Nano Printing | Beam Pen Lithography | Piezo XYZ

Desktop nanoprinter based on a novel, highly scalable, and versatile photolithographic technology and XYZ piezo-driven nano-precision stage finds applications in photonics, meta-materials, electronics, soft robotics, and biomedicine.

The PRISM award-winning TERA-Fab™ E series platform is a tool for the precise bioprinting and rapid prototyping of nano-structures and nanostructured devices. It integrates structured light illumination with ultra-precise optomechanics to enable the rapid printing of millimeter-scale, arbitrary designs with a diffraction-unlimited (sub-250 nm) resolution using arrays of 100s of thousands of independently actuatable near-field probes. At the center of the platform, the PI P-611 NanoCube XYZ piezo nanopositioning scanning stage is visible. The piezo stage controls the movement of the substrate under beam pen array between light exposures with nanometer precision.

Nanoscale components have applications in semiconductor manufacturing, medical technology, and photonics. Lithography is one way to produce miniscule structures. However, just like with classical microscopy, the resolution of optical lithography suffers from the diffraction limit. Over the past few decades, near-field and super-resolution techniques have aided modern microscopy to overcome this limit and related solutions were applied in lithography. However, achieving high resolution and high throughput with one single technique has been difficult. Recent lithography advances based upon scanning probe microscopy and arrays of transparent pyramid-shaped elastomeric tips, now allow patterning of molecules over large-areas with high-throughput.

A new parallel technique, called beam pen lithography, can toggle between near- and far-field distances, allowing arbitrary patterns of both large and sub-diffraction limit features to be generated by passing light of a desired wavelength through nanoscopic apertures at each tip in the array.

One of the advantages of BPL is its flexibility to create arbitrary, programmable patterns, independent of fixed photomasks with no need to create a new master for each variation. This maskless technique saves both time and cost, making it ideal for prototyping.

Highly accurate motion in X, Y, and Z is needed to make BPL work. The motion part is handled by a closed-loop P-611 piezo flexure stage. This nanopositioning system precisely moves the substrate under the beam pen array between light exposures and enables rapid reconstruction of an arbitrary, high-resolution pattern - up to 100,000s of sub-250 nm pixels at a time. The nanopositioning stage is actuated by special multilayer piezo stacks whose ceramic encapsulation provides protection against humidity and moisture, important in bio-chemical applications.

The ability to rapidly prototype and fabricate millimeter-scale nanostructured patterns and devices with sub-diffraction resolution not only reduces the time and accelerates the discovery, but it also enables routine fabrication of structures and devices not previously possible.

BPL tip array with millions of tips can be addressed with digital micro-mirror device (DMD) of >750,000 mirrors.

The P-611 NanoCube XYZ nano-precision stage provides 100x100x100µm motion with 1 nanometer resolution. Position sensors for each axis provide exact information to a controller. The piezo drive principle and frictionless flexure guiding system enables responsiveness in the millisecond range. The compact dimensions of the XYZ stage facilitate integration into instrumentation of all sorts

Bioprinting and Tissue Engineering

Bioprinting is one of the many applications of the TERA-Fab™ E series platform. It allows the production of tissues for reconstitution and organs for transplantation. Even the food industry, a massive economic sector that benefits greatly from genomic engineering, is showing interest in this emerging field. The possibility to bring down the cost for rapid fabrication of more accurate, i.e. more biologically relevant bioconstructs for tissue engineering and pharmaceutical applications, has the potential to transform industries.

Applications in Confined Chemical Synthesis and Highly Localized Photochemistry

BPL enables the synthesis of structures with nanoscale resolution and can generate millions of attoliter-sized nano-wells that serve as “nanoreactors”. The TERA-Fab™ E system is useful for biochemical applications because of its ability to immobilize and photochemically synthesize/modify many types of biological structures with feature sizes that are similar to those found in biological and living systems.

Applications in Electronics

Complex structures used in electronic circuits can also be produced with the maskless tool. To provide an example for the addressable dimensions: fully functional resistors, capacitors or inductors of several millimeter length by a few micrometer width and comprised of an array of nanowires (<200nm) have been produced.

Says Andrey Ivankin, CTO and Co-Founder of TERA-print, “TERA-print set out to develop desktop nanoprinters that offer high, in some cases sub-100 nm, resolution patterning of a wide range of materials. This demanded a piezo stage that allows for precise motion in XYZ, is compatible with high relative humidity environments to conform with a wider range of molecular inks, and can also tolerate the force generated by 100,000s of beam pens brought into contact with the substrate. NanoCube from PI met all of these requirements in an extremely compact format with the added benefit of German engineering quality and reliability.”

More information about the TERA-print and its Desktop Nanoprinter is available here: https://www.tera-print.com/