Sustainability competency: Self-awareness; Normative. UNESCO has developed eight key competencies for sustainability that are aimed at learners of all ages worldwide. Many versions of these exist, as are linked here*. In the UK, these have been adapted within higher education by AdvanceHE and the QAA with appropriate learning outcomes. The full list of competencies and learning outcome alignment can be found in the Education for Sustainable Development Guidance*. *Click the pink ''Sustainability competency'' text to learn more.
AHEP mapping: This resource addresses two of the themes from the UK’s Accreditation of Higher Education Programmes fourth edition (AHEP4): The Engineer and Society (acknowledging that engineering activity can have a significant societal impact) and Engineering Practice (the practical application of engineering concepts, tools and professional skills). To map this resource to AHEP outcomes specific to a programme under these themes, access AHEP 4 here and navigate to pages 30-31 and 35-37.
Related SDGs: SDG 4 (Quality education); SDG 13 (Climate action).
Reimagined Degree Map Intervention: More real-world complexity; Active pedagogies and mindset development; Cross-disciplinarity.The Reimagined Degree Map is a guide to help engineering departments navigate the decisions that are urgently required to ensure degrees prepare students for 21st century challenges. Click the pink ''Reimagined Degree Map Intervention'' text to learn more.
Who is this article for? This article should be read by educators at all levels in higher education who are seeking to apply an approach of teaching with case studies in order to reveal the links between ethics and sustainability. Engaging with this topic will also help to prepare students with the soft skill sets that employers are looking for.
As environmental pressures mount, the world demands not just engineering solutions, but sustainable ones. This shift presents profound challenges and opportunities for engineering educators. How can we equip future engineers with the ethical frameworks and critical thinking skills needed to navigate the complex trade-offs inherent in green solutions?
This article provides a guide for integrating ethical considerations into engineering education by using case studies. By fostering awareness of sustainability principles and promoting responsible decision-making through real-world examples, we can empower students to become stewards of a more equitable and resilient future.
The interplay of ethics and sustainability:
At its core, sustainability goes beyond environmental impact. It encompasses social responsibility, economic viability, and intergenerational equity. Ethical engineering aligns with these principles by:
Prioritising transparency and honesty: Green solutions shouldn’t mask potential downsides or mislead stakeholders.
Respecting all stakeholders: Engineers must consider the needs and voices of local communities, indigenous populations, and future generations.
Envisioning long-term consequences: Solutions conceived with short-term gain in mind can have unforeseen environmental and social repercussions.
Integrating ethical considerations into engineering curricula presents several challenges:
Balancing economic pressures: Sustainable solutions don’t always align with immediate cost-effectiveness. Educators must help students navigate these complex trade-offs and advocate for long-term benefits.
Fostering interdisciplinary collaboration: Sustainability demands diverse perspectives. Educators can encourage partnerships with ecologists, sociologists, and other experts to enrich student understanding.
Staying updated with evolving technologies: The sustainability landscape is dynamic. Educators must themselves embrace continuous learning to ensure their curriculum reflects the latest developments and potential ethical dilemmas.
Learning from a case study:
The sprawling Ivanpah Solar Electric Generating System in California’s Mojave Desert, initially celebrated as a beacon of clean energy, now casts a complex shadow on the region’s ecological landscape. While harnessing the sun’s power to electrify millions, its concentrated solar technology inadvertently unleashed unintended consequences. The intense heat generated by the mirrors tragically claimed thousands of birds, particularly desert tortoises, a threatened species. Drawn to the shimmering light, they would collide with the mirrors or structures, falling victim to a technological mirage. This stark reality challenged the “green” label of a project originally intended to combat climate change.
Unforeseen costs of progress:
Ivanpah’s case highlights the hidden costs of even well-intentioned renewable energy projects. It sparks critical questions for students to grapple with:
Sustainability beyond carbon emissions: While reducing carbon footprint is crucial, broader ecosystem impacts must be considered. Can technological advancements mitigate harm to vulnerable species and habitats?
Balancing energy needs with ecological needs: How can we find the sweet spot between harnessing renewable energy and preserving biodiversity? Can alternative technologies or site selection minimise ecological disruption?
Engaging stakeholders in ethical decision-making: How can local communities and ecological experts be meaningfully included in planning and mitigation strategies to ensure equitable outcomes?
By delving into the Ivanpah case (and others like it*), students can develop critical thinking skills to analyse the long-term implications of seemingly green solutions. They learn to consider diverse perspectives, advocate for responsible design practices, and prioritise environmental stewardship alongside energy production.
As educators, we hold the power to shape the ethical compass of future engineers. By integrating ethical considerations into the fabric of our curriculum, we can equip them with the tools and knowledge necessary to:
Make informed decisions: Students should learn to analyse solutions through the lens of ethics, considering environmental impact, social responsibility, and economic viability.
Engage in open dialogue: Cultivating a culture of critical thinking and open communication is crucial for addressing diverse perspectives and mitigating potential ethical concerns.
Collaborate ethically: Students should understand the importance of interdisciplinary collaboration, respecting diverse expertise and working towards shared goals that benefit all stakeholders.
Conclusion:
The pursuit of a sustainable future demands ethical engineers, engineers who can not only innovate, but also act with integrity and responsibility. By equipping students with the knowledge and skills necessary to grapple with complex ethical dilemmas, we can empower them to become transformative agents of change, shaping a world that thrives for generations to come.
References:
Delong, D. (2012). ‘Sustainable engineering: A comprehensive introduction’. John Wiley & Sons.
Any views, thoughts, and opinions expressed herein are solely that of the author(s) and do not necessarily reflect the views, opinions, policies, or position of the Engineering Professors’ Council or the Toolkit sponsors and supporters.
Keywords: SDGs; AHEP; Sustainability; Design; Life cycle; Local community; Environment; Circular economy; Recycling or recycled materials; Student support; Higher education; Learning outcomes.
Sustainability competency: Systems thinking; Anticipatory; Critical thinking.UNESCO has developed eight key competencies for sustainability that are aimed at learners of all ages worldwide. Many versions of these exist, as are linked here*. In the UK, these have been adapted within higher education by AdvanceHE and the QAA with appropriate learning outcomes. The full list of competencies and learning outcome alignment can be found in the Education for Sustainable Development Guidance*. *Click the pink ''Sustainability competency'' text to learn more.
AHEP mapping: This resource addresses two of the themes from the UK’s Accreditation of Higher Education Programmes fourth edition (AHEP4): The Engineer and Society (acknowledging that engineering activity can have a significant societal impact) and Engineering Practice (the practical application of engineering concepts, tools and professional skills). To map this resource to AHEP outcomes specific to a programme under these themes, access AHEP 4 here and navigate to pages 30-31 and 35-37.
Related SDGs: SDG 9 (Industry, innovation, and infrastructure); SDG 12 (Responsible consumption and production).
Reimagined Degree Map Intervention: Adapt and repurpose learning outcomes; More real-world complexity.The Reimagined Degree Map is a guide to help engineering departments navigate the decisions that are urgently required to ensure degrees prepare students for 21st century challenges. Click the pink ''Reimagined Degree Map Intervention'' text to learn more.
