Spectral imaging has many applications, from methane detection using satellites to disease detection on crops. However, spectral cameras remain a costly solution ranging from 10 thousand to 100 thousand euros for the hardware alone. Here, we present a low-cost multispectral camera (LC-MSC) with 64 LEDs in eight different colors and a monochrome camera with a hardware cost of 340 euros. Our prototype reproduces spectra accurately when compared to a reference spectrometer to within the spectral width of the LEDs used and the ±1σ variation over the surface of ceramic reference tiles. The mean absolute difference in reflectance is an overestimate of 0.03 for the LC-MSC as compared to a spectrometer, due to the spectral shape of the tiles. In environmental light levels of 0.5 W m−2 (bright artificial indoor lighting) our approach shows an increase in noise, but still faithfully reproduces discrete reflectance spectra over 400 nm–1000 nm. Our approach is limited in its application by LED bandwidth and availability of specific LED wavelengths. However, unlike with conventional spectral cameras, the pixel pitch of the camera itself is not limited, providing higher image resolution than typical high-end multi- and hyperspectral cameras. For sample conditions where LED illumination bands provide suitable spectral information, our LC-MSC is an interesting low-cost alternative approach to spectral imaging.
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Our planet’s ecology and society are on a collision course, which manifests due to a contradiction in the assumptions of unlimited material growth fueling the linear economic paradigm. Our closed planetary ecosystem imposes confined amounts of space and a finite extent of resources upon its inhabitants. However, practically all the economic perspectives have been defiantly neglecting these realities, as resources are extracted, used and disposed of reluctantly (Ellen MacArthur Foundation 2015). The circular economy attempts to reconcile the extraction, production and usage of goods and resources with the limited availability of those resources and nature’s regenerative capabilities This perspective entails a shift throughout the supply chain, from material science (e g non-toxic, regenerative biomaterials) to novel logistical systems (e g low-carbon reverse logistics). Because of this, the circular economy is often celebrated for its potential environmental benefits and its usefulness as a blueprint for sustainable development (Ellen MacArthur Foundation 2017). Unfortunately, the promise of the circular economy aiming at enhanced sustainability through restorative intent and design (McDonough & Braungart 2010), is often inhibited by institutional barriers posed by the current linear economy of take, make, use and waste (Ghisellini et al. 2016). Underlying those barriers our cultural paradigm celebrates consumerism, exponential growth and financial benefit instead of human values such as diversity, care and trust. Based on a mapping exercise of the circular economy discourse in the Netherlands and an overview of international (academic) literature (Van den Berg 2020) supplemented with collaborative co-creation sessions, visiting events, conferences, giving talks and classes, we have defined a gap leading to the focus of the Professorship. First, we highlight the importance of a process approach in studying the transition from a linear to a circular economy, which is why we use the verb ‘entrepreneuring’ as it indicates the movement we collectively need to make. The majority of work in the field is based on start-ups and only captures snapshots while longitudinal and transition perspectives - especially of larger companies - are missing (Merli et al. 2019; Geissdoerfer et al. 2018; Bocken et al. 2014). We specifically adopt an entrepreneurship-as-practice lens (Thompson, Verduijn & Gartner 2020), which allows us to trace the doings – as opposed to only the sayings - of organizations involved in circular innovation. Such an approach also enables us to study cross-sector and interfirm collaboration, which is crucial to achieve ecosystem circularity (Raworth 2019). As materials flow between actors in a system, traditional views of ‘a value chain’ slowly make way for an ecosystem or value web perspective on ‘organizing business’. We summarize this first theme as ‘entrepreneurship as social change’ broadening dominant views of what economic activity is and who the main actors are supposed to be (Barinaga 2013; Calás, Smircich & Bourne 2009; Steyaert & Hjorth 2008; Nicholls 2008). Second, within the Circular Business Professorship value is a big word in two ways. First of all, we believe that a transition to a circular economy is not just a transition of materials, nor technologies - it is most of all a transition of values We are interested in how people can explore their own agency in transitioning to a circular economy thereby aligning their personal values with the values of the organization and the larger system they are a part of Second, while circularity is a broad concept that can be approached through different lenses, the way in which things are valued and how value is created and extracted lies at the heart of the transition (Mazzucato 2018). If we don’t understand value as collectively crafted it will be very hard to change things, which is why we specifically focus on multiplicity and co-creation in the process of reclaiming value, originating from an ethics of care Third, sustainability efforts are often concerned with optimization of the current – linear – system by means of ecoefficient practices that are a bit ‘less bad’; using ’less resources’, causing ‘less pollution’ and ‘having less negative impact’. In contrast, eco-effective practices are inherently good, departing from the notion of abundance: circular thinking celebrates the abundance of nature’s regenerative capacities as well as the abundance of our imagination to envision new realities (Ellen MacArthur Foundation 2015). Instead of exploiting natural resources, we should look closely in order to learn how we can build resilient self-sustaining ecosystems like the ones we find in nature. We are in need of rediscovering our profound connection with and appreciation of nature, which requires us to move beyond the cognitive and employ an aesthetic perspective of sustainability This perspective informs our approach to innovating education: aesthetics can support deep sustainability learning (Ivanaj, Poldner & Shrivastava 2014) and contribute to facilitating the circular change makers of the future. The current linear economy has driven our planet’s ecology and society towards a collision course and it is really now or never: if we don’t alter the course towards a circular economy today, then when? When will it become urgent enough for us to take action? Which disaster is needed for us to wake up? We desperately need substitutes for the current neo-liberal paradigm, which underlies our linear society and prevents us from becoming an economy of well-being In Entrepreneuring a regenerative society I propose three research themes – ‘entrepreneurship as social change’, ‘reclaiming value’ and ‘the aesthetics of sustainability’ – as alternative ways of embracing, studying and co-creating such a novel reality. LinkedIn: https://www.linkedin.com/in/kim-poldner-a003473/
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The necessity for humans inhabiting the 21st century to slow down and take time to carry out daily practices frames the discourse of this research note. We suggest reconceptualising tourist wellbeing through the concept of slow adventure, as a response to the cult of speed and as a vehicle for engaging in deep, immersive and more meaningful experiences during journeys in the outdoors. We suggest that slow adventure has the potential to improve people’s general health and wellbeing through mindful enjoyment and consumption of the outdoor experience and thus bring people back to a state of mental and physical equilibrium. In so doing, we argue that extending the concept to include discussions around the psychological and social aspects of slow adventure is needed.
