News | November 30, 2021

3D Laser Nanoprinters Become Compact

Researchers of the Cluster of Excellence 3D Matter Made to Order Show How 3-dimensional Nanostructures Can Be Printed Using Compact Desktop Devices – Publication in Nature Photonics

Lasers in conventional laser printers for paper printouts are very small. 3D laser printers for 3-dimensional microstructures and nanostructures, by contrast, have required big and expensive laser systems so far. Researchers of Karlsruhe Institute of Technology (KIT) and the Heidelberg University now use another process for this purpose. Two-step absorption works with inexpensive and small, blue laser diodes. As a result, much smaller printers can be used. Work is reported in Nature Photonics. (DOI: 10.1038/s41566-021-00906-8)

Presently, laser printing is the method of choice for additive manufacture by 3D printing, as it offers the best spatial resolution of all methods and reaches an extremely high printing speed. In laser printing, a focused laser beam is directed towards a light-sensitive liquid. At the focal point, the laser light turns a switch in special molecules and triggers a chemical reaction. The reaction leads to the local hardening of the material. By moving the focal point, any 3D micro- and nanostructures can be produced. The chemical reaction is based on so-called two-photon absorption, meaning that two photons excite the molecule at the same time, which causes the desired chemical modification. However, this simultaneous excitation happens very rarely, which is why complex pulsed laser systems have to be applied, resulting in bigger dimensions of the laser printer.

More Compact 3D Printers Thanks to Two-step Process
When using the so-called two-step process, more compact, smaller printers can be realized. The first photon transfers the molecule to an intermediate state. In the second step, a second photon transfers the molecule from the intermediate state to the desired excited state and starts chemical reaction. The advantage: Contrary to two-photon absorption, the absorption of the two photons must not necessarily happen at the same time. “For the process, compact and low-power continuous-wave laser diodes can be used,” says Vincent Hahn, the first author of the study from KIT’s Institute of Applied Physics (APH). The required laser powers are far below those of conventional laser pointers. Printing, however, requires specific photoresists. “Development of these photoresists has taken several years and has been possible only in collaboration with chemists,” says Professor Martin Wegener, APH.

Not Only Easier, but Better
“The publication reveals that the idea works, even better than the previously used two-photon absorption,” Hahn says. To Martin Wegener, the advantage is obvious: “It is a big difference between using a femtosecond laser as large as a big suitcase for several ten thousand euros or a semiconductor laser that is as large as a pinhead and costs less than ten euros. Now, the other components of the 3D laser nanoprinter also have to be miniaturized. To me, a device that will be as large as a shoebox appears realistic in the next years. That would be even smaller than the laser printer on my desktop at KIT.” This way, 3D laser nanoprinters might become affordable for many groups. Experts are already talking about a democratization of 3D laser printing technology.

Along with KIT researchers, scientists from Heidelberg University were involved in the publication. The publication originated within the framework of the joint Cluster of Excellence "3D Matter Made to Order" of KIT and Heidelberg University.

Cluster of Excellence “3D Matter Made to Order”
In the Cluster of Excellence 3D Matter Made to Order (3DMM2O), scientists of Karlsruhe Institute of Technology (KIT) and Heidelberg University conduct interdisciplinary research into innovative technologies and materials for digital scalable additive manufacture to enhance the precision, speed, and performance of 3D printing. Work is aimed at completely digitizing 3D manufacture and materials processing from the molecule to the microstructure. In addition to funding as a Cluster of Excellence under the Excellence Strategy competition launched by the federation and the federal states, 3DMM2O is financed by Carl Zeiss Foundation. For More information, visit

More about the KIT Center Materials in Technical and Life Sciences:

About Universities of Excellence in Germany, Heidelberg University
Founded in 1386, Ruperto Carola is an internationally oriented research university whose subject spectrum includes the humanities, the social sciences, law, the natural, engineering and life sciences, and medicine. As one of the Universities of Excellence in Germany, Heidelberg University’s successes in the Excellence Competitions and its standing in international rankings confirm its leading role in the academic landscape. It is part of Heidelberg University’s self-concept to further develop outstanding individual disciplines, to strengthen interdisciplinary cooperation, and to carry research results over into society. With a research-oriented course of study in more than 180 programmes, its nearly 30,000 students can choose from a virtually singular array of subject combinations and individual qualification pathways.

Being “The Research University in the Helmholtz Association”, KIT creates and imparts knowledge for the society and the environment. It is the objective to make significant contributions to the global challenges in the fields of energy, mobility, and information. For this, about 9,600 employees cooperate in a broad range of disciplines in natural sciences, engineering sciences, economics, and the humanities and social sciences. KIT prepares its 23,300 students for responsible tasks in society, industry, and science by offering research-based study programs. Innovation efforts at KIT build a bridge between important scientific findings and their application for the benefit of society, economic prosperity, and the preservation of our natural basis of life. KIT is one of the German universities of excellence.

Source: Karlsruhe Institute of Technology (KIT)