VHL University of Applied Sciences (VHL) is a sustainable University of AppliedSciences that trains students to be ambitious, innovative professionals andcarries out applied research to make a significant contribution to asustainable world. Together with partners from the field, they contribute to innovative and sustainable developments through research and knowledge valorisation. Their focus is on circular agriculture, water, healthy food & nutrition, soil and biodiversity – themes that are developed within research lines in the variousapplied research groups. These themes address the challenges that are part ofthe international sustainability agenda for 2030: the sustainable developmentgoals (SDGs). This booklet contains fascinating and representative examplesof projects – completed or ongoing, from home and abroad – that are linked tothe SDGs. The project results contribute not only to the SDGs but to their teaching as well.
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Hogescholen starten in 2022 met een eigen doctoraatstraject: het Professional Doctorate. Daarmee introduceert het hbo een nieuwe beroepsopleiding waarmee het de grenzen in de beroepspraktijk wil verleggen. Kandidaten worden opgeleid tot hooggekwalificeerde professionals die leren te interveniëren in complexe vraagstukken zoals de energietransitie of de gezondheidszorg. Belangrijke en noodzakelijke toevoeging Hogescholen zien een doctoraatstraject in het hbo als een belangrijke en noodzakelijke toevoeging binnen het hoger onderwijs stelsel. Het Professional Doctorate (PD) maakt een doorlopende leerlijn van bachelor via master tot doctorate in de beroepskolom mogelijk, en wordt nauw verbonden met het overige hbo-onderwijs. Doel is dat hbo bachelor- en masterstudenten in hun onderwijs de vruchten plukken van het onderzoek van PD-kandidaten naar de laatste ontwikkelingen in de beroepspraktijk. Daarmee is de introductie van het professional doctorate ook een investering in de bredere aansluiting van het hbo op de arbeidsmarkt.
Research conducted by Universities of Applied Sciences (UASs) is frequently driven by professional practice where researchers are challenged with finding solutions to real-life problems. These real-life solutions are significantly enhanced by the participation of stakeholders. Through this inclusion and the resulting interactions, activities, and knowledge transfer, between the stakeholder and research(ers), impacts occur at a micro level. Micro impacts are the normal impacts that occur during the research process through interactions between researchers and stakeholders, that facilitate an unexpected and unplanned effect, be it positive or negative (Lykke et al. 2023, Mapping Research Activities and Societal Impact by Taxonomy of Indicators: Uniformity and Diversity across Academic Fields, Journal of Documentation, 79: 1049–70). Contribution analysis has been recognized as a viable method for evaluating micro impacts. One recognized contribution analysis framework is Kok and Schuit’s (2012, Contribution Mapping: A Method for Mapping the Contribution of Research to Enhance Its Impact, Health Research Policy and Systems, 10: 21) Contribution Mapping. It is also one of the frameworks acknowledged as conforming to several of the recommendations for evaluating UAS research impact. However, to do justice to the nature of Practice Oriented research, a new framework is needed. The purpose of this article is to test how Contribution Mapping works in real-life to answer the question: What can we learn from Contribution Mapping as an impact evaluation tool for a future UAS specific research impact evaluation framework? This article will examine the specificity of UAS research, the relevance of Contribution Mapping for evaluating UAS research, and the theoretical and practical implications of Contribution Mapping. Through inductive analysis conducted on information gleaned from interviews and focus groups, observations, challenges, and limitations are identified, and modifications suggested to take into consideration for a new framework.
The SPRONG-collaboration “Collective process development for an innovative chemical industry” (CONNECT) aims to accelerate the chemical industry’s climate/sustainability transition by process development of innovative chemical processes.The CONNECT SPRONG-group integrates the expertise of the research groups “Material Sciences” (Zuyd Hogeschool [Zuyd]), “Making Industry Sustainable” (Hogeschool Rotterdam [HRotterdam]), “Innovative Testing in Life Sciences & Chemistry” and “Circular Water” (both Hogeschool Utrecht [HUtrecht]) and affiliated knowledge centres (Centres of Expertise CHILL [affiliated to Zuyd] and HRTech, and Utrecht Science Park InnovationLab [ILab]).The combined CONNECT-expertise generates critical mass to facilitate process development of necessary energy-/material-efficient processes for the 2050 goals of the Knowledge and Innovation Agenda (KIA) Climate and Energy (mission C) using Chemical Key Technologies. CONNECT focuses on process development/chemical engineering. We will collaborate with SPRONG-groups centred on chemistry and other non-SPRONG initiatives.The CONNECT-consortium will generate a Learning Community of the core group (universities of applied science [UASs] and knowledge centres), companies (high-tech equipment, engineering and chemical end-users), secondary vocational training, universities, sustainability institutes and regional governments/network organizations that will facilitate research, demand articulation and professionalization of students and professionals.