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Verduurzaming van de chemische en landbouwsector is essentieel om klimaat- en circulaire doelstellingen te halen. Eén van de mogelijkheden om de chemische sector te vergroenen is om hernieuwbare grondstoffen als ‘feedstock’ voor productie te gebruiken. Biopolymeren die gemaakt worden uit hernieuwbare grondstoffen zijn een interessant groen alternatief voor fossiele plastics. Een veelbelovende groep ‘biobased plastics’ zijn polyhydroxyalkanoaten (PHA). PHAs worden door micro-organismen geproduceerd en kunnen verschillende samenstellingen hebben die de eigenschappen van dit materiaal beïnvloeden. Hierdoor zijn PHA's, blends van PHA en andere biobased materialen voor vele toepassingen geschikt te maken en derhalve een serieuze uitdager van fossiele plastics. Zodra deze biobased producten aan het einde van hun gebruikersfase komen, of als single-use materiaal in bijvoorbeeld de agrarische sector worden toegepast, is het belangrijk naast de mogelijkheden voor hergebruik en recycling inzicht te hebben in de snelheid en volledigheid van de biologische afbraak. In het voorgestelde KIEM-onderzoek wordt biologische afbraak middels industriële en kleinschalige compostering en in natuurlijke milieus bepaald. Onder verschillende omstandigheden, zoals in mariene, estuariene en zoetwatermilieus, en in verschillende bodemtypen zoals zand, klei en veenbodems wordt vastgesteld of effectieve afbraak plaatsvindt. Afbraak tot bouwstenen voor nieuwe polymeren of volledige mineralisatie, de snelheid daarvan en of mogelijk sprake is van vorming van microplastics wordt onderzocht. Stimuleren van biologische afbraak door bio-augmentatie wordt eveneens onderzocht. Een succesvol project draagt bij aan het verbeteren van de business case van zowel producenten van biobased polymeren (Paques Biomaterials) als van de maakindustrie die producten maken van deze groene ‘plastics’ (Maan Biobased Products; Happy Cups). Het projectresultaat geeft aanwijzingen over de impact die het onvermijdelijke PHA--zwerfafval zal hebben op het milieu en hoe deze impact zich verhoudt tot die van fossiel-gebaseerd zwerfplastic. Daarnaast vormt dit project ook de basis voor een nieuwe business case voor gecontroleerde end-of-life verwerkingsmethodieken.
It is known that several bacteria in sewage treatment plants can produce attractive quantities of biodegradable polymers within their cell walls (up to 80% of the cell weight). These polymers may consist of polyhydroxyalkanoates (PHA), a bioplastic which exhibits interesting characteristics like excellent biodegradation, low melting point and good environmental footprint. PHA bioplastics or PHBV are still quite expensive because cumbersome downstream processing steps of the PHAcontaining bacteria are needed before PHA can be applied in products. In this proposal, the consortium investigates the possibilities for eliminating these expensive and environmentally intensive purification steps, and as a result contribute to speeding up the up-take of PHA production of residual streams by the market. The objective of the project is to investigate the possibilities of direct extrusion of PHAcontaining bacteria and the application opportunities of the extruded PHA. The consortium of experienced partners (Paques Biomaterials, MAAN Group, Ecoras and CoEBBE) will investigate and test the extrusion of different types of PHA-containing biomass, and analyse the products on composition, appearance and mechanical properties. Moreover, the direct extrusion process will be evaluated and compared with conventional PHA extraction and subsequent extrusion. The expected result will be a proof of principle and provide an operational window for the application of direct extrusion with PHA-containing biomass produced using waste streams, either used as such or in blends with purified PHA. Both the opportunities of the direct extrusion process itself as well as the application opportunities of the extruded PHA will be mapped. If the new process leads to a cheaper, more environmentally friendly produced and applicable PHA, the proof of principle developed by the consortium could be the first step in a larger scale development that could help speeding up the implementation of the technology for PHA production from residual streams in the market.
This proposal is directed at the creation of sustainable embedding and preservation methods for biomaterials, in particular those incorporating structural colours (SCs). SCs use the interaction of light with highly ordered, nanostructured materials to generate colour. SCs are intense, angle dependent, can be polarized, non-fading and non-toxic; all characteristics with advantages over pigments. SCs can be created from bacteria, are widely found in nature and offers a route to the creation of high-performance biobased materials: i.e. ‘green’ replacements for dyes. However, naturally derived structural coloured biomaterials, particularly bacteria, require preservation or embedding – an essential step in developing durable products. The current embedding agent is an epoxy resin which is not a sustainable reagent. Indeed, there is a wider need for thermoset matrix materials and other polymers that are more environmentally friendly yet with good performance and cost. In this proposal we will develop such matrix materials using bacterial SCs as a test case and the primary application.
