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Challenges in addressing sustainability within product development

Published online by Cambridge University Press:  27 August 2025

Katharina Zumach Open the ORCID record for Katharina Zumach [Opens in a new window] ,
Sven Wehrend Open the ORCID record for Sven Wehrend [Opens in a new window]  and
Dieter Krause Open the ORCID record for Dieter Krause [Opens in a new window]
Katharina Zumach*
Affiliation:
Hamburg University of Technology, Germany
Sven Wehrend
Affiliation:
Hamburg University of Technology, Germany
Dieter Krause
Affiliation:
Hamburg University of Technology, Germany
*
katharina.zumach@tuhh.de

Abstract:

Due to climate change, sustainability has become a crucial topic in product development, while addressing it is associated with many challenges. Based on a literature review, those challenges are collected and clustered into nine categories and sub-categories defined for this purpose. Additionally, a research project is analysed. The exhibited challenges such as data availability versus influenceability, a lack of unified sustainability criteria, and decision-making trade-offs underscore the need for refined methodologies and collaboration in sustainability-oriented design. The differently sourced challenges are compared and the new challenges arising from the research project are sorted into the categories. Finally, possible reasons are discussed for why within the project only challenges from four out of nine categories are encountered.

Keywords

sustainabilityproduct developmentchallengesdesign practicedesign process

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Type
Article
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Proceedings of the Design Society , Volume 5: ICED25 , August 2025 , pp. 901 - 910
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Creative Common License - CCCreative Common License - BYCreative Common License - NCCreative Common License - ND
This is an Open Access article, distributed under the terms of the Creative Commons Attribution-NonCommercial-NoDerivatives licence (http://creativecommons.org/licenses/by-nc-nd/4.0/), which permits non-commercial re-use, distribution, and reproduction in any medium, provided the original work is unaltered and is properly cited. The written permission of Cambridge University Press must be obtained for commercial re-use or in order to create a derivative work.
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© The Author(s) 2025

1. Introduction

Due to the urgency of climate change and the associated increase in regulatory requirements, such as the European Green Deal (EGD) and the resulting policies like the Ecodesign for Sustainable Products Regulation (ESPR), sustainability in product development has become an imperative for companies. Furthermore the integration of sustainability aspects is seen as crucial to ensure long-term competitiveness (Reference Schulte and HallstedtSchulte & Hallstedt, 2017a). However, this integration is associated with challenges since there are several approaches to measure sustainability as well as various approaches to address sustainability in product development focussing on different aspects and product life phases. The development of modular product families offers additional potential with regard to sustainability, for example in relation to the realization of the R imperatives (Reference Sonego, Echeveste and Galvan DebarbaSonego et al., 2018), and a way of mastering variety-induced complexity (Reference Krause and GebhardtKrause & Gebhardt, 2023). With regard to product development, new methods are needed to integrate sustainability in design as a new target variable (Reference Schuh, Kuhn, Keuper, Patzwald, Schenk, Feucht, Kantelberg, Rossmair, Schroth, Viethen, Zeller and GuoSchuh et al., 2023). Yet, it is important to clearly identify challenges in addressing sustainability. Therefore, this paper first presents a literature review to identify challenges that arise in addressing sustainability in product development. This paper also presents challenges faced by the authors in the context of a research project for the development of sustainable aircraft cabin components and systems using a holistic understanding of sustainability. The challenges encountered in the project are then compared with the challenges found in the literature.

2. Research background

Sustainability is becoming an increasingly important issue in society, politics and business. Policy initiatives such as the EGD (Reference Krause and GebhardtEuropean Commission, 2019) are increasing the pressure on companies to assess and improve the sustainability of their own operations and products. In the EGD, the European Commission has set itself the goal of achieving net-zero emissions by 2050 and decoupling economic growth from resource consumption. To this end, the EGD is being concretised in other initiatives such as the Circular Economy Action Plan (European Commission 2020), enforcing the call for businesses to become more sustainable.

However, assessing the sustainability of a product throughout its lifecycle can be a complex, labour-intensive process, and there are many different indicators to evaluate. Regulatory requirements do also not address a uniform indicator or sustainability aspect. For example, the ESPR mentioned above explicitly addresses R-imperatives such as product durability or reusability, while the Corporate Sustainability Reporting Directive requires the measurement and disclosure of sustainability in the form of greenhouse gas emissions.

