Optimizing a photon absorber using conformal cooling channels and additive manufacturing in copper

Younes Chahid; Carolyn Atkins; Stephen Hodbod; John Robinson; Xia Liu; Stephen Watson; Maia Jones; Mark Cliffe; Dayo Ogunkanmi; Richard Kotlewski; Lee Chapman; Scott Beamish; Jorge Linde Cerezo; Thomas Wearing; Ahmad Baroutaji; Arun Arjunan; Chantal Fowler; Paul Vivian

doi:10.1107/s1600577525003078

Optimizing a photon absorber using conformal cooling channels and additive manufacturing in copper

Younes Chahid^*, Carolyn Atkins, Stephen Hodbod, John Robinson, Xia Liu, Stephen Watson, Maia Jones, Mark Cliffe, Dayo Ogunkanmi, Richard Kotlewski, Lee Chapman, Scott Beamish, Jorge Linde Cerezo, Thomas Wearing, Ahmad Baroutaji, Arun Arjunan, Chantal Fowler, Paul Vivian

^*Corresponding author for this work

School of Engineering and Technology

Research output: Contribution to journal › Article › peer-review

Abstract

Many of the 70 synchrotron facilities worldwide are undergoing upgrades to their infrastructure to meet a growing demand for increased beam brightness with nanometre‐level stability. These upgrades increase the mechanical and thermal challenges faced by beamline components, creating opportunities to apply novel methodologies and manufacturing processes to optimize hardware performance and beam accuracy. Absorbers are important beamline components that rely on water‐cooled channels to absorb thermal energy from excess light caused by synchrotron radiation or photon beams created by insertion devices, all within a limited volume, to protect downstream equipment and ensure safe, reliable operation. Additive manufacturing (AM) has been shown to meet criteria relevant to synchrotron environments like leak tightness and vacuum compatibility. However, there is a research gap on the heat transfer and pressure drop impact of different AM conformal cooling channel geometries, as well as the print quality of AM copper parts using low‐power infrared lasers and their compliance with absorber requirements. In this study, an intermediate model of a Diamond Light Source photon absorber was optimized to incorporate AM conformal cooling channels, leading to two concept designs named `Horizontal' and `Coil'. When compared with the baseline design, the lightweight Horizontal concept performed the best in this study, with simulations showing a maximum temperature drop of 11%, a calculated pressure drop reduction of 82%, a mass reduction of 86%, and the consolidation of 21 individually brazed pipes into a single manifold. The AM print quality and compliance with the synchrotron environment was examined by producing custom benchmark artefacts and measuring their surface roughness, dimensional accuracy and porosity levels, which are characteristics that can affect heat absorption, structural integrity, thermal conductivity and vacuum performance. The study demonstrates the benefits and addresses outstanding challenges in reducing thermal fatigue, as well as the size, vibrations and energy consumption of AM absorbers.

Original language	English
Number of pages	15
Journal	Journal of Synchrotron Radiation
Volume	32
Issue number	Pt 4
Early online date	23 May 2025
DOIs	https://doi.org/10.1107/s1600577525003078
Publication status	Published - Jul 2025

Bibliographical note

This is an open-access article distributed under the terms of the Creative Commons Attribution (CC-BY) Licence, which permits unrestricted use, distribution, and reproduction in any medium, provided the original authors and source are cited.

Data Access Statement

The data that support the findings of this study are openly available in eData, the STFC repository, including the relevant STL files and videos of pressure drop testing, both available in https://edata.stfc.ac.uk/handle/edata/972.

