--- title: "Laser Printed Polymers: 3D Printing without Solvents" id: "3951" type: "post" slug: "laser-printed-polymers-3d-printing-without-solvents" published_at: "2024-03-19T13:28:55+00:00" modified_at: "2024-03-18T20:03:51+00:00" url: "https://www.plasticsengineering.org/2024/03/laser-printed-polymers-3d-printing-without-solvents-003951/" markdown_url: "https://www.plasticsengineering.org/2024/03/laser-printed-polymers-3d-printing-without-solvents-003951.md" excerpt: "Researchers at the KTH Royal Institute of Technology and Stockholm University in Sweden have unlocked a game-changing potential in 3D printing technology. By hacking into a 3D printer, they've transformed it into a versatile tool akin to a laser printer,..." taxonomy_category: - "3D Printing/Additive Manufacturing" - "Aerospace" - "Electrical & Electronics" - "Industry" - "Medical" - "Process" taxonomy_post_tag: - "3D Printing" - "additive manufacturing" - "Laser Printing" - "polymer printing" - "Polymers" - "Prototyping" - "Solvents" --- [Home](https://www.plasticsengineering.org/) » [News](https://www.plasticsengineering.org/news/) » [Process](https://www.plasticsengineering.org/c/process/) » Laser Printed Polymers: 3D Printing without Solvents # Laser Printed Polymers: 3D Printing without Solvents PhD student Lee-Lun Lai loads a tray into a 3D microprinter to demonstrate how polymer transistors can be made faster, cheaper and more sustainably. Courtesy of [KTH](https://www.kth.se/en/om/nyheter/centrala-nyheter/3d-microprinter-hacked-to-fabricate-transistors-for-bioelectronics-1.1319335) ### Researchers at the [KTH](https://www.kth.se/en/om/nyheter/centrala-nyheter/3d-microprinter-hacked-to-fabricate-transistors-for-bioelectronics-1.1319335) Royal Institute of Technology and Stockholm University in Sweden have unlocked a game-changing potential in 3D printing technology. By hacking into a 3D printer, they’ve transformed it into a versatile tool akin to a laser printer. It’s capable of printing various polymers without the need for solvents, chemicals, or stringent clean room conditions. 3D printing and additive manufacturing have revolutionized how objects are created, from intricate structures to complex components, without the constraints of traditional production methods. However, its reliance on specific chemicals and controlled environments has limited its application in certain industries, particularly aerospace and medical devices. ## Simplifying Prototyping with Laser Polymer Printing Traditional methods of printing polymers for flexible electronic devices have been hindered by the requirements of clean rooms and specialized inks, making rapid prototyping costly and time-consuming. Recognizing this bottleneck, researchers sought a more accessible solution to advance bioelectronic technologies. Erica Zeglio, faculty researcher with Digital Futures, left, shows a finished transistor. At right is KTH Professor Frank Niklaus. By leveraging ultrafast laser pulses, researchers bypassed the need for pristine environments, enabling swift prototyping of microscale devices critical for medical implants and wearable electronics. This breakthrough eliminates the time-consuming lift-off processes and environmentally harmful solvents associated with conventional 3D printing methods. ## Applications and Advantages The newfound approach not only accelerates prototyping but also paves the way for developing novel materials and enhancing existing ones. Moreover, it offers a sustainable alternative by eliminating the use of non-eco-friendly solvents and developer baths, making it a greener option for manufacturing. “Current methods rely on expensive and unsustainable cleanroom practices,” Erica Zeglio, faculty researcher with Digital Futures says. “The method we proposed here doesn’t.” With the potential to revolutionize soft electronic device manufacturing, this innovative 3D printing method promises broader accessibility and affordability in the production of advanced technologies. Finally, by bridging the gap between laboratory research and practical applications, it marks a significant step forward in the democratization of technology. By **[Plastics Engineering](https://www.plasticsengineering.org/author/pe-anonymous/)** | March 19, 2024 ##### [Plastics