In addition to the well-known economic target values of time, cost and quality, sustainability indicators therefore need to be added as a further operational target variables, thus increasing complexity of the development process. Modularisation in general is an established approach of dealing with increasing internal complexity. It describes the targeted development of the modularity of a product, i.e. the combination of components into modules and the definition of interfaces (Reference Krause and GebhardtKrause & Gebhardt, 2023).

Modularisation can also have a positive impact on the sustainability of a product, for example by making it easier to disassemble products into modules at the end of their life cycle, so that they can be reused or recycled in a targeted way (Reference Sonego, Echeveste and Galvan DebarbaSonego et al., 2018). However, in order to adequately address these positive effects of modularisation, especially towards the end of the life cycle, a holistic view taking into account the entire life cycle is required. Such a holistic approach, which on the one hand takes into account the entire product life cycle and on the other also includes all three pillars of sustainability, brings with it various challenges.

The challenges that can go hand in hand with a holistic approach to sustainability were also identified within a research project. The aim of this project is to design sustainable, resource-efficient components and systems for aircraft cabins, focussing on the modular product architecture in particular. Together with project partners from the aviation industry and science, a holistic view of all three pillars of sustainability is being pursued across the entire product lifecycle. The project team encountered various challenges that prompted to carry out in-depth research on this topic and to see which challenges are already found in the literature and which are not.

3. Research approach

To systematically collect challenges in addressing sustainability, a brief literature review was conducted. As the topic of sustainability is continuously gaining relevance and thus numerous contributions discuss various aspects of sustainability, the initial search string already tried to narrow down the results to contributions within the field of product development. Based on the assumption that challenges in addressing sustainability arise not only in the development of modular product families, but also in the wider field of product development, we did not limit the search to modularity. Therefore, the three search fields “challenges”, “sustainability” and “product development” were defined, whereby each search field contains multiple search terms (Table 1).

Table 1. Search fields and respective search terms for the literature review

Using the online database Scopus, a query (TITLE-ABS-KEY) for the defined search fields with the respective search terms led to 12,432 results as of November 2024. The results were reduced to 5,564 entries by enforcing the explicit reference of the keywords for the search terms in the fields “sustainability” and “product development”. Deeming the number of publications still too high for detailed analysis, the keywords for the search terms were changed to be the used author keywords. This follows the assumption that author keywords are chosen consciously by the author whereas keywords also include index terms. This resulted in 582 documents found. To further ensure that the results focus on challenges connected to addressing sustainability, the search field “challenges” was narrowed to a search within title or keyword, excluding contributions mentioning the search terms only in the abstract. As the scope of this contribution lies within the field of engineering, filtering for this subarea results in a further reduction from 115 results to now 69 entries. An exclusion of duplicates leads to 67 entries that need to be analysed derived from the scopus search. Snowballing was additionally used in order to be observant of further publications relevant to the topic. The selection process started by reading the title, followed by the abstract, and then, if considered relevant, the entire contribution.

The literature review resulted in a catalogue of challenges, in which many challenges mentioned by different authors overlapped. Thus, duplicate challenges were identified and merged. With respect to their content, the challenges were then clustered into categories. The clustering of challenges found in the literature enabled their comparison with challenges encountered in the research project.

The challenges encountered in the research project are the result of subjective observations and reflections by the project team. With the project focus on researching and designing sustainable, resource-efficient components and systems, challenges mainly occurred concerning sustainable product design itself and not as much the implementation into operational processes. The challenges were discussed repeatedly but informally during project meetings, both in joint workshops between the project partners and in status meetings. They were listed and systematized for the comparison with the challenges found in the literature.

4. Categorisation and comparison of challenges

The following section provides an overview of the results from the literature review, clustered into nine categories building on the challenges and five categories introduced by Dekoninck (2016). This is followed by a comparison of challenges derived from the literature and the challenges encountered in the research project.

4.1. Challenges derived from the literature and categorisation

The literature review resulted in the collection of 72 challenges that can be grouped into the nine categories which is visualised in Figure 1. Each category is further divided into two to five sub-categories, which are briefly described below with the help of exemplarily picked challenges.