Who is this article for? This article is for educators working at all levels of higher education who wish to integrate Sustainability into their robotics engineering and design curriculum or module design. It is also for students and professionals who want to seek practical guidance on how to integrate Sustainability considerations into their robotics engineering.
Part of the strategy to ensure that engineers incorporate sustainability into their solution development is to ensure that engineering students are educated on these topics and taught how to incorporate considerations at all stages in the engineering process (Eidenskog et al., 2022). For instance, students need not only to have a broad awareness of topics such as the SDGs, but they also need lessons on how to ensure their engineering incorporates sustainable practice. Despite the increased effort that has been demonstrated in engineering generally, there are some challenges when the sustainability paradigm needs to be integrated into robotics study programs or modules (Leifler and Dahlin, 2020). This article details one approach to incorporate considerations of the SDGs at all stages of new robot creation: including considerations prior to design, during creation and manufacturing and post-deployment.
1. During research and problem definition:
Sustainability considerations should start from the beginning of the engineering cycle for robotic systems. During this phase it is important to consider what the problem statement is for the new system, and whether the proposed solution satisfies this in a sustainable way, using Key Performance Indicators (KPIs) linked to the SDGs (United Nations, 2018), such as carbon emissions, energy efficiency and social equity (Hristov and Chirico, 2019). For instance, will the energy expended to create the robot solution be offset by the robot once it is in use? Are there long-term consequences of using a robot as a solution? It is important to begin engagement with stakeholders, such as end-users, local communities, and subject matter experts to gain insight into these types of questions and any initial concerns. Educators can provide students with opportunities to engage in the research and development of robotics technology that can solve locally relevant problems and benefit the local community. These types of research projects allow students to gain valuable research experience and explore robotics innovations through solving problems that are relatable to the students. There are some successful examples across the globe as discussed in Dias et al., 2005.
2. At design and conceptualisation:
Once it is decided that a robot works as an appropriate solution, Sustainability should be integrated into the robot system’s concept and design. Considerations can include incorporating eco-design principles that prioritise resource efficiency, waste reduction, and using low-impact materials. The design should use materials with relatively low environmental footprints, assessing their complete life cycles, including extraction, production, transportation, and disposal. Powered systems should prioritise energy-efficient designs and technologies to reduce operational energy consumption, fostering sustainability from the outset.
3.During creation and manufacturing:
The robotic system should be manufactured to prioritise methods that minimise, mitigate or offset waste, energy consumption, and emissions. Lean manufacturing practices can be used to optimise resource utilisation where possible. Engineers should be aware of the importance of considering sustainability in supply chain management to select suppliers with consideration of their sustainability practices, including ethical labour standards and environmentally responsible sourcing. Robotic systems should be designed in a way that is easy to assemble and disassemble, thus enabling robots to be easily recycled, or repurposed at the end of their life cycle, promoting circularity and resource conservation.
4. Deployment:
Many robotic systems are designed to run constantly day and night in working environments such as manufacturing plants and warehouses. Thus energy-efficient operation is crucial to ensure users operate the product or system efficiently, utilising energy-saving features to reduce operational impacts. Guidance and resources should be provided to users to encourage sustainable practices during the operational phase. System designers should also implement systems for continuous monitoring of performance and data collection to identify opportunities for improvement throughout the operational life.
5.Disposal:
Industrial robots have an average service life of 6-7 years. It is important to consider their end-of-life and plan for responsible disposal or recycling of product components. Designs should be prioritised that facilitate disassembly and recycling (Karastoyanov and Karastanev, 2018). Engineers should identify and safely manage hazardous materials to comply with regulations and prevent environmental harm. Designers can also explore options for product take-back and recycling as part of a circular economy strategy. There are various ways of achieving that. Designers can adopt modular design methodologies to enable upgrades and repairs, extending their useful life. Robot system manufacturers should be encouraged to develop strategies for refurbishing and reselling products, promoting reuse over disposal.
Conclusion:
Sustainability is not just an option but an imperative within the realm of engineering. Engineers must find solutions that not only meet technical and economic requirements but also align with environmental, social, and economic sustainability goals. As well as educating students on the broader topics and issues relating to Sustainability, there is a need for teaching considerations at different stages in the robot development lifecycle. Understanding the multifaceted connections between sustainability and engineering disciplines, as well as their impact across various stages of the engineering process, is essential for engineers to meet the challenges of the 21st century responsibly.
Any views, thoughts, and opinions expressed herein are solely that of the author(s) and do not necessarily reflect the views, opinions, policies, or position of the Engineering Professors’ Council or the Toolkit sponsors and supporters.
Sustainability competency: Collaboration; Integrated problem-solving.UNESCO has developed eight key competencies for sustainability that are aimed at learners of all ages worldwide. Many versions of these exist, as are linked here*. In the UK, these have been adapted within higher education by AdvanceHE and the QAA with appropriate learning outcomes. The full list of competencies and learning outcome alignment can be found in the Education for Sustainable Development Guidance*. *Click the pink ''Sustainability competency'' text to learn more.
AHEP mapping: This resource addresses two of the themes from the UK’s Accreditation of Higher Education Programmes fourth edition (AHEP4): The Engineer and Society (acknowledging that engineering activity can have a significant societal impact) and Engineering Practice (the practical application of engineering concepts, tools and professional skills). To map this resource to AHEP outcomes specific to a programme under these themes, access AHEP 4 here and navigate to pages 30-31 and 35-37.
Related SDGs: All 17; see specific examples below for SDG 2 (Zero Hunger); SDG 13 (Climate Action).
Reimagined Degree Map Intervention: Adapt and repurpose learning outcomes; Active pedagogies and mindset development; Authentic assessment.The Reimagined Degree Map is a guide to help engineering departments navigate the decisions that are urgently required to ensure degrees prepare students for 21st century challenges. Click the pink ''Reimagined Degree Map Intervention'' text to learn more.
Who is this article for? This article should be read by educators at all levels in Higher Education who wish to embed sustainable development goals into computing projects.
Education for Sustainable Development (ESD) is defined by UNESCO (2021) as: “the process of equipping students with the knowledge and understanding, skills and attributes needed to work and live in a way that safeguards environmental, social and economic wellbeing, in the present and for future generations.” All disciplines have something to offer ESD, and all can contribute to a sustainable future. This guide presents how to embed the Sustainable Development Goals (SDGs) into undergraduate computing projects, using problem-based learning and teamwork as the main pedagogical tools (Mishra & Mishra, 2020).
Embedding Sustainable Development Goals (SDGs) into computing group projects:
Typically, the aim of the undergraduate Computing Group Project is to:
start preparing students for a professional career in the computing industry.
familiarise the students with working in software development teams.
give them the experience of delivering a non-trivial software system.
This type of project provides students with an opportunity to integrate various skills, including design, software development, project management, and effective communication.
In this project setting, the students can be asked to select a project theme based on the SDGs. The module team then can support student learning in three key ways:
1. Lectures, labs, and regular formative assessments can build on lab activities to walk the project groups through a sustainability journey that starts from a project pitch, continues with design, implementation, and project progress reporting, and ends with delivering a final demo.
2. Blending large classroom teaching with small group teaching, where each group is assigned a tutor, to ensure timely support and feedback on formative assessments.
