TERA-print

12/22/2022

12/12/2022

We are thrilled to announce that we’ve been named a Deep Tech Pioneer by Hello Tomorrow!

A big thank you to the judges at Hello Tomorrow who picked our solution out of thousands of applications! We look forward to attending the event in March 2023.



https://hello-tomorrow.org/global-summit/?utm_source=dtp&utm_medium=community&utm_campaign=deep_tech_pioneer

08/03/2022

Our new industry challenger - TERA-Fab E series 2.0.

Higher power and more uniform near UV light, advanced software functionality, and even better user experience while delivering an unprecedented combination of resolution and throughput - whatever the application.

Learn More: https://www.teraprint.us/eseries

07/21/2022

Proud to be welcomed by Nasdaq alongside some of the best innovators in Chicago last week!

Many thanks to Chicago Innovation for sponsoring the event and to all of those who believe in our innovative technology. We hope to be back at soon!

Learn More about TERA-print and the Chicago Innovation Awards: https://chicagoinnovation.com/about/winners/

07/07/2022

Researchers at Heriot-Watt University in Scotland utilized in combination with liquid crystal (LCEs) to and demonstrate photo-actuated microgrippers capable of controllably manipulating microbeads.

By modulating structural geometries and incorporating light-absorbing dyes for heating, the researchers were able to optimize their design. Use the TERA-Fab E series to explore and design photo-responsive devices like this.

Learn More: https://onlinelibrary.wiley.com/doi/epdf/10.1002/admt.202101732
Visit Us: www.tera-print.com

06/13/2022

A team of researchers at Rice University (Houston, TX) led by Prof. James Tour used -activated rotors to kill harmful to humans. This novel mechanism represents the dawning of a new paradigm of anti-microbial treatments aimed at curing resistant bacterial infections.

With resistance (AMR) accelerating over time, the development of this light-based therapy is a promising new strategy with the potential to save countless lives. Use the TERA-Fab E series to and new photochemistries like this for your application.

Read More: https://www.science.org/doi/full/10.1126/sciadv.abm2055
Visit Us: www.tera-print.com

06/02/2022

from The University of British Columbia created multilayer architectures of 3rd- and 4th-generation using photoinduced electron transfer reversible addition fragmentation chain transfer (PET-RAFT) polymerization.

By using direct , as well as a digital micromirror device, or , it was demonstrated that the oxygen tolerant surface-initiated PET-RAFT approach allows for enhanced control over layer thickness and spatial resolution in the brush.

Develop advanced devices and improve patterning resolution/throughout with the TERA-Fab E series.

Read more: https://onlinelibrary.wiley.com/doi/full/10.1002/anie.202107830
Visit Us: www.tera-print.com

05/24/2022

Researchers from The University of Freiburg recently demonstrated a new enabling the direct patterning of chips without the need for intermediary molds. While polystyrene is commonly used in many applications (petri dishes, etc.), it typically requires expensive modes of production such as injection molding.

This new resin makes the material more to the space, enabling researchers to iteratively design their systems from conception to implementation without the risk of material inconsistencies.

Explore the potential of high resolution and high throughput photolithography with materials like this using the TERA-Fab E series.

Learn More: https://onlinelibrary.wiley.com/doi/epdf/10.1002/admt.202200084
Visit Us: www.tera-print.us

05/18/2022

We are very happy to announce that TERA-print was awarded a U.S. Department of Energy (DOE) Phase II to turn our award-winning TERA-Fab E series beam pen lithography (BPL) platform into a printer. Led by Kyle Justus (Principal Investigator and Senior Scientist), William Hutson (Senior Engineer), and Shaowei Ding, PhD (Senior Scientist), our Team will develop a new desktop machine to produce high-density DNA arrays and long-strand faster, cheaper, and at the point of use.

04/26/2022

Rapid Prototyping for Organ-on-Chip Development (OoC): A team of researchers from University of Strathclyde develop a modular platform for in vitro modeling of the central nervous system. By better mimicking the physiological conditions of tissue using , they could produce a more representative OoC model for understanding neuronal function and dysfunction, but also build a platform that enables more targeted development of novel to combat . [Scale Bars = (i) 500 µm, (ii and iii) 100 µm, (iv) 200 µm]

The TERA-Fab E series allows researchers to explore the , micro- and macroscale using a single mask-free tool. This easy-to-use desktop system allows the development of even more intricate designs right from the comfort of your own laboratory – no specialized facility needed.

Read More: https://pubs.rsc.org/en/content/articlelanding/2022/LC/D2LC00115B
Visit Us: www.tera-print.com

04/14/2022

A Northwestern University team led by Nobel Laureate Prof. Fraser Stoddart developed a novel artificial pump (AMP) for unidirectional, linear transport pump for biologically relevant materials. AMPs are made of interlocking designed to mechanically and materials of interest and can be actuated by various stimuli, such as chemicals, electricity, or light.

The long-term development of AMPs and other similar nanotechnology tools are essential for driving next generation systems, experiments, tools and much more.

Could the TERA-Fab E series help to accelerate this ?

Read More: https://pubs.acs.org/doi/abs/10.1021/jacs.0c06663 #
Visit Us: www.tera-print.com

04/07/2022

Researchers from Purdue University developed a high-speed surfing probe lithography (SSPL) method which scales up by enabling high-frequency cantilever-based patterning across a rapidly moving substrate surface. The strategy combines systems for , flow focusing and deposition to achieve resolution on a substrate moving at a linear velocity on the order of meters per second.

The principles of , and high-throughput patterning are poised to revolutionize , all of which the TERA-Fab E is equipped to address. These techniques could be adopted to integrate hundreds of thousands of patterning heads, which further push the limit of throughput in a massively multiplexed fashion and with the adoption of .

Read More: https://pubs.acs.org/doi/10.1021/acs.nanolett.1c03705?fig=fig3&ref=pdf
Visit Us: www.tera-print.com

  TERA-print®   Learn More        A unique blend of technical capabilities   Resolution Change patterning resolutions from 250 nm to over 100 µm in an instant. Versatility Enhanced material compatibility enables limitless patterning flexibility. Throughput Pattern with independent control ...