Figure 1. Overview of categories and number of challenges therein

Challenges that are connected to a company’s strategy can be grouped into three sub-categories. In terms of management decision and support, a lack of management commitment and support hinders the transition to sustainable product development as measures to implement sustainability are not prioritized and support is not consistent (Reference Dekoninck, Domingo, O'Hare, Pigosso, Reyes and TroussierDekoninck et al., 2016; Reference Gröbe-Boxdorfer and EngelnGröbe-Boxdorfer & Engeln, 2023; Reference Schulte and HallstedtSchulte & Hallstedt, 2017a; Reference Wang, Burke and ZhangWang et al., 2022). For a successful implementation., a clear division of responsibilities is needed additional to management support, as otherwise it can be difficult to know which department should house the implementation activities (Reference Dekoninck, Domingo, O'Hare, Pigosso, Reyes and TroussierDekoninck et al., 2016). In order to develop a long-term strategy, environmental topics need to be integrated into management and corporate strategy (Reference Dekoninck, Domingo, O'Hare, Pigosso, Reyes and TroussierDekoninck et al., 2016). Furthermore, to integrate sustainability aspects into product development, new business models and solutions that take into account the entire product life cycle are needed (Reference Hallstedt, Isaksson, Nylander, Andersson and KnutsHallstedt et al., 2023).

On the level of operations , the integration into the product development process is considered difficult in terms of the implementation of activities into the process (Reference Dekoninck, Domingo, O'Hare, Pigosso, Reyes and TroussierDekoninck et al., 2016). On one hand, this might be due to problems fitting with timescales of the process, on the other hand, it could be connected to the lack of systematic approach for the implementation throughout the entire company (Reference Dekoninck, Domingo, O'Hare, Pigosso, Reyes and TroussierDekoninck et al., 2016). Especially early on in the development process, the involvement of different stakeholders is difficult, as is the management of their expectations (Reference Dekoninck, Domingo, O'Hare, Pigosso, Reyes and TroussierDekoninck et al., 2016). Sustainability aspects should already be included in the planning phase of the product development process (Reference Paulson and SundinPaulson & Sundin, 2019). Nonetheless, the management of customer requirements concerning sustainability can be challenging (Reference Dekoninck, Domingo, O'Hare, Pigosso, Reyes and TroussierDekoninck et al., 2016).

Challenges related to society and culture as well as organizational culture can be categorized into societal challenges, company-internal inhibitions, policies and regulations, infrastructure and customer acceptance. On a societal level, environmental impacts have yet to be seen as a global target, so that sustainability becomes a goal to be met (Reference Dekoninck, Domingo, O'Hare, Pigosso, Reyes and TroussierDekoninck et al., 2016). On the company level, there exist inhibitions that result in inertia and a lack of motivation for change (Reference Dekoninck, Domingo, O'Hare, Pigosso, Reyes and TroussierDekoninck et al., 2016; Reference Gröbe-Boxdorfer and EngelnGröbe-Boxdorfer & Engeln, 2023). Policies and regulations set the framework for industrial practices. Both a lack of governmental action and support hinder the transition towards sustainable product development (Reference Wang, Burke and ZhangWang et al., 2022). In addition to governmental support, a suitable infrastructure needs to be created, e.g. to support circular resource flows (Reference Wang, Burke and ZhangWang et al., 2022). Additionally, customer acceptance ensures the companies’ economic continuity. Especially in regard to circular products and services’, concerns regarding the performance, quality or safety remain on the customers’ side (Reference Wang, Burke and ZhangWang et al., 2022).

In the category collaboration , awareness-raising and communication are important for the implementation of sustainability activities into the development process and the value chain (Reference Dekoninck, Domingo, O'Hare, Pigosso, Reyes and TroussierDekoninck et al., 2016; Reference Paulson and SundinPaulson & Sundin, 2019). Thereby, communication among stakeholders with different expertise, be it company-internal or -external stakeholders, is difficult (Reference Dekoninck, Domingo, O'Hare, Pigosso, Reyes and TroussierDekoninck et al., 2016). For the internal collaboration within a company, multidisciplinary as well as multi-department collaboration is needed, even though it can be difficult to collaborate between different departments (Reference Dekoninck, Domingo, O'Hare, Pigosso, Reyes and TroussierDekoninck et al., 2016; Reference Gröbe-Boxdorfer and EngelnGröbe-Boxdorfer & Engeln, 2023). For the collaboration within the value chain, the identification of stakeholders from the value chain to be included in the sustainability efforts is challenging (Reference Dekoninck, Domingo, O'Hare, Pigosso, Reyes and TroussierDekoninck et al., 2016). Companies experience a lack of control over sustainability aspects throughout the whole value chain and need to ensure the fulfilment of sustainability requirements within the value chain (Reference Paulson and SundinPaulson & Sundin, 2019; Reference Schulte and HallstedtSchulte & Hallstedt, 2017a).

