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'''Air/water jet machining'''
'''Air/water jet machining'''
[[File:Plasma Treatment.jpg|thumb|(left) PDMS microfluidic chips and glass placed inside plasma system. (right) Plasma generated inside the system to activate PDMS and glass surfaces  ]]
[[File:Bonding of PDMS and glass for fabrication of microfluidic device.jpg|thumb|Bonding of PDMS and glass for fabrication of microfluidic device]]


==Bonding==
==Bonding==
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'''PDMS/PDMS and PDMS/glass bonding'''
'''PDMS/PDMS and PDMS/glass bonding'''
[[File:Contact Angle Plasma Tretament vs Time.jpg|1000px|thumb|center|Pictures of contact angle for water drop on PDMS and borosilicate glass after plasma treatment in the PDMS lab at DTU for different time]]
[[File:Contact Angle Plasma Tretament vs Time.jpg|1000px|thumb|center|Pictures of contact angle for water drop on PDMS and borosilicate glass after plasma treatment in the PDMS lab at DTU for different time]]


'''PDMS/PMMA bonding'''
'''PDMS/PMMA bonding'''

Revision as of 15:58, 16 July 2026



THIS PAGE IS UNDER CONSTRUCTION

Unless otherwise stated, all content on this page was created by Claudia Chaves Villarreal, DTU Nanolab

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PDMS Lab at DTU Nanolab

Polydimethylsiloxane (PDMS), also known as silicone, has become a fundamental material for fabricating microfluidic devices with applications in health, chemistry, biomedical sciences and more.

DTU Nanolab has a dedicated laboratory for the processing of PDMS and fabrication of microfluidics located in building 347. The PDMS Lab is part of the PolyFabLab and has been equipped with brand-new instruments funded by the Novo Nordisk Foundation, alongside selected equipment and processes from previous facilities.

The laboratory has 4 different areas:

1. Non-cured PDMS: All mixtures of PDMS resin and curing agent are prepared on this area. Cellophan film is provided and must be placed on the table ALWAYS when working with uncured PDMS.

2. Cured PDMS: Only cured PDMS can be handled in this area.

3. Fume hood: safe area for handling volatile chemicals that are hazardous for human and environment health. The spin-coating machine and the hazardous waste are also located in this area.

4. Plasma machine: equipment to condition the surfaces for bonding of parts in microfluidic devices.

5. Storage area: to store chemicals, samples, sample holders, tools, and materials.

6. Personal protective equipment and emergency shower equipment: googles, lab coats, emergency shower and eyewasher are provided for the safety of lab users

Material requirements

Process flow

Mixing PDMS resin and degassing

Soft lithography micro molding

Mold surface conditioning

Molding by pouring

Molding by spin coating

Baking – Curing

Photograph of a PDMS microfluidic wafer after curing and demolding

The PDMS can cure without heating in ~24 hours. Curing the PDMS at higher temperatures in the oven can decrease the time spent curing. The temperatures between 60°C to 100°C can be used, and the choice must be optimized for the specific device design, and the desired mechanical and surface properties. The curing time depends on the temperature and the thickness of PDMS. As a standard procedure to cure PDMS, place the casted PDMS on the mold in the oven for at least 2 hours at ~80°C.

Demolding

After curing, the PDMS microfluidic chip is a solid and chemically inert material. Once cooled, the PDMS is easily peeled off from the mold. The demolding and further processes of cured PDMS must be done in the designated “cured PDMS”. If the demolding does not occur readily, wetting it with isopropanol or ethanol might be helpful. Otherwise, the mold must be conditioned properly before casting the PDMS.

3D printing

Example of a 20 mm commercial puncher used to cut individual chips out of a PDMS microfluidic wafer

Cutting PDMS

Punching

Create access ports, also known as through-holes, using manual commercial punchers available for biopsy or general use. Punch the devices on top of the green cutting board to extend the lifetime of the puncher blade and to avoid marking the table. Solvents like ethanol, isopropanol and acetone can be used as lubricants to facilitate the cutting and result in a cleaner surface. All solvents must be always used inside the fume hood. The resulting punched holes in PDMS tend to be slightly smaller than the puncher diameter, so, the final dimensions of the holes must be confirmed with metrology methods.

Clean well the place before leaving. Dispose all cellophane liner used. Be sure no residues of PDMS are left in the work areas, and place all PDMS residues in the C-waste container.

Scanning Electron Microscopy (SEM) micrographs for comparison of methods to fabricate through-holes in PDMS

Laser ablation

Machining/milling

Air/water jet machining

(left) PDMS microfluidic chips and glass placed inside plasma system. (right) Plasma generated inside the system to activate PDMS and glass surfaces
Bonding of PDMS and glass for fabrication of microfluidic device

Bonding

PDMS/PDMS and PDMS/glass bonding

Pictures of contact angle for water drop on PDMS and borosilicate glass after plasma treatment in the PDMS lab at DTU for different time


PDMS/PMMA bonding

References

For further information contact Stephan Sylvest Keller suke@dtu.dk or Claudia Chaves Villarreal cchvi@dtu.dk