3. A summative assessment based on a well-structured project portfolio template, guiding students to present and reflect on their individual contribution to the group effort. This portfolio may form the only graded element of their work, giving the students the opportunity to learn from their mistakes in formative assessments and present their best work at the end of the module.
Mapping the learning outcomes to the eight UNESCO key competencies for sustainability (Advance HE, 2021), the students will have the opportunity to experience the following:
Group work: The students plan, manage, and track a substantial group activity, understanding and applying the principles of professional and ethical behaviour in a group context. They “recognise that a collective effort is not just a simple sum of each individual’s effort but is likely to be more complex and have multiple drivers that may be personal, political or communal” (Advance HE, 2021, p. 24).
Open-ended problem: The groups take an open-ended problem, collect, and analyse relevant information and define the requirements. They will “identify the tensions between the 17 SDGs and recognise their interconnections” (Advance HE, 2021, p. 24) and work towards “creating their visions for the future” (Advance HE, 2021, p. 25).
Non-trivial software development: The students will independently and systematically design, develop, and evaluate a piece of software that is data-driven and has non-trivial functionality. This way, they will “develop and implement innovative actions that further sustainable development at the local level and beyond” (Advance HE, 2021, p. 27).
Alternative solutions: They will analyse complex systems and compare and evaluate alternative problem solutions according to given criteria, including from a technical perspective.
Communication: They will effectively present ideas and solutions, recognising the importance of “verbal and non-verbal communication skills and their role in group cohesion” (Advance HE, 2021, p. 28).
More specifically, sustainable development can be embedded following a lecture-lab-formative assessment-summative assessment path:
1. Introduction lecture: Introduce the SDGs and give real-life examples of software that contribute to SDGs (examples include: for SDG 2 – Zero Hunger, the World Food Programme’s Hunger Map; SDG 13 – Climate Action, Climate Mind ). The students then can be instructed to do their own research on SDGs.
2. Apply design thinking to project ideation: In a lecture, students are introduced to design thinking and the double-diamond of design to use a diverge-converge strategy to first “design the right thing” and second “design things right.” In a practical session, with teaching team support, the students can meet their groups for a brainstorming activity. It is essential to inform students about setting ground rules for discussion, ensuring all voices are heard. Encourage students to apply design thinking to decide which SDG-based problem they would like to work on to develop a software solution. Here, giving students an example of this process based on a selected SDG will be useful.
3. Formative assessment – project pitch deliverable: The next step is to channel students’ output of the design thinking practical to a formative assessment. Students can mould their discussion into a project pitch for their tutors. Their presentation should explain how their project works towards one or more of the 17 SDGs.
4. Summative assessment – a dedicated section in project portfolio: Finally, dedicating a section in a project portfolio template on ideation ensures students reflect further on the SDGs. In the portfolio, students can be asked to reflect on how individual ideas were discussed and feedback from different group members was captured. They should also reflect on how they ensured the chosen problem fits one or more SDGs, describe the selection process of the final software solution, and what alternative solutions for the chosen SDG they have discussed, elaborating on the reasons for the final choice.
Conclusion:
Computing projects provide an excellent opportunity to align teaching, learning, and assessment activities to meet key Sustainable Development competencies and learning outcomes. The projects can provide transformational experiences for students to hear alternative viewpoints, reflect on experiences, and address real-world challenges.
Lewrick, M., Link, P., Leifer, L.J. & Langensand, N. (2018). The design thinking playbook: mindful digital transformation of teams, products, services, businesses, and ecosystems. New Jersey: John Wiley & Sons, Inc, Hoboken.
Any views, thoughts, and opinions expressed herein are solely that of the author(s) and do not necessarily reflect the views, opinions, policies, or position of the Engineering Professors’ Council or the Toolkit sponsors and supporters.
Sustainability competency: Integrated problem-solving.UNESCO has developed eight key competencies for sustainability that are aimed at learners of all ages worldwide. Many versions of these exist, as are linked here*. In the UK, these have been adapted within higher education by AdvanceHE and the QAA with appropriate learning outcomes. The full list of competencies and learning outcome alignment can be found in the Education for Sustainable Development Guidance*. *Click the pink ''Sustainability competency'' text to learn more.
AHEP mapping: This resource addresses three of the themes from the UK’s Accreditation of Higher Education Programmes fourth edition (AHEP4): The Engineer and Society (acknowledging that engineering activity can have a significant societal impact) and Engineering Practice (the practical application of engineering concepts, tools and professional skills) and Science and Mathematics (the ability to apply the knowledge, not merely understand it).To map this resource to AHEP outcomes specific to a programme under these themes, access AHEP 4 here and navigate to pages 30-31 and 35-37.
Related SDGs: See below for problems specific to SDG 5 (Gender Equality); SDG 6 (Clean Water and Sanitation); SDG 7 (Affordable and Clean Energy); SDG 9 (Industry, Innovation and Infrastructure); SDG 10 (Reduced Inequalities); SDG 12 (Responsible Consumption and Production); SDG 14 (Life Below Water); and SDG 15 (Life on Land).
Reimagined Degree Map Intervention: Cross-disciplinarity.The Reimagined Degree Map is a guide to help engineering departments navigate the decisions that are urgently required to ensure degrees prepare students for 21st century challenges. Click the pink ''Reimagined Degree Map Intervention'' text to learn more.
Who is this article for? This article should be read by academics and educators at all levels in higher education who wish to integrate sustainability into the engineering curriculum within the typical mathematics-specific modules that are present. It will also help prepare students with the key graduate attributes and skills required by professional accreditation bodies and employers.
Global challenges that call for environmental, sustainable and innovative solutions have consistently pushed us to be open to the changes and challenges within engineering education (Graham, 2012; Graham, 2018; Crawley et al., 2014; Lawlor, 2013; The Royal Academy of Engineering, 2007). Despite the prevalence of the UN Sustainable Development Goals(SDGs) since 2015, several reports and studies (Mulder et al., 2012; Buckler and Creech, 2014; Lazzarini et al., 2018; Morrissey, 2013; Neubauer et al., 2017; Wals, 2014; Miñano Rubio et al. 2019) have noted that the incorporation of sustainability within universities finds the greatest barrier in the field of teaching, with curricula often failing to address key environmental and ethical issues. This situation reflects the need for educators to develop a toolkit of resource materials that can serve as a reference guide for the effective and systematic integration of sustainability into university engineering curricula (Thürer et al., 2018).
Basic principles for embedding sustainability and ethics:
The principles for integrating sustainability into mathematical problems and exercises within the engineering curricula share strong parallels to the embedding of ethical components, as documented within several guidance articles from the EPC’s Engineering Ethics Toolkit. Some of these include:
Interweaving into existing course materials:
Much like ethics, integrating sustainability into science and engineering courses* is “largely a matter of providing context for what is already being taught, context that also makes the material already being taught seem “more relevant” (Davis, 2006, Miñano Rubio et al. 2019). The technique of “micro-insertion” described by Davis in the context of ethics can also be succinctly adapted for sustainability issues, in that these “are not add-ons; they work like an alloy, adding strength to the course without adding volume” i.e., they need not be perceived as components to be introduced in lieu of existing technical material.