The category data availability can be divided into four sub-categories. In the sub-category of sustainability assessment and quantification, one challenge is the definition of criteria used to assess sustainability. On the one hand, there is a variety of criteria that could be applied, on the other hand, sustainability remains hard to quantify and measure which results in a lack of applicable criteria for deciding on the most sustainable solution difficult (Reference Schulte and HallstedtSchulte & Hallstedt, 2017a). The missing transparency of decisions and their impact on sustainability hinders the communication to designers and engineers (Reference Hallstedt, Isaksson, Nylander, Andersson and KnutsHallstedt et al., 2023). In terms of data collection and depth of analysis, especially the early stage of product development, the fuzzy front end, poses challenges (Reference Chang, Lee and ChenChang et al., 2014). Finding the environmental impact data required is difficult and there is not enough specified information, e.g. to support the definition of goals and scopes (Reference Chang, Lee and ChenChang et al., 2014; Reference Dekoninck, Domingo, O'Hare, Pigosso, Reyes and TroussierDekoninck et al., 2016; Reference Gröbe-Boxdorfer and EngelnGröbe-Boxdorfer & Engeln, 2023). The data quality influences the results of the assessment, which makes the assessment itself sensitive to uncertainties (Reference Chang, Lee and ChenChang et al., 2014). In terms of inherent risk properties, the challenge of quantification refers to the difficulty of expressing the sustainability risks in numbers and to connecting them with other attributes such as profitability, which ultimately leads to a vague connection between short-term and long-term effects (Reference Schulte and HallstedtSchulte & Hallstedt, 2017b).

Different challenges arise connected to resource allocation , more specifically to the allocation of data (cf. data availability), money, time, and expertise. Money is needed for example for investment in larger innovation projects, as there are start-up costs to be dealt with (Reference Held, Weidmann, Kammerl, Hollauer, Mörtl, Omer and LindemannHeld et al., 2018; Reference Skjøndal BarSkjøndal Bar, 2015; Reference Wang, Burke and ZhangWang et al., 2022). If no extra time is allocated for new process steps and initiatives, steps such as the assessment of sustainability, the redesign of components and the search for suppliers that provide sustainable solutions are not implemented (Reference Paulson and SundinPaulson & Sundin, 2019). The lack of expertise is two-fold. Employees often do not have the necessary level of sustainability knowledge (Reference Dekoninck, Domingo, O'Hare, Pigosso, Reyes and TroussierDekoninck et al., 2016; Reference Gröbe-Boxdorfer and EngelnGröbe-Boxdorfer & Engeln, 2023; Reference Paulson and SundinPaulson & Sundin, 2019; Reference Skjøndal BarSkjøndal Bar, 2015; Reference Wang, Burke and ZhangWang et al., 2022). Additionally, there is a lack of common definition or shared understanding of the term sustainability within companies (Reference Gröbe-Boxdorfer and EngelnGröbe-Boxdorfer & Engeln, 2023; Reference Schulte and HallstedtSchulte & Hallstedt, 2017a, Reference Schulte and Hallstedt2017b).

Challenges concerning method or tool support either refer to the selection or the implementation and application of tools or methods. For the method or tool selection, criteria are needed to identify the most appropriate tool or method (Reference Dekoninck, Domingo, O'Hare, Pigosso, Reyes and TroussierDekoninck et al., 2016; Reference Held, Weidmann, Kammerl, Hollauer, Mörtl, Omer and LindemannHeld et al., 2018). The implementation and application pose challenges, which can be seen from the fact that many tools are not used in industrial practice (Reference Hallstedt, Isaksson, Nylander, Andersson and KnutsHallstedt et al., 2023; Reference Held, Weidmann, Kammerl, Hollauer, Mörtl, Omer and LindemannHeld et al., 2018; Reference Skjøndal BarSkjøndal Bar, 2015). Furthermore, the implementation of new tools into the development process is difficult and there is also a need for new tools, e.g. for tools that are able to give an overview of the impact of different design alternatives and how conflicting goals can be dealt with (Reference Dekoninck, Domingo, O'Hare, Pigosso, Reyes and TroussierDekoninck et al., 2016; Reference Schulte and HallstedtSchulte & Hallstedt, 2017a).