Engineering](https://www.plasticsengineering.org/author/pe-anonymous/) [+ postsBio ⮌](#) ### Other posts you could read [May 6, 2026Reinforcement Learning for Polymer Design and Manufacturing](https://www.plasticsengineering.org/2026/05/reinforcement-learning-for-polymer-design-and-manufacturing-011146/) [April 21, 2026Flame-Resistant Polymers for Space Safety and Aerospace Use](https://www.plasticsengineering.org/2026/04/flame-resistant-polymers-for-space-safety-and-aerospace-use-011162/) [April 28, 2026IKV Colloquium 2026: The Journey of Research and Industry](https://www.plasticsengineering.org/2026/04/ikv-colloquium-2026-the-journey-of-research-and-industry-010989/) [May 7, 2026PCR Plastics Are Redefining Aesthetic Standards](https://www.plasticsengineering.org/2026/05/pcr-plastics-are-redefining-aesthetic-standards-011186/) [May 20, 2026Mechanical Recycling of Polyolefins in Food Packaging](https://www.plasticsengineering.org/2026/05/mechanical-recycling-of-polyolefins-in-food-packaging-011336/) [May 4, 2026Why Your Feeder Choice Is Quietly Undermining Consistency](https://www.plasticsengineering.org/2026/05/why-your-feeder-choice-is-quietly-undermining-consistency-011175/) [April 24, 2026Emerging Markets for Polyolefins in the Solar Industry](https://www.plasticsengineering.org/2026/04/emerging-markets-for-polyolefins-in-the-solar-industry-011128/) [May 18, 2026Packaging Redesign: Why Most Fail and What Drives Success](https://www.plasticsengineering.org/2026/05/packaging-redesign-why-most-fail-and-what-drives-success-011263/) ## Share Your Thoughts [Cancel reply](/2024/03/laser-printed-polymers-3d-printing-without-solvents-003951/#respond) - [https://twitter.com/share?url=https://www.plasticsengineering.org/?p=3951&text=Laser+Printed+Polymers%3A+3D+Printing+without+Solvents&via=Plastics_Mag](https://twitter.com/share?url=https://www.plasticsengineering.org/?p=3951&text=Laser+Printed+Polymers%3A+3D+Printing+without+Solvents&via=Plastics_Mag) - [https://www.facebook.com/sharer.php?u=https://www.plasticsengineering.org/?p=3951&t=Laser+Printed+Polymers%3A+3D+Printing+without+Solvents](https://www.facebook.com/sharer.php?u=https://www.plasticsengineering.org/?p=3951&t=Laser+Printed+Polymers%3A+3D+Printing+without+Solvents) - [https://www.linkedin.com/shareArticle?mini=true&url=https://www.plasticsengineering.org/?p=3951&title=Laser%20Printed%20Polymers:%203D%20Printing%20without%20Solvents&summary=Researchers+at+the+KTH+Royal+Institute+of+Technology+and+Stockholm+University+in+Sweden+have+unlocked+a+game-changing+potential+in+3D+printing+technology.+By+hacking+into+a+3D+printer%2C+they%27ve+transformed+it+into+a+versatile+tool+akin+to+a+laser+printer%2C+capable+of+printing+various+polymers+without+the+need+for+solvents%2C+chemicals%2C+or+stringent+clean+room+conditions.&source=Plastics+Engineering](https://www.linkedin.com/shareArticle?mini=true&url=https://www.plasticsengineering.org/?p=3951&title=Laser%20Printed%20Polymers:%203D%20Printing%20without%20Solvents&summary=Researchers+at+the+KTH+Royal+Institute+of+Technology+and+Stockholm+University+in+Sweden+have+unlocked+a+game-changing+potential+in+3D+printing+technology.+By+hacking+into+a+3D+printer%2C+they%27ve+transformed+it+into+a+versatile+tool+akin+to+a+laser+printer%2C+capable+of+printing+various+polymers+without+the+need+for+solvents%2C+chemicals%2C+or+stringent+clean+room+conditions.&source=Plastics+Engineering) - [https://www.reddit.com/submit?url=https://www.plasticsengineering.org/?p=3951&title=Laser+Printed+Polymers%3A+3D+Printing+without+Solvents](https://www.reddit.com/submit?url=https://www.plasticsengineering.org/?p=3951&title=Laser+Printed+Polymers%3A+3D+Printing+without+Solvents) - [/cdn-cgi/l/email-protection#99a6eaecfbf3fcfaeda4c9f5f8eaedf0faeab9dcf7fef0f7fcfcebf0f7feb9b4b9d5f8eafcebb9c9ebf0f7edfcfdb9c9f6f5e0f4fcebeaa3b9aaddb9c9ebf0f7edf0f7feb9eef0edf1f6ecedb9caf6f5effcf7edeabffbf6fde0a4f1edede9eaa3b6b6eeeeeeb7e9f5f8eaedf0faeafcf7fef0f7fcfcebf0f7feb7f6ebfeb6a6e9a4aaa0aca8](/cdn-cgi/l/email-protection#99a6eaecfbf3fcfaeda4c9f5f8eaedf0faeab9dcf7fef0f7fcfcebf0f7feb9b4b9d5f8eafcebb9c9ebf0f7edfcfdb9c9f6f5e0f4fcebeaa3b9aaddb9c9ebf0f7edf0f7feb9eef0edf1f6ecedb9caf6f5effcf7edeabffbf6fde0a4f1edede9eaa3b6b6eeeeeeb7e9f5f8eaedf0faeafcf7fef0f7fcfcebf0f7feb7f6ebfeb6a6e9a4aaa0aca8) - [#comments](#comments)