Method for creation of inclined microstructures using a scanned laser image
First Claim
1. A method of controlling inclination and depth of ablation of a workpiece by an energy beam comprising the steps of:
- a) providing a workpiece;
b) generating an energy beam and directing said beam at said workpiece to ablate portions of the surface thereof;
c) moving the workpiece relative to said beam at a velocity to create a path of ablated material from the workpiece surface, said path of ablated material having ramps at each end of said path; and
d) controlling the velocity of said workpiece relative to ablation rate of material from the workpiece surface to create a desired inclination of said ramps and depth of ablated material in said path.
2 Assignments
0 Petitions
Accused Products
Abstract
A system for controlling inclination and depth of ablation of a polymer planar waveguide or semiconductor wafer substrate utilizes a laser which directs the beam at the substrate to ablate portions of the surface thereof and a translatable stage for moving the substrate relative to the beam to create a path of ablated material from the surface. The velocity of the substrate is controlled relative to ablation rate of material from the surface or the dimension of the beam is controlled along the path of ablated material to create a desired inclination and depth of ablated material in the path. The depth of ablated material is a function of the beam width along the path of ablated material, workpiece velocity and ablation rate and is substantially controlled by the formula:
where D is the depth of ablated material, R is ablation rate, W is beam dimension along the path of ablated material, and V is workpiece velocity.
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Citations
22 Claims
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1. A method of controlling inclination and depth of ablation of a workpiece by an energy beam comprising the steps of:
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a) providing a workpiece;
b) generating an energy beam and directing said beam at said workpiece to ablate portions of the surface thereof;
c) moving the workpiece relative to said beam at a velocity to create a path of ablated material from the workpiece surface, said path of ablated material having ramps at each end of said path; and
d) controlling the velocity of said workpiece relative to ablation rate of material from the workpiece surface to create a desired inclination of said ramps and depth of ablated material in said path. - View Dependent Claims (2, 3, 4, 5, 6)
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4. The method of claim 2 wherein the ramps at each end of said path of ablated material have slopes substantially determined by the formula:
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5. The method of claim 1 wherein said step (b) generates a continuous wave laser beam.
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6. The method of claim 1 wherein said step (b) generates a pulsed laser beam.
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7. A method of controlling inclination and depth of ablation of a workpiece by an energy beam comprising the steps of:
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a) providing a workpiece;
b) generating an energy beam and directing said beam at said workpiece to ablate portions of the surface thereof;
c) moving the workpiece relative to said beam to create a path of ablated material from the workpiece surface, said path of ablated material having ramps at each end of said path; and
d) controlling the dimension of said beam along the path of ablated material to create a desired inclination of said ramps and depth of ablated material in said path. - View Dependent Claims (8, 9, 10, 11, 12)
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10. The method of claim 8 wherein the ramps at each end of said path of ablated material have slopes substantially determined by the formula:
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11. The method of claim 7 wherein said step (b) generates a continuous wave laser beam.
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12. The method of claim 7 wherein said step (b) generates a pulsed laser beam.
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13. A method of controlling inclination and depth of ablation of a workpiece by an energy beam comprising the steps:
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a) providing a workpiece;
b) generating an energy beam and directing said beam at said workpiece to ablate portions of the surface thereof;
c) creating a path of ablated material having ramps at ends thereof by moving said workpiece relative to said energy beam at a velocity whereby said energy beam forms an initial ramp at a first end of said path, travels along a length of said path, and forms a final ramp at a second end of said path; and
d) controlling the velocity of said workpiece relative to ablation rate of material from the workpiece surface to create desired inclinations of said initial and final ramps of said path and a desired depth of said path of ablated material. - View Dependent Claims (14, 15, 16, 17)
e) directing said energy beam at said path of ablated material; and
f) increasing said inclinations of said initial and final ramps of said path and said depth of said path of ablated material using said energy beam.
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15. The method of claim 13 wherein the depth of ablated material is substantially controlled by the formula:
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16. The method of claim 13 wherein said initial and final ramps have slopes substantially determined by the formula:
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17. The method of claim 13 wherein said step (c) said energy beam forms said initial ramp at said first end of said path by ablating said workpiece down from a top surface of said workpiece to a bottom of said path, and forms said final ramp at said second end of said path by ablating said workpiece up from said bottom of said path to said top surface of said workpiece.
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18. A method of controlling inclination and depth of ablation of a workpiece by an energy beam comprising the steps of:
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a) providing a workpiece;
b) generating an energy beam and directing said beam at said workpiece to ablate portions of the surface thereof;
c) creating a path of ablated material having ramps at ends thereof by moving said workpiece relative to said energy beam whereby said energy beam forms an initial ramp at a first end of said path, travels along a length of said path, and forms a final ramp at a second end of said path; and
d) controlling the dimension of said beam along the path of ablated material to create desired inclinations of said initial and final ramps of said path and a desired depth of said path of ablated material. - View Dependent Claims (19, 20, 22)
e) directing said energy beam at said path of ablated material; and
f) increasing said inclinations of said initial and final ramps of said path and said depth of said path of ablated material using said energy beam.
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20. The method of claim 18 wherein the depth of ablated material is substantially controlled by the formula:
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22. The method of claim 18 wherein said step (c) said energy beam forms said initial ramp at said first end of said path by ablating said workpiece down from a top surface of said workpiece to a bottom of said path, and forms said final ramp at said second end of said path by ablating said workpiece up from said bottom of said path to said top surface of said workpiece.
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21. The method of claim herein said initial and final ramps have slopes substantially determined by the formula:
Specification