Results from the application of methods, e.g. results of sustainability assessment methods such as life cycle assessment (LCA), are not immediately applicable for decision making (Reference Dekoninck, Domingo, O'Hare, Pigosso, Reyes and TroussierDekoninck et al., 2016). The assessment results are therefore mainly used for reporting instead of for product improvements (Reference Held, Weidmann, Kammerl, Hollauer, Mörtl, Omer and LindemannHeld et al., 2018). Using sustainability knowledge to support decision making across different functions poses a challenge concerning decision making in the product development process (Reference Dekoninck, Domingo, O'Hare, Pigosso, Reyes and TroussierDekoninck et al., 2016). Furthermore, trade-offs exist within different sustainability criteria themself as well as between sustainability goals and economic goals. There is a perceived inherent conflict between sustainability and financial goals and the connection to cost and value is vague (Reference Schulte and HallstedtSchulte & Hallstedt, 2017a, Reference Schulte and Hallstedt2017b). As the relation between sustainability and profitability is not obvious and the customers’ willingness to pay is unclear (Reference Held, Weidmann, Kammerl, Hollauer, Mörtl, Omer and LindemannHeld et al., 2018; Reference Schulte and HallstedtSchulte & Hallstedt, 2017a), sustainability still is seen rather as a add-on than a necessity (Reference Gröbe-Boxdorfer and EngelnGröbe-Boxdorfer & Engeln, 2023). On top of that, there is no formalized approach to handle trade-offs and the quantification and measurement of sustainability is, as discussed above, challenging (Reference Schulte and HallstedtSchulte & Hallstedt, 2017a).

In terms of methodological complexity , sustainability in itself is generally seen as complex, as it is interwoven with societal and economic processes (Reference Gröbe-Boxdorfer and EngelnGröbe-Boxdorfer & Engeln, 2023). As described above, the implementation and assessment of sustainability is difficult, especially in early phases. With the limitation of time and of data available in the early design stages, the integration of sustainability needs to be done without compromising the completeness of sustainability assessment and improvements (Reference Hallstedt, Isaksson, Nylander, Andersson and KnutsHallstedt et al., 2023). The technology-induced complexity is connected to the need to address new types of needs and simultaneously integrate new types of technologies with high potential for increasing sustainability in process or product (Reference Hallstedt, Isaksson, Nylander, Andersson and KnutsHallstedt et al., 2023). Product-induced complexity is related to understanding the product’s effect on the environment (Reference Balkenende and BakkerBalkenende & Bakker, 2015). Especially technologically advanced products such as electronics entail an intrinsic complexity, that can pose challenges for example for end-of-life treatment (Reference Balkenende and BakkerBalkenende & Bakker, 2015). Lastly, the lifespan of a product influences the pace of change. Especially products with long life spans, such as machinery, constitute long-lasting investments, that can cause a lock-in preventing investment in new environmentally better solutions (Reference Skjøndal BarSkjøndal Bar, 2015).

Table 2 summarizes the categories and sub-categories as well as the references in which challenges, that are grouped into the respective category, are mentioned. Below the table, the challenges encountered in the research project are described and compared to the challenges from the literature.

Table 2. Categories and sub-categories of challenges in addressing sustainability

4.2. Challenges encountered in the project compared with the literature

The first challenge encountered in the project is the contradiction between influenceability and data availability. Especially at the beginning of a development project in the conceptual design phase, when many decisions have not yet been made, sustainability can be strongly influenced (Reference Han, Jiang and ChildsHan et al., 2021). In contrast, assessing sustainability at this stage is afflicted with inaccuracies as the product is still vague and therefore assumptions have to be made. The assessment is furthermore dependent on the individual company processes. This gives rise to the following question: At which point in the development process is the influenceability of the different sustainability aspects constrained by decisions. For example, material selection can be decided early on in order to narrow the sustainable design space (Reference HallstedtHallstedt, 2017) and the materials themselves can be assessed, but the final sourcing decision is often not in the responsibility of product development. Decisions about the sourcing of raw materials, semi-finished products and components, which are relevant to social sustainability, are finalised later in the process, when the product is sufficiently concrete. The suppliers can also change after start of production which impacts the product’s sustainability assessment. Decisions on different functional principles, which can strongly influence the efficiency of a product in its use phase, are made at an early stage and therefore have to be decided on the basis of vague data. This is confirmed by the challenges relating to data availability that are mentioned in the literature, especially concerning the limitation of data in the early stage of product development (Reference Chang, Lee and ChenChang et al., 2014; Reference Hallstedt, Isaksson, Nylander, Andersson and KnutsHallstedt et al., 2023) and the challenge of finding a balance between simplification and potential loss of accuracy, reliability, or quality (Reference Dekoninck, Domingo, O'Hare, Pigosso, Reyes and TroussierDekoninck et al., 2016). However, the challenge of unclear influenceability of aspects could be added to highlight the contradiction between influenceability and data availability.