Keywords

particle accelerator
additive manufacturing
3D printing
pressure drop
heat transfer

Access to Document

10.1107/s1600577525003078Licence: CC BY 4.0

Y Chahid et al_Optimizing a photon absorber using conformal cooling channels and additive manufacturing in copper
This is an open-access article distributed under the terms of the Creative Commons Attribution (CC-BY) Licence, which permits unrestricted use, distribution, and reproduction in any medium, provided the original authors and source are cited.
Final published version, 35.1 MBLicence: CC BY 4.0

Cite this

Chahid, Y., Atkins, C., Hodbod, S., Robinson, J., Liu, X., Watson, S., Jones, M., Cliffe, M., Ogunkanmi, D., Kotlewski, R., Chapman, L., Beamish, S., Linde Cerezo, J., Wearing, T., Baroutaji, A., Arjunan, A., Fowler, C., & Vivian, P. (2025). Optimizing a photon absorber using conformal cooling channels and additive manufacturing in copper. Journal of Synchrotron Radiation, 32(Pt 4). https://doi.org/10.1107/s1600577525003078

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abstract = "Many of the 70 synchrotron facilities worldwide are undergoing upgrades to their infrastructure to meet a growing demand for increased beam brightness with nanometre‐level stability. These upgrades increase the mechanical and thermal challenges faced by beamline components, creating opportunities to apply novel methodologies and manufacturing processes to optimize hardware performance and beam accuracy. Absorbers are important beamline components that rely on water‐cooled channels to absorb thermal energy from excess light caused by synchrotron radiation or photon beams created by insertion devices, all within a limited volume, to protect downstream equipment and ensure safe, reliable operation. Additive manufacturing (AM) has been shown to meet criteria relevant to synchrotron environments like leak tightness and vacuum compatibility. However, there is a research gap on the heat transfer and pressure drop impact of different AM conformal cooling channel geometries, as well as the print quality of AM copper parts using low‐power infrared lasers and their compliance with absorber requirements. In this study, an intermediate model of a Diamond Light Source photon absorber was optimized to incorporate AM conformal cooling channels, leading to two concept designs named `Horizontal' and `Coil'. When compared with the baseline design, the lightweight Horizontal concept performed the best in this study, with simulations showing a maximum temperature drop of 11%, a calculated pressure drop reduction of 82%, a mass reduction of 86%, and the consolidation of 21 individually brazed pipes into a single manifold. The AM print quality and compliance with the synchrotron environment was examined by producing custom benchmark artefacts and measuring their surface roughness, dimensional accuracy and porosity levels, which are characteristics that can affect heat absorption, structural integrity, thermal conductivity and vacuum performance. The study demonstrates the benefits and addresses outstanding challenges in reducing thermal fatigue, as well as the size, vibrations and energy consumption of AM absorbers.",

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author = "Younes Chahid and Carolyn Atkins and Stephen Hodbod and John Robinson and Xia Liu and Stephen Watson and Maia Jones and Mark Cliffe and Dayo Ogunkanmi and Richard Kotlewski and Lee Chapman and Scott Beamish and {Linde Cerezo}, Jorge and Thomas Wearing and Ahmad Baroutaji and Arun Arjunan and Chantal Fowler and Paul Vivian",

note = "This is an open-access article distributed under the terms of the Creative Commons Attribution (CC-BY) Licence, which permits unrestricted use, distribution, and reproduction in any medium, provided the original authors and source are cited. ",

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Chahid, Y, Atkins, C, Hodbod, S, Robinson, J, Liu, X, Watson, S, Jones, M, Cliffe, M, Ogunkanmi, D, Kotlewski, R, Chapman, L, Beamish, S, Linde Cerezo, J, Wearing, T, Baroutaji, A, Arjunan, A, Fowler, C & Vivian, P 2025, 'Optimizing a photon absorber using conformal cooling channels and additive manufacturing in copper', Journal of Synchrotron Radiation, vol. 32, no. Pt 4. https://doi.org/10.1107/s1600577525003078

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T1 - Optimizing a photon absorber using conformal cooling channels and additive manufacturing in copper

AU - Chahid, Younes

AU - Atkins, Carolyn

AU - Hodbod, Stephen

AU - Robinson, John

AU - Liu, Xia

AU - Watson, Stephen

AU - Jones, Maia

AU - Cliffe, Mark

AU - Ogunkanmi, Dayo

AU - Kotlewski, Richard

AU - Chapman, Lee

AU - Beamish, Scott

AU - Linde Cerezo, Jorge

AU - Wearing, Thomas

AU - Baroutaji, Ahmad

AU - Arjunan, Arun

AU - Fowler, Chantal

AU - Vivian, Paul

N1 - This is an open-access article distributed under the terms of the Creative Commons Attribution (CC-BY) Licence, which permits unrestricted use, distribution, and reproduction in any medium, provided the original authors and source are cited.

