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report:eth [2026/04/08 17:08] – [6.5 Liability] team4report:eth [2026/04/23 11:36] (current) – [6.2 Engineering Ethics] team4
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 ===== 6. Ethical and Deontological Concerns ===== ===== 6. Ethical and Deontological Concerns =====
  
-==== 6.1 Introduction ====  
-The deployment of technological solutions within natural and often fragile marine ecosystems involves significant ethical considerations. This chapter examines the deontological principles that have guided the decision-making process, with the aim of ensuring that the proposed intervention does not unintentionally harm the systems it is designed to protect. 
  
-Key considerations include the long-term lifecycle of materials, particularly in relation to preventing marine pollution and the accumulation of debris. In addition, the integrity and reliability of the environmental data collected are of central importance, as such data must accurately reflect ecosystem conditions. The ethical implications of material selection, including the use of reusable versus virgin resources, are also addressed.+==== 6.1 Introduction ==== 
  
-This chapter highlights the responsibility of engineers to ensure transparency and objectivity in reporting project outcomes. Providing accurate and unbiased information about the performance of the habitat is essential to avoid misleading claims and to prevent “greenwashing.” In this waythe project seeks to uphold principles of responsible engineering and contribute to genuine ecological stewardship.+This chapter outlines the ethical and deontological principles guiding the development of a smart artificial marine habitat. It focuses on ensuring environmental protectiondata integrity, and responsible engineering practices, while addressing key considerations such as sustainability, transparency, and long-term system reliability.
 ==== 6.2 Engineering Ethics ====  ==== 6.2 Engineering Ethics ==== 
-Engineering ethics play a critical role in the design and development of artificial marine habitats intended to support endangered fish species. Structures must be designed with a high degree of structural integrity, durability, and reliability to withstand harsh marine environments and maintain long-term functionality. Engineers have a responsibility to ensure that both the habitats and any associated monitoring systems are safe for marine organisms, installation personnel, and the surrounding environment. 
-Equally important is the need to minimize ecological disruption. Artificial habitats should be carefully designed to avoid damaging the seabed or interfering with existing ecosystems. Instead, their purpose should be to complement and enhance natural habitats, thereby promoting biodiversity and ecological balance. 
  
-Material selection is another key ethical consideration. Engineers must prioritize the use of non-toxicenvironmentally sustainable, and long-lasting materials. The production processes involved in creating these habitats should follow to principles of sustainability, ensuring that environmental impact is minimized throughout the lifecycle of the project.+Engineering ethics play an important role in the design and development of artificial marine habitats for endangered fish species. Engineers must ensure that structures are designed with sufficient strength, durability, and reliability to withstand harsh marine conditions such as saltwater exposure and wave forces [(QU2021)], [(FOLPP2013)]. This is essential to guarantee long-term functionality and safety. 
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 +Engineers also have a responsibility to ensure that both the habitat structures and monitoring systems do not pose risks to marine organisms, installation personnel, or the surrounding environment. Safety and reliability must be considered throughout the entire design process. 
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 +Another key ethical consideration is minimizing ecological disruptionArtificial habitats should not damage the seabed or negatively affect existing ecosystems. Instead, they should be designed to support and enhance natural habitats. Studies have shown that well-designed artificial reefs can increase biodiversity and improve marine ecosystem conditions [(SELLA2015)]. 
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 +Material selection is also important. Engineers should choose non-toxic and environmentally sustainable materials that are suitable for long-term use in marine environments. 
 + 
 +Transparency is an essential part of ethical engineering practice. Engineers must ensure that all collected data is accurate and reported honestly, regardless of the results. This supports scientific research and contributes to better decision-making in marine conservation.
  