*For specific examples, see the following guidance articles:
The inclusion of sustainability aspects into mathematical problems does require a great deal of care, thought and gradual experience as it might be done in a seamless and organic manner, without appearing to be artificial or contrived. The focus should be upon how students are engaging with these themes and not merely upon introducing sustainability as an add-on component to be taught (Butt et al., 2022). Often this is avoided by ensuring that such concepts emerge naturally from the technical nature of the mathematics/physics of the problem itself i.e., through an enlargement of the context of a problem by aligning it to a realistic scenario (see examples below).
Subjective and reflective aspects:
Another point worth noting is that the answers to the sustainability elements of a question will often involve open-ended discussions and will most certainly involve subjective aspects, prompting deeper reflection from both students and instructors (Paulauskaite-Taraseviciene et al., 2022). This is unlike the objective ‘right or wrong’ answers provided to the technical parts of the problem, therefore even the guided ‘solution sketches’ provided in some of the example questions below, should not be treated as exact and fixed in nature, in fact these may be altered, tweaked or modified on subsequent usage.
A final principle to mention pertains to the identification and mapping of key sustainability concepts within problems to each of the different 17 SDGs as applicable (see examples below). By establishing direct links between the overarching themes emerging from the technical problems and the SDGs formulated by the United Nations as part of its 2030 Agenda for Sustainable Development, students will be able to acquire a much more holistic view of sustainability within the context of their technical learning in engineering disciplines (Zelinka and Amadei, 2017; Ramirez-Mendoza et al., 2020)
Examples of mathematical problems with embedded sustainability:
The following three example problems from Chiodo and Muller, 2023 with minor adaptations (as permitted under the Creative Commons License CC BY-SA 4.0), illustrate ways in which sustainability aspects can be integrated within traditional technical exercise questions found in engineering mathematics courses:
Partial solution comments have been included here for brevity, please refer to Chiodo and Muller, 2023 for full solution details.
Problem 1: Pipeline construction
Topic: Optimisation.
SDG mapping: SDG 7 (Affordable and Clean Energy), SDG 9 (Industry, Innovation and Infrastructure), SDG 14 (Life Below Water), SDG 15 (Life on Land).
An oil company wants to build a pipeline connecting an oil platform to a refinery (on land). The coastline is straight. The oil platform is at a distance of 13km from the coast. The refinery is on the coastline, a distance 10km from the point on the coast closest to the platform. Building the pipeline will lead to a cost of £90,000 per km at sea and £60,000 per km on land.
Calculate the optimal length for building the pipeline. What are the factors that need to be considered when providing a response to this question?
Solution comments: The cost-minimising path is given by Snell’s law and is an exercise in trigonometry and calculus. But who said we were optimising over cost? This is an assumption often engrained into engineers while they are students, but it need not always be the right way to optimise. How many decisions made by government agencies (often based on advice offered by mathematical consultants) use economics as the sole criterion for optimisation?
Economic actions almost always have externalities, such as possible damage to the environment (the pipe may go through a coral reef or protected habitat) or to existing infrastructure (it may go through a school or a site of archaeological significance). How could we mathematically model the environmental and human impact of laying this pipe? There are numerous factors to consider and students, much like policymakers would, should take a holistic view of these effects and at least be aware of, and question the implications of basing decisions solely on economic factors.
Problem 2: Environmental disasters
Topic: Differential equations.
SDG mapping: SDG 6 (Clean Water and Sanitation), SDG 12 (Responsible Consumption and Production).
A chemical accident took place near a small village in Peru. The region’s local water reservoir has a volume V. The inflow and outflow of the reservoir is given by the flow rate r. Let x(t) be the amount of mercury in the reservoir at time t. Assume that the reservoir was clean at the beginning i.e., x(0) = 0. Let C(t) be the concentration of mercury flowing into the reservoir.
a. Set up and solve a differential equation describing the concentration of the reservoir.
b. How can you use your solution to model repeated pollution (e.g., criminals dumping mercury near the reservoir every weekend)?
c. What are some relevant questions you can ask about the concentration of mercury in the reservoir?
d. Suppose that the polluter is caught and after some cleaning, the incoming water is clean. How can you use your model to analyse when the water in the reservoir will be safe again? How sure are you of your answer and how much does it matter?
Solution comments:This question is designed to show students that very simple mathematics can be used to model local environmental disasters, which can often be an example of how it may be used unsustainably. It teaches students to find good questions instead of merely answering someone else’s questions.
For part c), possible questions for students to consider can include:
Will the pollution of the reservoir ever reach a dangerous level?
What is deemed a “safe” level of mercury in the reservoir?
How closely does the concentration of the reservoir follow the inflow of pollutant chemicals?
Will the reservoir reach an equilibrium concentration of mercury?
For part d) for the sub question “How sure are you?”, students will need to explore what the ‘known’ unknowns are e.g., errors in the measurement apparatus, non-uniform mixing, samples taken in a very clean/dirty part of the stream or reservoir. They may also need to consider any ‘unknown’ unknowns e.g., other sources of pollutants, samples being tampered with accidentally or deliberately, etc.
For part d) for the sub question “How much does it matter?”, students should identify that we are dealing with poison in drinking water, so it matters immensely! They should understand that this is an estimate, which helps forecast when the water might be safe to drink (the only way to actually know is to thoroughly test it). This question helps students to realise that the mathematics is simply one part of a much bigger solution and should not be relied upon as a definitive answer to a question as serious as the safety of drinking water.
In a particular admissions cycle, a mathematics department observes a higher success rate for male applicants than for female applicants. To investigate whether this is the same across he two sub-departments of Pure Mathematics and Applied Mathematics, the following year the department asks each applicant to give their preference for pure or applied mathematics (they are not allowed to be ambivalent) and records the resulting statistics as shown in Figure 4 below:
Total
Applications
Successful
Female
300
30
Male
1000
210
Prefer applied
Applications
Successful
Female
270
18
Male
350
15
Prefer pure
Applications
Successful
Female
30
12
Male
650
195
Figure 4: Admission statistics for male and female applications to study mathematics
a. Compare the success rates for male and female applicants that prefer applied mathematics, prefer pure mathematics and their success rates overall.
b. What do you notice? Why is this possible? This is known as Simpson’s Paradox.
c. If possible, find the admission statistics by gender and mathematics preference (pure/applied) from your university’s mathematics department and see if the same phenomenon occurs.
Solution comments:The purpose of this question is to demonstrate Simpson’s paradox in which a trend appears in several different groups of data but disappears or reverses when these groups are combined. It also attempts to highlight the immense gender disparity in many mathematics departments around the world.
For part b) it is evident from the calculations in part a) that females with a given preference (pure/applied mathematics) have a higher success rate than males with the same preference, but lower overall. This is Simpson’s Paradox. The heuristic reason for why this is possible is that the largest male cohort (those that prefer pure) has a much higher acceptance rate than the largest female cohort (those that prefer applied). So, the overall acceptance of men is dominated by those who prefer pure, while the overall acceptance of women is dominated by those who prefer applied. This is a great lesson in why it is usually a terrible idea to take “averages of averages”.
The main purpose of part c) is not so much for students to redo the calculation (it is not a given that Simpson’s Paradox will always arise here), but rather to illustrate the immense gender disparity in many mathematics departments around the world.