The consortium within the research project consists of four project partners. Both on company/university level as well as on an individual level, everyone had a unique understanding of sustainability. This goes in hand with the lack of a common definition of sustainability, as described by Reference Gröbe-Boxdorfer and EngelnGröbe-Boxdorfer and Engeln (2023) as well as Schulte and Hallstedt (2017a, 2017b). To overcome this challenge, various definitions of sustainability as well as sustainability criteria were researched by the different research partners. They were compiled and compared in several joint workshops. This aimed towards sharing a joint understanding of sustainability within the project and in the context of the aviation industry.

When researching sustainability criteria within the project, a variety of different criteria and indicators, from quantitative to qualitative, were found. However, there was no consistency in the information provided to explain the different criteria, nor was there a catalogue of criteria and indicators with support or guidelines on when to use which indicator in terms of solution space within the product development process. This confirms the challenges within the sub-category of sustainability assessment and quantification. That is, that sustainability is hard to quantify and the transformation of sustainability goals into measurable requirements remains subject of research (Reference Paulson and SundinPaulson & Sundin, 2019; Reference Schulte and HallstedtSchulte & Hallstedt, 2017a, Reference Schulte and Hallstedt2017b).

The challenge of the lack of sustainability criteria that was perceived by the companies in the questionnaire study of Reference Schulte and HallstedtSchulte and Hallstedt (2017a), which aimed at identifying preconditions and capabilities for the integration of sustainability in product development, first seems to be in contrast to the variety of criteria found within the research project. However, as explained by Reference Schulte and HallstedtSchulte and Hallstedt (2017a), the lack of sustainability criteria refers to the lack of approach or applicable criteria for identifying and deciding the most sustainable solution. This strengthens the other challenges mentioned in terms of the quantification of sustainability and its translation into specific requirements. No single criteria of sustainability can be found, as sustainability entails different dimensions and therefore many different aspects. The phrasing could therefore be changed to lack of (directly applicable) criteria or lack of criteria to find sustainable solution, which would then entail the variety of criteria within the literature and the difficulty for companies to choose a criterion. Additionally, the challenge of the lack of support for choosing sustainability criteria could be added, analogously to the lack of criteria for selecting the most suitable tools or methods mentioned in Reference Dekoninck, Domingo, O'Hare, Pigosso, Reyes and TroussierDekoninck et al. (2016) and Reference Held, Weidmann, Kammerl, Hollauer, Mörtl, Omer and LindemannHeld et al. (2018). In connection with the above-mentioned contradiction between influenceability and data availability, the selection of criteria should be focused on aspects that can be influenced by the decision maker. In early design stages, for example, it can be helpful to relate the sustainability criteria to the different levels of the product architecture as described by Reference Wehrend, Schwan, Zumach and KrauseWehrend et al. (2024).

Within the realm of decision making, sustainability goals add further requirements that have to be taken into account. Therefore, as mentioned in the literature, trade-offs arise (Reference Dekoninck, Domingo, O'Hare, Pigosso, Reyes and TroussierDekoninck et al., 2016; Reference Schulte and HallstedtSchulte & Hallstedt, 2017a). This was also encountered within the project as different criteria are evaluated and therefore target-conflicts emerge. In the context of aviation, the product life cycles or, more precisely, the time in use of the product is long, as aircrafts are usually operated for roughly 30 years. Due to the long time in use and the fuel consumption during operation, the use phase is currently the phase in which most emissions are emitted. As mentioned by Reference Skjøndal BarSkjøndal Bar (2015) the product influences the possible pace of change. In the context of sustainability and criteria to be applied, the type of product also influences the levers that should be applied to improve the product’s sustainability. Currently, weight is the determining factor to evaluate sustainability in the aviation industry. No alternative concept would be implemented, if it was heavier than another. In the aviation industry, the following question therefore arises: When will the shift in perspective happen when weight is not enough? The information about product types and a respective categorisation of methods, as proposed by O’Hare and McAloone (2014), would hereby support the selection of suitable methods. Therefore, the challenge of a lack of support in choosing tools or methods (Reference Held, Weidmann, Kammerl, Hollauer, Mörtl, Omer and LindemannHeld et al., 2018) is encountered in the research project.