-Transparency is an essential in ethical engineering practice. Engineers should ensure that all data collected through habitat monitoring systems is accurate, openly shared, and reported honestly regardless of whether the findings are positive or negative. Such transparency supports scientific collaboration and contributes to a deeper understanding of marine ecosystems, ultimately improving conservation strategies. 
-In conclusion, engineers have a fundamental ethical obligation to develop solutions that not only support the recovery of endangered fish species but also promote the long-term health and resilience of marine ecosystems for future generations. 
  
 ==== 6.3 Sales and Marketing Ethics ====  ==== 6.3 Sales and Marketing Ethics ==== 
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 +__//**HERNAN: I WILL CHECK THIS**//__
  
 The duty of safety and quality assurance requires that all underwater sensors and electrical components are designed and implemented in a manner that ensures they are safe for both users and marine life. This includes minimizing potential risks associated with system failures by incorporating reliable design solutions and protective measures that reduce the likelihood and impact of malfunctions. The duty of safety and quality assurance requires that all underwater sensors and electrical components are designed and implemented in a manner that ensures they are safe for both users and marine life. This includes minimizing potential risks associated with system failures by incorporating reliable design solutions and protective measures that reduce the likelihood and impact of malfunctions.
  
-The duty of information transparency emphasizes the importance of providing accurate and accessible data. Real-time sensor data should be disclosed in a clear and reliable manner, allowing stakeholders to assess environmental performance and understand the actual impact of the system on sustainability outcomes.+The duty of information transparency emphasizes the importance of providing accurate and accessible data. Sensor data should be disclosed in a clear and reliable manner, allowing stakeholders to assess environmental performance and understand the actual impact of the system on sustainability outcomes.
  
 The duty to maximize economic utility involves supporting clients in achieving cost efficiency over time. This includes designing systems that reduce long-term maintenance requirements and operational costs, thereby increasing the overall economic value of the solution. The duty to maximize economic utility involves supporting clients in achieving cost efficiency over time. This includes designing systems that reduce long-term maintenance requirements and operational costs, thereby increasing the overall economic value of the solution.
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-The project aims to support marine ecosystems while minimizing negative environmental impacts. The artificial habitats are designed to promote biodiversity and contribute to the restoration of natural fish populations without disrupting the surrounding ecosystem.+The project aims to support marine ecosystems while minimizing negative environmental impacts. Artificial habitats are designed to promote biodiversity and help restore fish populations without significantly disrupting the surrounding ecosystem.
  
-Material selection prioritizes durability and environmental compatibility in order to reduce pollution and long-term ecological harmCare is taken to ensure that the structures do not release harmful substances into the marine environment.+Material selection focuses on durability and environmental compatibility in order to reduce pollution and long-term ecological damageSpecial attention is given to ensuring that the structures do not release harmful substances into the marine environment.
  
-The project also contributes to environmental awareness and education by enabling the collection of monitoring data through integrated sensors. This data supports researchers and local communities in developing a deeper understanding of marine ecosystems and the factors that influence their health.+In addition, the project contributes to environmental awareness and education by enabling the collection of monitoring data through integrated sensors. This data can support researchers and local communities in better understanding marine ecosystems and the factors that influence their health.
  
-The design considers ecosystem balance, ensuring that the habitat supports species that naturally coexist and avoids introducing elements that could negatively affect the existing ecological structure. This approach aligns with principles of environmental responsibility and sustainable marine management.+The design also considers ecosystem balance by supporting species that naturally coexist and avoiding elements that could disturb the existing ecological structure. Studies have shown that ecologically enhanced marine structures can increase biodiversity without compromising structural performance [(SELLA2015)].
 ==== 6.5 Liability ====  ==== 6.5 Liability ==== 
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 +__//**HERNAN: I WILL CHECK IT**//__
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 Liability relates to the responsibility for potential consequences if the system does not perform as intended. This includes risks such as incorrect environmental data, failure of monitoring components, or unintended interactions with the surrounding marine environment. Liability relates to the responsibility for potential consequences if the system does not perform as intended. This includes risks such as incorrect environmental data, failure of monitoring components, or unintended interactions with the surrounding marine environment.