Conclusion:
The aim of this article is to provide academics and educators in higher education with an insight into how sustainability concepts may be integrated into technical, mathematical problems prevalent throughout engineering curricula. This should hopefully motivate lecturers to design their own versions of similar exercises to embed within their own courses and help build on ongoing calls to enhance the restructuring of our university programmes to better prepare future engineers to tackle global sustainability challenges by drawing not only on their technical and scientific knowledge, but also on their creativity, ethical, professional and leadership skills.
Any views, thoughts, and opinions expressed herein are solely that of the author(s) and do not necessarily reflect the views, opinions, policies, or position of the Engineering Professors’ Council or the Toolkit sponsors and supporters.
Authors: Peter Mylon MEng PhD CEng FIMechE PFHEA NTF and SJ Cooper-Knock PhD (The University of Sheffield).
Topic: Maker Communities and ESD.
Tool type: Knowledge.
Relevant disciplines: Any.
Keywords: Interdisciplinary; Education for sustainable development; Makerspaces, Recycling or recycled materials; Employability and skills; Inclusive learning; Local community; Climate change; Student engagement; Responsible consumption; Energy efficiency; Design; Water and sanitation; AHEP; Sustainability; Higher education; Pedagogy.
Sustainability competency: Collaboration; Integrated problem-solving.UNESCO has developed eight key competencies for sustainability that are aimed at learners of all ages worldwide. Many versions of these exist, as are linked here*. In the UK, these have been adapted within higher education by AdvanceHE and the QAA with appropriate learning outcomes. The full list of competencies and learning outcome alignment can be found in the Education for Sustainable Development Guidance*. *Click the pink ''Sustainability competency'' text to learn more.
AHEP mapping: This resource addresses two of the themes from the UK’s Accreditation of Higher Education Programmes fourth edition (AHEP4): The Engineer and Society (acknowledging that engineering activity can have a significant societal impact) and Engineering Practice (the practical application of engineering concepts, tools and professional skills). To map this resource to AHEP outcomes specific to a programme under these themes, access AHEP 4 here and navigate to pages 30-31 and 35-37.
Related SDGs: SDG 4 (Quality education); SDG 6 (Clean water and sanitation); SDG 11 (Sustainable cities and communities); SDG 12 (Responsible consumption and production); SDG 13 (Climate action).
Reimagined Degree Map Intervention: Active pedagogies and mindset development; Cross-disciplinarity.The Reimagined Degree Map is a guide to help engineering departments navigate the decisions that are urgently required to ensure degrees prepare students for 21st century challenges. Click the pink ''Reimagined Degree Map Intervention'' text to learn more.
Who is this article for? This article should be read by educators at all levels in higher education who are curious about how maker spaces and communities can contribute to sustainability efforts in engineering education. Engaging with this topic will also help to prepare students with the soft skill sets that employers are looking for.
Premise:
Makerspaces can play a valuable role in Education for Sustainable Development (ESD). In this article, we highlight three specific contributions they can make to ESD in Engineering: Makerspaces enable engineering in real-world contexts; they build cross-disciplinary connections and inclusive learning; and they promote responsible consumption.
A brief introduction to makerspaces:
In recent years, a ‘makerspace’ movement has emerged in Higher Education institutions. While most prevalent in the US, there are now a number of university-based makerspaces in the UK, including the iForge at the University of Sheffield, the Institute of Making at UCL, and the Makerspace at King’s College London. So what is a makerspace, and what do they have to do with Education for Sustainable Development (ESD)?
Makerspaces are part of a larger “maker movement” that includes maker fairs, clubs and magazines. Within universities, they are “facilities and cultures that afford unstructured student-centric environments for design, invention, and prototyping.” (Forest et al., 2016). Successful and inclusive makerspaces are student led. Student ownership of makerspace initiatives deepens student motivation, promotes learning, and encourages peer-to-peer collaboration. Successful makerspaces produce thriving learning communities, through which projects can emerge organically, outside of curriculum structures and discipline boundaries.
In terms of Education for Sustainable Development (ESD), this means that students can bring their passion to make a difference, and can meet other students with similar interests but complementary skill sets. With support from the University, they can then be given opportunities to put their passion and skills into practice. Below, we focus on three concrete contributions that makerspaces can make to ESD: Opportunities for applied learning; expanded potential for cross-disciplinary learning, and the chance to deepen engaged learning on sustainable consumption.
1. Maker communities enable engineering in real world contexts:
1.1 ESD rationale
ESD enables students to think critically about possible solutions to global challenges. It encourages students to consider the social, economic, and political context in which change takes place. ESD also spurs students to engage, where possible, with those beyond the university.
It may be tempting to think of engineering as simply a technical exercise: one in which scientific and mathematical knowledge is taken and applied to the world around us. In practice, like all other professions, engineers do not simply apply knowledge, they create it. In order to do their work, engineers build, hold, and share ideas about how the world works: how users will behave; how materials will function; how they can be repaired or disposed of; what risks are acceptable, and why. These ideas about what is reasonable, rational, and probable are, in turn, shaped by the broader social, political, and economic context in which they work. This context shapes everything from what data is available, to what projects are prioritised, and how risk assessments are made. Rather than trying to ignore or remove these subjective and context-based elements of engineering, we need to understand them. In other words, rather than ask whether an engineering process is impacted by social, political, and economic factors we need to ask how this impact happens and the consequences that it holds. ESD encourages students to think about these issues.
1.2 The contribution of makerspaces
The availability of both equipment and expertise, and the potential for practical solutions, means that makerspaces often attract projects from outside the university. These provide opportunities to practise engineering in real-world contexts, where there is the possibility for participatory design. All such projects will require some consideration of social, political, or economic factors, which are at the heart of the Sustainable Development Goals.
One example of this is SheffHEPP, a hydroelectric power project at the University of Sheffield. In response to requests for help from local communities, students are designing and building small-scale hydroelectric power installations in a number of locations. This multidisciplinary project requires an understanding of water engineering, electrical power generation, battery storage and mechanical power transmission, as well as taking into consideration the legal, financial, and environmental constraints of such an undertaking. But it also requires Making – students have made scale models and tested them in the lab, and are now looking to implement their designs in situ. Such combinations of practical engineering and real-world problems that require consideration of the wider context provide powerful educational experiences that expose students to the realities of sustainable development.
There are a number of national and international organisations for students that promote SDGs through competitions and design challenges. These include:
Engineers Without Borders – an international organisation with branches at many UK universities, which runs, amongst other things, the ‘Engineering for People Design Challenge’
Shell EcoMarathon – a vehicle design competition focused on energy optimisation
Cybathlon– a platform that challenges teams globally to develop assistive technologies suitable for everyday use, with and for people with disabilities
Student engagement with such activities is growing exponentially, and makerspaces can benefit students who are prototyping ideas for the competitions. At Sheffield, there are over 20 co-curricular student-led projects in engineering, involving around 700 students, many of which engage with the SDGs. In addition to SheffHEPP and teams entering all of the above competitions, these include teams designing solutions for rainwater harvesting, vaccine storage, cyclone-proof shelters for refugees, plastics recycling, and retrofitting buildings to reduce energy consumption. As well as the employability benefits of such activities, students are looking for ways to use engineering to create a better future, with awareness of issues around climate change and sustainability increasing year on year. And none of these activities would be possible without access to maker facilities to build prototypes.
