life management, such as by using of recycled and renewable materials, reducing the use of key materials (dematerialization), maximizing resource efficiency in manufacturing, and making R&D investments in substitute materials. Additionally, companies can manage these issues by screening, selection, monitoring, and engagement with suppliers to ensure their resilience to external risks. It does not address issues associated with environmental and social externalities created by operational activity of individual suppliers, which is covered in a separate category.
      • Materials Sourcing Wind technology entities source materials from global supply chains for use in turbines, including critical materials, such as neodymium and dysprosium, and critical minerals including tantalum and tungsten. Materials sourcing risks result from a low substitution ratio, the concentration of deposits in a few countries, geopolitical considerations, and competition from other industries. Direct drive turbines, which increasingly are being used for reliability, may require significantly more critical materials than more traditional drive trains. Entities may minimise negative externalities and protect themselves from related input cost volatility and supply constraints by creating transparent supply chains, sourcing materials from reliable suppliers or regions that have minimal environmental or social risks associated with them, supporting research into alternative inputs, and reducing reliance on these materials.
      • Materials Efficiency The Wind Technology & Project Developers industry’s long-term success depends on producing energy at a comparatively lower cost than other energy sources. Steel and other materials purchases are one of the largest costs of turbines, and inputs such as steel have exhibited price volatility in the past. In recent years, wind turbines have grown in size, in terms of both the tower height and the swept area of the rotor, to improve energy output and increase the potential for wind energy production in more areas. To achieve this expansion cost-effectively, entities may employ innovative methods to increase turbine output while using materials more efficiently. Increased output and efficiency could influence entities’ competitiveness and market share, costs of production, and operational risks related to the supply and price volatility of raw materials, as well as the ability of the entity to scale.

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