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Campus Academy
Oostergoweg 9
8911 MA Leeuwarden
+31 (0)58 284 30 00
info@wetsus.nl

research
and analytical facilities

Research facilities

  • -80 °C freezer
  • Amplicon sequencing
  • Anaerobic glove box
  • Automated research fume hoods with PLC and SCADA
  • Automatic film applicator
  • Automated dip coater
  • Ball mill
  • Bead beater with cryolys cooling system (mechanical cell
    disruption)
  • Biobench algae flatpanel reactor systems
  • Biofouling monitors with and without water production
  • Biological safety cabinets (HEPA filtered)
  • Black water, urine and water storage tanks
  • Climate unit/Indoor Plant Growth Room
  • CNC mill
  • Continuous and batch reactors
  • Cooling and heating compartments
  • Cutting plotter
  • Soldering station
  • Doppler echo imaging system
  • Extruder for bioplastics
  • Fermentation equipment
  • Filament and resin 3D printers
  • Flat sheet membrane production
  • Freeze dryer
  • Fully equipped electrotechnical station
  • Fully equipped optical lab facility
  • GAP fume cabinets
  • Gas and sewage water distribution network
  • High voltage lab
  • High-speed cooled centrifuge
  • Hot rolling press/calendering machine
  • Knife mill
  • Labopress (molding and pressing)
  • Laboratory eStretching machine / membrane spinning
    device
  • Laboratory information management system (LIMS)
  • Laser cutter
  • Metagenomics
  • ML-II level advanced microscopy lab
  • ML-II level microbiology lab
  • Multi-channel potentiostats
  • Nanofiltration system (pilot scale)
  • Online process control
  • Respirometer
  • Safety precaution measurements and systems
  • Safety vacuum drying oven
  • Shaking incubators (hot, cold, light)
  • Sonication equipment
  • Temperature monitoring system (sample quality control)
  • Transcriptomics (RNA sequencing)
  • Tube furnace
  • Ultra Turrax homogenizer
  • Ultrasonic underwater inspection system
  • Walk-in fume cupboards
  • Welding equipment for foils and exotic metals
  • Whole-genome sequencing
  • Moisture analyzer

Analytical equipment

  • μ-GC (biogases)
  • Spectrophotometric absorbance/fluorescence/
    luminescence platereader
  • AFM (atomic force microscopy)
  • CO2 precision analyzers
  • CLSM (confocal laser scanning microscopy)
  • CPD (critical point dryer for SEM microscopy)
  • DSC (differential scanning calorimetry)
  • Dynamic and monotonic titration systems
  • EA (elemental analyzer)
  • Flowcytometer (total and targeted cell enumeration)
  • FT-IR (Analysis/identification of composition of solids,
    liquids)
  • FEEM (fluorescence excitation emission matrix
    spectrophotometer)
  • GC-FID, GC-FPD, GC-MS/MS (gaschromatography,
    pyrolysis & HTS autosampler)
  • Gel electrophoresis (DGGE, DNA, protein)
  • Gel imaging system
  • High-speed camera and image acquisition
  • IC (ion chromatography of anions, cations & fatty acids)
  • ICP-OES (elemental analysis, option to microwave
    digestion)
  • Ultrasensitive Triple Stage Quad LC-MS/MS
  • High Resolution Accurate Mass Orbitrap LC-MS/MS (for
    non-targeted screening)
  • LC-OCD (liquid chromatography organic carbon detection
    system)
  • Microscopy: Brightfield, DIC, fluorescence (inverse and
    upright), phase contrast
  • MinIon (mobile long-read sequencing)
  • Nanodrop spectrophotometry (nucleic acid quality
    assessment)
  • OCT (optical coherence tomography)
  • Particle sizing 1-1000 nm asymmetric field flow fraction-
    MALS
  • Particle sizing (50-1500 nm, including zeta potential)
  • qPCR (quantitative real-time polymerase chain reaction)
  • Quantus (fluorometer for nucleic acids and proteins
    quantification)
  • Raman spectrometry system
  • Rheometer
  • High Resolution SEM-EDS (scanning electron microscopy
    combined with elemental analysis)
  • Spectrophotometric analyzers
  • Surface area and porosity analyzer
  • TGA (thermogravimetric analysis)
  • Thermocycler for PCR (polymerase chain reaction)
  • Carbon analyzer (TC, IC, NPOC, TOC and TN)
  • UHPLC UV/VIS
  • Vacuum filtration systems
  • Viscosity meter
  • Thermographic infrared camera system
  • Thermal conductivity sensor system
Combining scientific excellence with commercial relevance
Oostergoweg 9
8911 MA Leeuwarden
+31 (0)58 284 30 00
info@wetsus.nl
wetsus logo white