Linked to the makerspace movement is the concept of hackathons – short sprints where teams of students compete to design and prototype the best solution to a challenge. At Sheffield, these have included:
Hackcessible – an assistive technology hackathon where students work with disabled members of the community to design bespoke solutions to problems that fall outside of the scope of healthcare provision;
The Biodigester Hackathon – finding the best way to convert waste from the University’s Diamond building into energy;
The Rice Seeder Design Challenge – working with a social enterprise in Cambodia to improve the design of traditional rice seeders in order to increase productivity.
In summary, Makerspaces enable students to access multiple initiatives through which they can engage in learning that is potentially participatory and applied. These forms of learning are critical to ESD and have the potential to address multiple Sustainable Development Goals.
2. Maker communities build cross-disciplinary connections and encourage inclusive learning:
2.1 ESD rationale
Global complex challenges cannot be resolved by engineers alone. ESD encourages students to value different forms of knowledge, from within and beyond academia. Within academia, makerspaces can provide opportunities for students to collaborate with peers from other disciplines. Cross-disciplinary knowledge can play a crucial role in understanding the complex challenges that face our world today. Makerspaces also offer an opportunity for students to engage with other forms of knowledge – such as the knowledge that is formed through lived experience – and appreciate the role that this plays in effective practices of design and creation. Finally, makerspaces can help students to communicate their knowledge in ways that are understandable to non-specialist audiences. This inclusive approach to knowledge creation and knowledge sharing enables students to think innovatively about sustainable solutions for the future.
2.2 The contribution of makerspaces
Cross-disciplinary spaces
Student-led makerspaces encourage students to lead in the creation of cross-disciplinary connections. For example, at the University of Sheffield, the makerspace has primarily been used by engineering students. Currently, however, the students are working hard to create events that will actively draw in students from across the university. This provides students with a co-created space for cross-disciplinary exchange as students train each other on different machines, learning alongside each other in the space. At other times, staff from different disciplines can come together to create shared opportunities for learning.
The cross-disciplinary nature of makerspaces and the universality of the desire to create encourages a diverse community to develop, with inclusivity as a core tenet. They can often provide opportunities for marginalised communities. Makerspaces such as the ‘Made in Za’atari’ space in Za’atari refugee camp have been used to give women in the camp a space in which they can utilise, share, and develop their skills both to improve wellbeing and create livelihoods. Meanwhile, projects such as Ambessa Play have provided opportunities for young people in refugee camps across the world to learn about kinetic energy and electronic components by creating a wind-up flashlight.
Spaces of inclusive learning
Maker projects also allow students to engage with their local communities, whether creating renewable energy installations, restoring community assets or educating the next generation of makers. Such projects raise the profile of sustainable development in the wider public and give students the opportunity to contribute to sustainable development in their neighbourhoods.
ESD does not just influence what we teach and how we teach; it also shapes who we are. A central tenet of ESD is that it helps to shape students, staff, and educational communities. When this happens, they are – in turn – better able to play their part in shaping the world around them.
3.2 The contribution of makerspaces
Even before the concept was popularised by the BBC’s ‘The Repair Shop’, repair cafes had begun to spring up across the country. Such facilities promote an ethos of repair and recycling by sharing of expertise amongst a community, a concept which aligns very closely with the maker movement. Items repaired might include furniture, electrical appliances, and ornaments. Related organisations like iFixit have also helped to promote responsible consumption and production through advocacy against built-in obsolescence and for the ‘Right to Repair’.
The same principles apply to Making in textiles – sustainable fashion is a topic that excites many students both within and outside engineering, and makerspaces offer the opportunity for upcycling, garment repair and clothes shares. Students can learn simple techniques that will allow them to make better use of their existing wardrobes or of used clothing and in the process begin to change the consumption culture around them. At the University of Sheffield, our making community is currently planning an upcycled runway day, in which students will bring clothing that is in need of refresh or repair from their own wardrobes or from local charity shops. Our team of peer-instructors and sewing specialists will be on hand to help students to customise, fit, and mend their clothes. In doing so, we hope to build an awareness of sustainable fashion amongst our students, enabling an upcycling fashion culture at the university.
Conclusion:
Education for Sustainable Development plays a vital role in enabling students to expand the knowledge and skills that they hold so that they can play their part in creating a sustainable future. Makerspaces offer a valuable route through which engineering students can engage with Education for Sustainable Development, including opportunities for applied learning, cross disciplinary connections, and responsible consumption.
Any views, thoughts, and opinions expressed herein are solely that of the author(s) and do not necessarily reflect the views, opinions, policies, or position of the Engineering Professors’ Council or the Toolkit sponsors and supporters.
Sustainability competency: Integrated problem-solving; Strategic; Self-awareness; Normative.UNESCO has developed eight key competencies for sustainability that are aimed at learners of all ages worldwide. Many versions of these exist, as are linked here*. In the UK, these have been adapted within higher education by AdvanceHE and the QAA with appropriate learning outcomes. The full list of competencies and learning outcome alignment can be found in the Education for Sustainable Development Guidance*. *Click the pink ''Sustainability competency'' text to learn more.
AHEP mapping: This resource addresses two of the themes from the UK’s Accreditation of Higher Education Programmes fourth edition (AHEP4): The Engineer and Society (acknowledging that engineering activity can have a significant societal impact) and Engineering Practice (the practical application of engineering concepts, tools and professional skills). To map this resource to AHEP outcomes specific to a programme under these themes, access AHEP 4 here and navigate to pages 30-31 and 35-37.
Related SDGs: SDG 8 (Decent work and economic growth); SDG 10 (Reduced Inequalities); SDG 13 (Climate action).
Reimagined Degree Map Intervention: More real-world complexity; Active pedagogies and mindset development.The Reimagined Degree Map is a guide to help engineering departments navigate the decisions that are urgently required to ensure degrees prepare students for 21st century challenges. Click the pink ''Reimagined Degree Map Intervention'' text to learn more.
Who is this article for? This article should be read by educators at all levels in higher education who wish to consider how to navigate tradeoffs between economic and environmental sustainability as they apply to engineering. Engaging with this topic will also help to prepare students with the soft skill sets that employers are looking for.
Premise:
In the face of the ever-growing need for economic progress and the escalating environmental crises, the engineering profession finds itself at a crossroads. Striking a delicate balance between economic growth and environmental sustainability is no longer an option but an imperative. This article delves into the pivotal role of engineering educators in shaping the mindset of future engineers, offering an expanded educational framework that fosters a generation capable of harmonising economic prosperity with environmental responsibility.
The uneasy truce:
Developing nations, with burgeoning populations and aspirations for improved living standards, grapple with the paradox of rapid economic expansion at the expense of environmental degradation. This necessitates a shift in focus for engineering educators, who bear the responsibility of cultivating engineers with a foresighted perspective. Rather than demonising economic growth, the goal is to instill a nuanced understanding of its interdependence with environmental well-being. For example, in developing countries like Brazil, rapid economic expansion driven by industries such as agriculture and logging has resulted in extensive deforestation of the Amazon region. This deforestation not only leads to the loss of valuable biodiversity and ecosystem services but also contributes to climate change through the release of carbon dioxide. Similarly, in industrialised nations, the pursuit of economic growth has often led to the pollution of air, water, and soil, causing adverse health effects for both humans and wildlife.
