UK based University of Nottingham has developed micro-scale 3D printed surface textures that control how gas particles rebound inside vacuum systems. By steering residual gas away from sensitive regions, the surfaces triple pumping efficiency, enabling smaller, more reliable, and portable quantum sensors. The advancement was made possible by additive manufacturingâs ability to create complex geometries that conventional machining cannot achieve.
Led by physicist L. Hackermueller, the results are reported in âExploiting complex 3D-printed surface structures for portable quantum technologies,â published in Physical Review Applied. These advances could be used in field-deployable quantum sensors for navigation, medical diagnostics, and fundamental physics experiments, where high-vacuum performance and portability are critical.
Quantum sensors measure tiny variations in gravity, magnetic fields, and other forces by tracking the behavior of individual quantum systems. They are poised to play a crucial role in applications such as medical diagnostics, navigation, and fundamental research. Their extreme sensitivity, however, makes them vulnerable to even the smallest collisions with air molecules, requiring operation in vacuum conditions.
Under normal atmospheric conditions, gas molecules constantly bump into each other, but in a high vacuum, they can travel meters or more without interaction. Controlling the movement of these particles is vital for accurate measurements. Even in carefully maintained vacuum environments, stray molecules can still enter the system, introducing noise that limits precision.
3D Printed Surfaces Boost Vacuum Efficiency for Quantum Sensors
To address this issue, the team 3D printed titanium components roughly the size of an ice hockey puck. Surfaces incorporated hexagonal cavities and conical protrusions to increase atom-surface interactions and bias particle trajectories. The modules were designed to fit directly into standard vacuum chamber ports.
The team validated the concept by integrating the textures into a surface-based vacuum pump. Tests showed the modified surfaces removed residual gas nearly three times faster than conventional flat designs, achieving pumping efficiencies up to 3.8 times per unit area.
âWe are still discovering the most effective surface textures; promising candidates include a hexagonal pattern similar to a honeycomb and an intricate three-dimensional pattern derived from geometry-inspired artwork,â said Nathan Cooper, Research Fellow at the School of Physics and Astronomy and lead author. âThis relatively low-tech innovation can substantially improve advanced quantum technologies.â
Numerical simulations suggest optimized designs could achieve up to a ten-fold increase in pumping performance.
The technique is not yet a full replacement for conventional vacuum pumps, since its effectiveness depends on factors such as surface geometry, fabrication accuracy, and the specific gas dynamics of each system. Future research will need to optimize surface designs, assess long-term stability, and integrate these textures into complete quantum sensor setups.
PhD student and co-author Ben Hopton emphasized both the challenges and opportunities. âWhatâs exciting about this work is that relatively simple surface engineering can have a surprisingly large effect. By shifting some of the burden from active pumping to passive surface-based pumping, this approach has the potential to significantly reduce, or even remove, the need for bulky pumps in some vacuum systems, allowing quantum technologies to be far more portable.â
High-vacuum systems are tightly constrained by geometry, surface properties, and material limitations, making conventional manufacturing slow and restrictive. AM offers a solution, enabling complex internal geometries and surface textures that remain vacuum-compatible while actively guiding gas particles.
Beyond the Nottingham study, metal AM has already been used to produce ultra-high-vacuum chambers for quantum experiments, such as Added Scientificâs 3D printed magnetic-optical trap chamber, which reduced size and weight while maintaining UHV performance. AM has also been validated for low-outgassing, vacuum-sensitive applications, including space environments where contamination control is critical.
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Featured image shows Micro-scale 3D printed surface textures. Image via University of Nottingham.
Led by physicist L. Hackermueller, the results are reported in âExploiting complex 3D-printed surface structures for portable quantum technologies,â published in Physical Review Applied. These advances could be used in field-deployable quantum sensors for navigation, medical diagnostics, and fundamental physics experiments, where high-vacuum performance and portability are critical.
Quantum sensors measure tiny variations in gravity, magnetic fields, and other forces by tracking the behavior of individual quantum systems. They are poised to play a crucial role in applications such as medical diagnostics, navigation, and fundamental research. Their extreme sensitivity, however, makes them vulnerable to even the smallest collisions with air molecules, requiring operation in vacuum conditions.
Under normal atmospheric conditions, gas molecules constantly bump into each other, but in a high vacuum, they can travel meters or more without interaction. Controlling the movement of these particles is vital for accurate measurements. Even in carefully maintained vacuum environments, stray molecules can still enter the system, introducing noise that limits precision.
3D Printed Surfaces Boost Vacuum Efficiency for Quantum Sensors
To address this issue, the team 3D printed titanium components roughly the size of an ice hockey puck. Surfaces incorporated hexagonal cavities and conical protrusions to increase atom-surface interactions and bias particle trajectories. The modules were designed to fit directly into standard vacuum chamber ports.
The team validated the concept by integrating the textures into a surface-based vacuum pump. Tests showed the modified surfaces removed residual gas nearly three times faster than conventional flat designs, achieving pumping efficiencies up to 3.8 times per unit area.
âWe are still discovering the most effective surface textures; promising candidates include a hexagonal pattern similar to a honeycomb and an intricate three-dimensional pattern derived from geometry-inspired artwork,â said Nathan Cooper, Research Fellow at the School of Physics and Astronomy and lead author. âThis relatively low-tech innovation can substantially improve advanced quantum technologies.â
Numerical simulations suggest optimized designs could achieve up to a ten-fold increase in pumping performance.
The technique is not yet a full replacement for conventional vacuum pumps, since its effectiveness depends on factors such as surface geometry, fabrication accuracy, and the specific gas dynamics of each system. Future research will need to optimize surface designs, assess long-term stability, and integrate these textures into complete quantum sensor setups.
PhD student and co-author Ben Hopton emphasized both the challenges and opportunities. âWhatâs exciting about this work is that relatively simple surface engineering can have a surprisingly large effect. By shifting some of the burden from active pumping to passive surface-based pumping, this approach has the potential to significantly reduce, or even remove, the need for bulky pumps in some vacuum systems, allowing quantum technologies to be far more portable.â
High-vacuum systems are tightly constrained by geometry, surface properties, and material limitations, making conventional manufacturing slow and restrictive. AM offers a solution, enabling complex internal geometries and surface textures that remain vacuum-compatible while actively guiding gas particles.
Beyond the Nottingham study, metal AM has already been used to produce ultra-high-vacuum chambers for quantum experiments, such as Added Scientificâs 3D printed magnetic-optical trap chamber, which reduced size and weight while maintaining UHV performance. AM has also been validated for low-outgassing, vacuum-sensitive applications, including space environments where contamination control is critical.
The 3D Printing Industry Awards are back. Make your nominations now.
Do you operate a 3D printing start-up? Reach readers, potential investors, and customers with the 3D Printing Industry Start-up of Year competition.Â
To stay up to date with the latest 3D printing news, donât forget to subscribe to the 3D Printing Industry newsletter or follow us on Linkedin.
Featured image shows Micro-scale 3D printed surface textures. Image via University of Nottingham.