Towards an economy of value preservation | By Niels Faber

Abstract

The realisation of a circular economy has thus far unfolded under the assumption that it would fit within existing economic arrangements. In practice, we witness many circular initiatives struggling to give shape to their ambitions, let alone develop to maturity. These past months, various material recycling organisations terminated their activities, seeing virgin alternatives from other parts of the world flooding the market at prices against they cannot compete. If the transition towards a circular economy (i.e. an economy of value preservation) is to be taken seriously, a new perspective on value in our economic system seems unavoidable, as the rewriting of the rules of the economic game. At this moment, current perceptions of value stand in the way of this transition both at micro as well as macro levels. Several contours for a collective exploration of new directions of value and economic configuration that foster circular transition will be addressed.

Searching Innovation for the Common Good | By Cees Buisman

Abstract

In his key note he will conclude after a life of innovations that it is impossible that humanity will stay within the save planetary boundaries with innovation only. We should be more critical about the behaviour of the rich population in the world and more critical about new innovations that prove to be dangerous, like the PFAS crisis shows at this moment. In his keynote he will investigate how to look at the world that can stay within the save planetary boundaries, how should we change ourselves? It is clear if we only talk about the words of science and systems we miss the essential words of how we should cooperate and change ourselves. And his search for coherent save innovations. Which innovations will be save and will lead to a fair and sustainable world? And will lead to a world we want to live in.

Future-fit economic models: What do they have in common – how can they join forces? | By Christian Felber

Abstract

There is a growing number of new sustainable, inclusive, cohesive, participatory, just and humane economic models. A possible next step in the discourse about them is the comparative analysis in order to find out key commonalities, potential synergies, and “requirements” for a future-fit economic model. The author and initiator of the Economy for the Common Good provides an overview of these „new sustainable economic models“ and compares them according to underlying values, principles, and practical ways of implementation. The keynote addresses the cooperative spirit of the conference and prepares the ground for its public highlight on the eve of June 3rd, the round table with representatives of diverse future-fit economic models.

The era of postgrowth economics | By Matthias Olthaar

Abstract

The scientific debate on whether economies should always continue to grow increasingly becomes a political and societal debate. On the one hand further growth for the most affluent countries seems neither possible nor valuable, but on the other hand there is still lack of understanding and knowledge what a non-growing economy should look like and could best be governed. In this lecture we discuss various policy measures that can be realistically implemented, take into account government finances and aim at a higher quality of life despite a non-growing economy.

Democratic principles for a sustainable economy | By Lisa Herzog

Abstract

Democracy is under pressure, and less and less able to stir the economy into a sustainable direction. Therefore, to stabilize democracy and to make possible the socio-ecological transformation of the economy, democratic principles need to be implemented directly in the economy. This is not only a matter of morality, but also has practical advantages. Democratizing the economy can increase legitimacy and take advantage of the “knowledge of the many” to accelerate the transformation. Democratic practices, especially deliberation, allow bringing together different forms of knowledge, which is crucial for the local implementation of principles of social and ecological sustainability. This talk explores what this idea means in more concrete terms, from democratic participation in the workplace to the democratization of time.

Market, state, association, and well-being. An historical approach | By Bas van Bavel

Abstract

Over the past decades, markets have conventionally been seen as the best instrument to stimulate economic growth and enhance prosperity and well-being. The automatic link between markets and economic growth is increasingly questioned, however, as well as the automatic link between economic growth and enhancement of well-being. This has led to attempts to capture well-being development more directly than through GDP per capita figures and has produced a more variegated picture of well-being growth. Also, this has led to a shift of focus to other coordination systems than the market, as primarily the state but increasingly also the association. Analyses of the historical record suggest that especially the latter could be a vital component in future well-being.