HOW TO CHOOSE THE RIGHT UV SOURCE FOR THE PHOTOLITHOGRAPHY OF SU-8 MICROFLUIDIC MOLD?

Photolithography UV sources are used in micro fabrication to expose a layer of photoresist. Depending on the different applications and photoresist, the choice for a specific UV source is different. That’s why, in the case of the soft-lithography, it’s important to check carefully some parameters to make sure that your equipment is well tuned and allows you to easily perform your SU-8 exposure. This guide is here to give you the points to keep in mind for those who want to buy a photolithography UV source to make SU-8 microfluidic mold. We do not consider here the case of a mask aligner for multi-layer SU-8 processing requiring photomask alignment.

Get the right UV power to get the right exposure timing

The real relevant parameter of a photolithography UV source is not really the power but more its surface energy created, in W.m-2 often given in mW.cm-2. This parameter is deeply linked to the exposure time, which is the time when the photoresist is lighted by the lamp. Indeed, these two parameters define the exposure degree of the photoresist, which is nothing more than the multiplication of these two parameters. It’s a value that has to be precise because an under-exposed SU-8 photoresist (an exposure degree too low) or an over-exposed SU-8 photoresist (an exposure degree too high) will lead to a resolution loss. The exposure degree is also called the exposure dose, it has to be sufficient to initiate the photoactive component of the photoresist in all the depth of the layer but without being to high to prevent any diffusion in the width. In function of the depth, each photoresist needs a particular exposure degree, given by the provider.

UV source with integrated timer

The photoresist is sensitive to over and under exposure. And thus, the UV exposure time has to be defined precisely to make sure to have a resolution as best as possible. All the photolithography UV sources don’t offer the same precision (within one second or one-tenth of a second) so make sure to set the time with at least a precision of 10% of the global exposure time (For example within one second for an exposure time of 10 seconds).

Photolithography UV source with integrated UV-meter

In the same way as the time, being able to control the power or more the surface energy of a photolithography UV source is a real asset. It is possible to change and handle the power; either by changing the input power or by changing the vertical position of the lamp to the wafer. At last, it’s essential to have a way to measure the power, some photolithography UV sources offer an automatic measure, if not, make sure to take a UV power measure device.

 The wavelength spectra of the UV source

Each photolithography UV source offers one or several wavelengths for exposure. The UV range is between 100nm and 400nm. We can divide it into three parts. The UVC or Deep UV, for wavelengths less than 280nm, the UVB or MidUV for wavelengths between 280nm and 315nm and finally the UVA or Near UV for wavelengths more than 315nm. The most used UV part is definitely the UVA. For each photoresist, one wavelength is particularly well fitted to initiate the cross-linkage, for example is 365nm for the SU-8. See in the chapter below difference between Hg bulb and UV LED spectra.

Photolithography UV source with mercury bulb or UV LED lamp

Traditionally, the mercury lamp is more used in photolithography process, however for a few years some equipment has been offering the possibility to use UV LED.

SU-8-photolithography-UV-source-tutorial-mercury bulbA mercury lamp has the advantage to generate several wavelengths at the same time and it’s some filters that select one specific wavelength. The mercury light spectrum has three particular wavelengths with a great emission power at 365, 405 and 436nm. The mercury lamp is used for a long time and so there is great expertise about it. What’s more, it is a powerful lamp that emits a great surface energy and it is able to expose a wide surface. However, the lamp heats and has to be cooled down and thus needs a great power (several hundreds of watt).

SU-8 photolithography UV source tutorial – UV ledUsing UV LED as photolithography UV source makes it possible to have a cold UV source and a light 100% monochromatic with a bandwidth centered at 10nm. A LED is cheap, needs much less power than a mercury lamp and has a longer lifetime. The wavelength depends on the kind of LED, the choice was limited at the beginning but know you can find quite all the wavelength you want. On the other hand, one UV LED lights only a small surface and has to be associated in grid to expose an entire wafer (until 200 for a 4inches wafer). What’s more is that the surface energy is generally weaker (around few mW.cm-2) and thus leads to longer insolation time.

 Parallelism of the UV light beam

It’s important that the UV light beam arrives parallel and vertical to the photoresist surface. For that, make sure to have a collimator in the optical path length. Make sure your light is also monochromatic, the need to have a real monochromatic light comes from the fact that the refractive index of a material is different according to the wavelength.

And thus a multichromatique beam will light a bigger zone after crossing the mask. In that case a filter is essential to have better resolutions for SU-8 processing when dealing with mercury photolithography lamp. With some mercury photolithography UV sources it is possible to add filter on the optic way. These filters make possible to select one wavelength really precisely for example. That’s why a filter at 365nm is highly recommended to expose the SU-8 with Mercury UV lamp.

The variability in time and space of your UV source

The light has to be uniform on the entire surface of the wafer to guarantee the same UV exposure dose everywhere and thus the same exposure for the whole layer. The light also has to be uniform between the mask and the photoresist, in order to have a good resolution, indeed,  the light has to be well collimated and arrived as more vertical as possible on the photoresist surface. The UV light has to be uniform in time, because variability in the surface energy makes the routine process obsolete. It’s really advised to measure regularly the lamp power to detect all changes or to choose an UV-lamp with an integrated UV meter.

The different contact modes of your photolithography UV source

The different contact modes between the mask and the wafer are: A proximity contact, “soft” contact, “hard” contact and “vacuum” contact.

• Proximity contact: The mask is not in real contact with the wafer but at a really tiny distance (about few µm). This mode is often used when a thick photoresist risks to stick to the mask and a process that do not need good resolution.
• Soft contact: The mask is softly placed on the substrate.
• Hard contact: The mask is holding against the wafer with a particular strength that makes the contact closer.
• Vacuum contact: The mask and the wafer are holding each other thanks to vacuum. This option, the most difficult to apply, offers better resolutions.

In case of a real contact, it has to be kept in mind that the contamination risk is greater between the mask and the photoresist and it can be unacceptable for some applications. The contact mode is relevant because the more the contact is strong, the less space between the mask and the photoresist remains. This gap has a big influence on the resolution and on the quotation respect. Indeed, the bigger is the gap the more width will be the pattern on the photoresist because of the light diffraction. If the mask must not be in contact with the photoresist, it is undeniable to choose the proximity contact but for all other cases, at least, a hard contact exposure is advised. For most SU-8 processing dedicated to microfluidic applications we generally recommend hard/ vacuum contact. For reproducible process try to choose a UV source with automatic contact and try to avoid to perform the contact between the mask and the wafer by pressing them together with your hand (reducing strongly the quality of your SU-8 photolithography).

The noise and the size of your photolithography UV source

Apart from the lamp that can make some noise, there is the cooling system that can be really noisy. Don’t forget to watch the photolithography UV source working to evaluate this parameter, after all you are going to work closely, it is better if the noise is not bothering. With all the differences and options (Mercury lamp or UV LED, cooling system, alignment system…) the size of a photolithography UV source can really vary and can require several square meters, make sure to have enough space for that.

The protection around the photolithography UV source

According to the photolithography UV source, the exposure can be internal or external and so visible by the user. UV rays of such intensity are dangerous for the eyes. Make sure to protect the user (Anti-UV glass) and the people around (anti-UV cover around the lamp). The mercury lamps have to be cooled down and can reach 900°C. At this temperature it is really imperative to be careful of burn risks. The lamp must not be reachable by the user and the potentially hot surfaces have to be pointed out. In most cases, the cooling system is with the lamp but not always and thus you need to anticipate a fan system to cool down your equipment. Think about it!