The SPRONG-collaboration “Collective process development for an innovative chemical industry” (CONNECT) aims to accelerate the chemical industry’s climate/sustainability transition by process development of innovative chemical processes. The CONNECT SPRONG-group integrates the expertise of the research groups “Material Sciences” (Zuyd Hogeschool), “Making Industry Sustainable” (Hogeschool Rotterdam), “Innovative Testing in Life Sciences & Chemistry” and “Circular Water” (both Hogeschool Utrecht) and affiliated knowledge centres (Centres of Expertise CHILL [affiliated to Zuyd] and HRTech, and Utrecht Science Park InnovationLab). The combined CONNECT-expertise generates critical mass to facilitate process development of necessary energy-/material-efficient processes for the 2050 goals of the Knowledge and Innovation Agenda (KIA) Climate and Energy (mission C) using Chemical Key Technologies. CONNECT focuses on process development/chemical engineering. We will collaborate with SPRONG-groups centred on chemistry and other non-SPRONG initiatives. The CONNECT-consortium will generate a Learning Community of the core group (universities of applied science and knowledge centres), companies (high-tech equipment, engineering and chemical end-users), secondary vocational training, universities, sustainability institutes and regional network organizations that will facilitate research, demand articulation and professionalization of students and professionals. In the CONNECT-trajectory, four field labs will be integrated and strengthened with necessary coordination, organisation, expertise and equipment to facilitate chemical innovations to bridge the innovation valley-of-death between feasibility studies and high technology-readiness-level pilot plant infrastructure. The CONNECT-field labs will combine experimental and theoretical approaches to generate high-quality data that can be used for modelling and predict the impact of flow chemical technologies. The CONNECT-trajectory will optimize research quality systems (e.g. PDCA, data management, impact). At the end of the CONNECT-trajectory, the SPRONG-group will have become the process development/chemical engineering SPRONG-group in the Netherlands. We can then meaningfully contribute to further integrate the (inter)national research ecosystem to valorise innovative chemical processes for the KIA Climate and Energy.
Design, Design Thinking, and Co-design have gained global recognition as powerful approaches for innovation and transformation. These methodologies foster stakeholder engagement, empathy, and collective sense-making, and are increasingly applied to tackle complex societal and institutional challenges. However, despite their collaborative potential, many initiatives encounter resistance, participation fatigue, or only result in superficial change. A key reason lies in the overlooked undercurrent—the hidden systemic dynamics that shape transitions. This one-year exploratory research project, initiated by the Expertise Network Systemic Co-design (ESC), aims to make systemic work accessible to creative professionals and companies working in social and transition design. It focuses on the development of a Toolkit for Systemic Work, enabling professionals to recognize underlying patterns, power structures, and behavioral dynamics that can block or accelerate innovation. The research builds on the shared learning agenda of the ESC network, which brings together universities of applied sciences, design practitioners, and organizations such as the Design Thinkers Group, Mindpact, and Vonken van Vernieuwing. By integrating systemic insights—drawing from fields like systemic therapy, constellation work, and behavioral sciences—into co-design practices, the project strengthens the capacity to not only design solutions but also navigate the forces that shape sustainable change. The central research question is: How can we make systemic work accessible to creative professionals, to support its application in social and transition design? Through the development and testing of practical tools and methods, this project bridges the gap between academic insights and the concrete needs of practitioners. It contributes to the professionalization of design for social innovation by embedding systemic awareness and collective learning into design processes, offering a foundation for deeper impact in societal transitions.
