The PDF file includes:

• Fig. S1. Schematic of experimental setup of LIA of bacteria.
• Fig. S2. Preparation and structural evaluation of honeycomb substrate.
• Fig. S3. Elemental analysis of honeycomb substrate.
• Fig. S4. Behavior of bacteria (P. aeruginosa) trapped in pores of honeycomb substrate during laser irradiation under bright-field condition (transparent optical image).
• Fig. S5. Survival confirmation of bacteria on honeycomb substrate.
• Fig. S6. Fluorescence image of trapped P. aeruginosa by changing laser power (20-s irradiation for each).
• Fig. S7. Fluorescence image of trapped S. aureus by changing laser power (20-s irradiation for each).
• Fig. S8. Comparative experiment of LIA of bacteria with flat gold film thickness: 10 nm in (27).
• Fig. S9. Thermographic images of flat Au film and Au-coated honeycomb substrate before and after infrared laser irradiation of 100 mW through 10× dry objective lens (initial power was 200 mW).
• Fig. S10. Thermographic images of flat Au film and Au-coated honeycomb substrate before and after infrared laser irradiation of 35 mW through 10× dry objective lens (initial power was 90 mW).
• Fig. S11. Thermographic images of flat Au film and Au-coated honeycomb substrate before and after infrared laser irradiation of 20 mW through 10× dry objective lens (initial power was 65 mW).
• Fig. S12. Model for the calculation of light-induced convection in honeycomb substrate.
• Fig. S13. Simulation of optical response of a gold thin film on the substrate.
• Legends for movies S1 and S2

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Other Supplementary Material for this manuscript includes the following:

• Movie S1 (.mp4 format). An example of fluorescence image of LIA process of S. aeruginosa into Au-coated honeycomb substrate (SYTO 9) with a laser power of 40 mW similar to Fig. 2B.
• Movie S2 (.mp4 format). Transparent image of S. aeruginosa in Au-coated honeycomb substrate after LIA, which corresponds to fig. S4.