Equipping our future stewards:
To navigate this delicate landscape, educators must move beyond traditional technical expertise, fostering a holistic approach that integrates ethical awareness, interdisciplinary collaboration, localised solutions, and a commitment to lifelong learning.
1. Ethical awareness: One potential counterargument to the expanded educational framework may be that the focus of engineering education should remain solely on technical expertise, with the assumption that ethical considerations and interdisciplinary collaboration can be addressed later in a professional context. However, research has shown that integrating ethical awareness and interdisciplinary collaboration early in engineering education not only enhances problem-solving skills but also cultivates a sense of responsibility and long-term thinking among future engineers.
2. Holistic thinking: Research has shown that interdisciplinary collaboration between engineering and social science disciplines can lead to more effective and sustainable solutions. For instance, a study conducted by the World Bank’s Water and Sanitation Program (WSP) found that by involving sociologists and anthropologists in the design and implementation of water infrastructure projects in rural communities, engineers were able to address cultural preferences and local knowledge, resulting in higher acceptance and long-term maintenance of the infrastructure. Similarly, a case study of a renewable energy project in Germany demonstrated how taking into account the geographic nuances of the region, such as wind patterns and solar radiation, led to more efficient and cost-effective energy solutions. Presently, Germany boasts the world’s fourth-largest installed solar capacity and ranks amongst the top wind energy producers.
3. Localised solutions: Students must be required to consider the social, cultural, and geographic nuances of each project. This means moving away from one-size-fits-all approaches and towards an emphasis on the importance of context-specific solutions. This ensures that interventions are not only technologically sound but also culturally appropriate and responsive to local needs, fostering sustainability at both the project and community levels.
4.Lifelong learning: Empower students with the skills to stay abreast of emerging technologies, ethical frameworks, and policy landscapes. Recognise that the landscape of sustainability is dynamic and ever evolving. Foster a culture of continuous learning and adaptability to ensure that graduates remain true stewards of a sustainable future, equipped to navigate evolving challenges throughout their careers.
A compass for progress:
By integrating these principles into engineering curricula, educators can provide students with a moral and intellectual compass—an ethical framework guiding decisions toward a future where economic progress and environmental responsibility coexist harmoniously. Achieving this paradigm shift will require collaboration, innovation, and a willingness to challenge the status quo. However, the rewards are immeasurable: a generation of engineers empowered to build a world where prosperity thrives alongside a healthy planet—a testament to the true potential of the engineering profession.
Engineering teachers can raise a generation of engineers who can balance economic growth with environmental responsibility by embracing a broader educational framework that includes ethical awareness, cross-disciplinary collaboration, localised solutions, and a commitment to lifelong learning. Through the adoption of these principles, engineering curricula can provide students with a moral and intellectual compass, guiding them toward a future where economic progress and environmental sustainability coexist harmoniously.
References:
International Renewable Energy Agency (IRENA) (2023). ‘Pathways to Carbon Neutrality: Global Trends and Solutions’, Chapter 3.
Sharma, P. (2022) ‘The Ethical Imperative in Sustainable Engineering Design’, Chapter 5.
United Nations (2021) ‘Goal 13: Climate Action. In Sustainable Development Goals: Achieving a Balance between Growth and Sustainability’. (pp. 120-135).
World Bank (2022) ‘Renewable Energy in Developing Nations: Prospects and Challenges’, pp.10-15.
Any views, thoughts, and opinions expressed herein are solely that of the author(s) and do not necessarily reflect the views, opinions, policies, or position of the Engineering Professors’ Council or the Toolkit sponsors and supporters.
Topic: Pedagogical approaches to integrating sustainability.
Tool type: Knowledge.
Relevant disciplines: Any.
Keywords: Education for Sustainable Development; Teaching or embedding sustainability; Course design; AHEP; Learning outcomes; Active learning; Assessment methods; Pedagogy; Climate change; Bloom’s Taxonomy; Project-based learning; Environment; Interdisciplinary; Higher education; Curriculum.
Sustainability competency: Integrated problem-solving competency.UNESCO has developed eight key competencies for sustainability that are aimed at learners of all ages worldwide. Many versions of these exist, as are linked here*. In the UK, these have been adapted within higher education by AdvanceHE and the QAA with appropriate learning outcomes. The full list of competencies and learning outcome alignment can be found in the Education for Sustainable Development Guidance*. *Click the pink ''Sustainability competency'' text to learn more.
AHEP mapping: This resource addresses two of the themes from the UK’s Accreditation of Higher Education Programmes fourth edition (AHEP4): The Engineer and Society (acknowledging that engineering activity can have a significant societal impact) and Engineering Practice(the practical application of engineering concepts, tools and professional skills). To map this resource to AHEP outcomes specific to a programme under these themes, access AHEP 4 here and navigate to pages 30-31 and 35-37.
Related SDGs: SDG 4 (Quality education); SDG 13 (Climate action).
Reimagined Degree Map Intervention: Adapt and repurpose learning outcomes; Active pedagogies and mindset development; Authentic assessment; Cross-disciplinarity.The Reimagined Degree Map is a guide to help engineering departments navigate the decisions that are urgently required to ensure degrees prepare students for 21st century challenges. Click the pink ''Reimagined Degree Map Intervention'' text to learn more.
Who is this article for? This article should be read by educators at all levels in higher education who are seeking an overall perspective on teaching approaches for integrating sustainability in engineering education. Engaging with this topic will also help to prepare students with the soft skill sets that employers are looking for.
Premise:
As stated in the 1987 United Nations Brundtland Report, ‘sustainability’ refers to “meeting the needs of the present without compromising the ability of future generations to meet their own needs” (GH, 1987 p.242). It is underpinned by a tripartite definition encompassing environmental, social and economic sustainability. The necessity for embracing sustainability is underscored by several pressing challenges we face as a global society, ranging from climate change to economic crises.
Against the backdrop of these global challenges, the role of the engineering profession assumes significant importance. While the scientific principles that underpin the various engineering disciplines remain largely the same, the responsibility of the engineering profession is to leverage these principles to address current and future challenges. Consequently, education for sustainable development (ESD) becomes a vital aspect of an engineer’s training, since the profession will guide the design and implementation of innovative solutions to challenges crosscutting environmental impact, judicious use of resources and social wellbeing.
Integrated course design:
Integrating ESD in engineering education requires programme and module designers to take a deliberate approach. Drawing on initial attempts to integrate sustainability in management and business education (Rusinko, 2010), four pedagogical approaches of ESD can be identified:
piggybacking,
mainstreaming,
specialising,
connecting.
The last two approaches are for creating new curriculum structures with a narrow discipline-specific focus and a broad transdisciplinary focus, respectively. The other two, piggybacking and mainstreaming, are approaches to embed sustainability within existing curriculum structures. Although piggybacking is the easier-to-implement approach, achieved by additional sessions or resources on sustainability being tagged onto existing course modules, mainstreaming enables a broader cross-curricular perspective that intricately intertwines sustainability with engineering principles.