PY - 2025/7

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N2 - Many of the 70 synchrotron facilities worldwide are undergoing upgrades to their infrastructure to meet a growing demand for increased beam brightness with nanometre‐level stability. These upgrades increase the mechanical and thermal challenges faced by beamline components, creating opportunities to apply novel methodologies and manufacturing processes to optimize hardware performance and beam accuracy. Absorbers are important beamline components that rely on water‐cooled channels to absorb thermal energy from excess light caused by synchrotron radiation or photon beams created by insertion devices, all within a limited volume, to protect downstream equipment and ensure safe, reliable operation. Additive manufacturing (AM) has been shown to meet criteria relevant to synchrotron environments like leak tightness and vacuum compatibility. However, there is a research gap on the heat transfer and pressure drop impact of different AM conformal cooling channel geometries, as well as the print quality of AM copper parts using low‐power infrared lasers and their compliance with absorber requirements. In this study, an intermediate model of a Diamond Light Source photon absorber was optimized to incorporate AM conformal cooling channels, leading to two concept designs named `Horizontal' and `Coil'. When compared with the baseline design, the lightweight Horizontal concept performed the best in this study, with simulations showing a maximum temperature drop of 11%, a calculated pressure drop reduction of 82%, a mass reduction of 86%, and the consolidation of 21 individually brazed pipes into a single manifold. The AM print quality and compliance with the synchrotron environment was examined by producing custom benchmark artefacts and measuring their surface roughness, dimensional accuracy and porosity levels, which are characteristics that can affect heat absorption, structural integrity, thermal conductivity and vacuum performance. The study demonstrates the benefits and addresses outstanding challenges in reducing thermal fatigue, as well as the size, vibrations and energy consumption of AM absorbers.

AB - Many of the 70 synchrotron facilities worldwide are undergoing upgrades to their infrastructure to meet a growing demand for increased beam brightness with nanometre‐level stability. These upgrades increase the mechanical and thermal challenges faced by beamline components, creating opportunities to apply novel methodologies and manufacturing processes to optimize hardware performance and beam accuracy. Absorbers are important beamline components that rely on water‐cooled channels to absorb thermal energy from excess light caused by synchrotron radiation or photon beams created by insertion devices, all within a limited volume, to protect downstream equipment and ensure safe, reliable operation. Additive manufacturing (AM) has been shown to meet criteria relevant to synchrotron environments like leak tightness and vacuum compatibility. However, there is a research gap on the heat transfer and pressure drop impact of different AM conformal cooling channel geometries, as well as the print quality of AM copper parts using low‐power infrared lasers and their compliance with absorber requirements. In this study, an intermediate model of a Diamond Light Source photon absorber was optimized to incorporate AM conformal cooling channels, leading to two concept designs named `Horizontal' and `Coil'. When compared with the baseline design, the lightweight Horizontal concept performed the best in this study, with simulations showing a maximum temperature drop of 11%, a calculated pressure drop reduction of 82%, a mass reduction of 86%, and the consolidation of 21 individually brazed pipes into a single manifold. The AM print quality and compliance with the synchrotron environment was examined by producing custom benchmark artefacts and measuring their surface roughness, dimensional accuracy and porosity levels, which are characteristics that can affect heat absorption, structural integrity, thermal conductivity and vacuum performance. The study demonstrates the benefits and addresses outstanding challenges in reducing thermal fatigue, as well as the size, vibrations and energy consumption of AM absorbers.

KW - particle accelerator

KW - additive manufacturing

KW - 3D printing

KW - pressure drop

KW - heat transfer

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JO - Journal of Synchrotron Radiation

JF - Journal of Synchrotron Radiation

IS - Pt 4

ER -

Optimizing a photon absorber using conformal cooling channels and additive manufacturing in copper

Abstract

Bibliographical note

Data Access Statement

Keywords

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