To summarize the challenges encountered in the research project, they are visualised in Figure 2.

Figure 2. Challenges encountered in the research project and sorted into the categories

Figure 2 shows that the main challenges in the project can be sorted into the four categories data availability, resource allocation, method or tool support, and decision making. The other five categories remain unchanged and are briefly discussed below. The icon on the left of the challenge indicates its origin. The books represent a challenge derived from the literature review. The pencil marks a challenge that was found in the literature but was slightly adapted in wording. The star represents a challenge that was encountered in the research project but not found in the literature review.

Challenges in the category strategy focus on the strategic considerations and decisions on the corporate level of a company. In contrast, work on a research project is associated with methodological aspects. Therefore, the strategic challenges were not encountered in the project, even though they may exist for the companies of the industrial partners. The fact that no challenges arose in the project with regard to operations can be attributed to the fact that it is a research project, meaning that the activities are not subordinate to the general product development process of the industrial partners, but are detached from it. The same applies to the category Society or (organizational) culture, as the research activities take place to a certain extent away from the daily business. Potential contact with internal resistance tends to take place later, when results are to be transferred into the development process. Within the scope of the project, no challenges in collaboration arose which might be attributed to the nature of researching somewhat apart from operational business. Having a methodical research background, the challenges associated with complexity are recognized, but not directly perceived as hurdles by the researchers.

5. Conclusion and outlook

This contribution presents the results from a literature review concerning challenges in addressing sustainability in product development. The challenges found in the literature were clustered into nine categories, namely the categories strategy, operations, society or (organizational) culture, collaboration, data availability, resource allocation, method or tool support, decision making, and complexity. The challenges from the literature were furthermore complemented by and compared to experiences from a research project. Out of ten challenges identified in the research project, seven were identical to challenges mentioned in the literature. For one existing challenge a slight change in wording was proposed. The two additional challenges that were identified were furthermore assigned to the categories. Lastly, it was discussed why in the project there were only found challenges from some of the categories and not from all of them.

Concerning the limitation of this contribution, the conducted literature review concentrated on contributions that explicitly focused on identifying and discussing challenges. However, foundational publications about sustainability in product development could also be analysed in regard to challenges met. The literature review conducted in this study therefore needs to be extended to a systematic literature review including fundamental publications about sustainability. Furthermore, the collection of challenges encountered in the research project is the subjective perception of the project members and could therefore be limited to the project context. Hence, an interview study in the companies of the project partners would be beneficial to further explore the challenges in addressing sustainability and verify whether the challenges encountered in the project generally apply.

The challenges identified in relation to addressing sustainability in product development highlight the multifaceted nature of sustainability. This is also reflected in the different categories to which the identified challenges have been assigned. Addressing sustainability in product development brings new objectives and thus additional complexity to the development process. This leads to different areas for future research. Especially the category data availability, which encompasses challenges associated with the assessment of sustainability, poses room for further investigations as with twelve challenges it contains the highest number of challenges therein. On one hand, there is a need for support in selecting suitable sustainability indicators and mapping existing approaches to improving sustainability to these indicators. On the other hand, supporting decision making in the context of sustainability should be further researched. This involves dealing with uncertain data in the early stages of product development on the one hand, and with trade-offs between sustainability and economic efficiency as well as between sustainability criteria on the other. The challenges in the category strategy should furthermore be analysed and targeted more in depth, as they lay the foundations for the successful implementation of sustainability measures in the company.

Acknowledgement

The presented research is based on the results of the project “RECab - Resource Efficient Cabin (FKZ: 20K2103E)” and is funded by the Federal Ministry for Economic Affairs and Climate Action (BMWK) as part of the sixth Civil Aeronautics Research Program (LUFO VI-2).

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Figure 0

Table 1. Search fields and respective search terms for the literature review

Figure 1

Figure 1. Overview of categories and number of challenges therein

Figure 2

Table 2. Categories and sub-categories of challenges in addressing sustainability

Figure 3

Figure 2. Challenges encountered in the research project and sorted into the categories