The mainstreaming approach is also an elegant fit with the accreditation requirements for sustainability; the latest edition of the Accreditation of Higher Education Programmes (AHEP) emphasises competence in evaluating ‘environmental and societal impact of solutions’ to ‘broadly-defined’ and ‘complex’ problems. In order to foster this ability, where sustainability is a guiding principle for developing engineering solutions, a holistic (re)consideration of all elements of constructive alignment (Biggs, 1996) – intended learning outcomes (ILOs), teaching and learning activities, and student assessment – is needed. To this end, the Integrated Course Design (ICD) pedagogical framework can be leveraged for a simultaneous and integrated consideration of course components for embedding sustainability.
Sustainability learning outcomes:
Bloom’s taxonomy (also see here), which conventionally guides formulation of ILOs, can be extended to incorporate sustainability-based learning outcomes. The action verb in the AHEP guidance for the learning outcome on sustainability is ‘evaluate’, signifying a high cognitive learning level. ILOs framed at this level call for application of foundational knowledge through practical, critical and creative thinking. Although the cognitive domain of learning is the main component of engineering education, sustainability competence is greater than just a cognitive ability. For more information, see the Reimagined Degree Map.
ESD is a lifelong learning process and as stated by UNESCO, it ‘enhances the cognitive, socio-emotional and behavioural dimensions of learning’. This integration of cognitive learning outcomes with affective aspects, referred to as ‘significant learning’ in the ICD terminology, is of utmost importance to develop engineers who can engage in sustainable and inclusive innovation. Furthermore, mapping programme and module ILOs to the UN Sustainable Development Goals (SDGs) is another way to integrate sustainability in engineering with connections between technical engineering competence and global sustainability challenges becoming more explicit to students and educators. Similarly, the ILOs can be mapped against UNESCO’s sustainability competencies to identify scope for improvement in current programmes. See the Engineering for One Planet Framework for more information and guidance on mapping ILOs to sustainability outcomes and competencies.
Teaching and learning activities:
Activities that engage students in ‘active learning’ are best placed to foster sustainability skills. Additional lecture material on sustainability and its relevance to engineering (piggybacking approach) will have limited impact. This needs to be supplemented with experiential learning and opportunities for reflection. To this end, design and research projects are very effective tools, provided the problem definition is formulated with a sustainability focus (Glassey and Haile, 2012). Examples include carbon capture plants (chemical engineering),green buildings (civil engineering) and renewable energy systems (mechanical and electrical engineering).
Project-based learning enables multiple opportunities for feedback and self-reflection, which can be exploited to reinforce sustainability competencies. However, with project work often appearing more prominently only in the latter half of degree programmes, it is important to consider other avenues. Within individual modules, technical content can be contextualised to the background of global sustainability challenges. Relevant case studies can be used in a flipped class environment for a more student-led teaching approach, where topical issues such as microplastic pollution and critical minerals for energy transition can be taken up for discussion (Ravi, 2023). Likewise, problem sheets or simulation exercises can be designed to couple technical skills with sustainability.
Student assessment:
With sustainability being embedded in ILOs and educational activities, the assessment of sustainability competence would also need to take a similar holistic approach. In other words, assessment tasks should interlace engineering concepts with sustainability principles. These assessments are more likely to be of the open-ended type, which is also the case with design projects mentioned earlier. Such engineering design problems often come with conflicting constraints (technical, business, societal, economic and environmental) that need careful deliberation and are not suited for conventional closed-book time-limited examinations.
More appropriate tools to assess sustainability, include scaled self-assessment, reflective writing and focus groups or interviews (Redman et al., 2021). In a broader pedagogical sense, these are referred to as authentic assessment strategies. Given the nexus between sustainability and ethics, inspiration can also be drawn from how ethics is being assessed in engineering education. Finally, pedagogical models such as the systems thinking hierarchical model (Orgill et al., 2019), can be used to inform the design of assessment rubrics when evaluating sustainability skills.
Any views, thoughts, and opinions expressed herein are solely that of the author(s) and do not necessarily reflect the views, opinions, policies, or position of the Engineering Professors’ Council or the Toolkit sponsors and supporters.
In developing the resources for the EPC’s Sustainability Toolkit, we took into account recent scholarship and best practices and reviewed existing material available on sustainability in engineering. You can find links to these online resources in our ever-growing library of engineering education resources on sustainability below. Please note, the resources linked below are all open-source. If you want to suggest a resource that has helped you, find out how on ourGet Involved page.
To view a page that only lists library links from a specific category type:
Listed below are links to resources that support educators’ awareness and understanding of sustainability topics in general as well as their connection to engineering education in particular. These have been grouped according to topic. You can also find our suite of knowledge tools, here.
Engineering Futures – Sustainability in Engineering 2023 webinars (You will need to create an account on the Engineering Futures website. Once you have created your account, navigate back to this link, scroll down to ”Sustainability in Engineering Webinars” and enter your account details. Click on the webinar recordings you wish to access. You will then be redirected to the Crowdcast website, where you will need to create an account to view the recordings.)
Any views, thoughts, and opinions expressed herein are solely that of the author(s) and do not necessarily reflect the views, opinions, policies, or position of the Engineering Professors’ Council or the Toolkit sponsors and supporters.
Author: The Sustainability Resources Library was produced by Crystal Nwagboso (Engineering Professors Council).If you want to suggest a resource that has helped you, find out how on our Get Involved page.
In developing the resources for the EPC’s Sustainability Toolkit, we took into account recent scholarship and best practices and reviewed existing material available on sustainability in engineering. You can find links to these online resources in our ever-growing library of engineering education resources on sustainability below. Please note, the resources linked below are all open-source. If you want to suggest a resource that has helped you, find out how on ourGet Involved page.
Listed below are linksto tools that are designed to support educators’ ability to measure quality and impact of sustainability teaching and learning activities. These have been grouped according to topic. You can also find our suite of assessment tools, here.
Click to view our Collaboration resources pagewhere you can find links to groups, networks, and organisations/initiatives that will support educators’ ability to learn with and from others.
Integration tools
Listed below are links to tools designed to support educators’ ability to apply and embed sustainability topics within their engineering teaching. These have been grouped according to topic. You can also find our suite of learning activities and case studies, here.
Listed below are links to resources that support educators’ awareness and understanding of sustainability topics in general as well as their connection to engineering education in particular. These have been grouped according to topic. You can also find our suite of knowledge tools, here.
Engineering Futures – Sustainability in Engineering 2023 webinars (You will need to create an account on the Engineering Futures website. Once you have created your account, navigate back to this link, scroll down to ”Sustainability in Engineering Webinars” and enter your account details. Click on the webinar recordings you wish to access. You will then be redirected to the Crowdcast website, where you will need to create an account to view the recordings.)
Any views, thoughts, and opinions expressed herein are solely that of the author(s) and do not necessarily reflect the views, opinions, policies, or position of the Engineering Professors’ Council or the Toolkit sponsors and supporters.
Author: The Sustainability Resources Library was produced by Crystal Nwagboso (Engineering Professors Council). If you want to suggest a resource that has helped you, find out how on our Get Involved page.
