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Towards Large Scale Atomic Manufacturing: Heterodyne Grating Interferometer with Zero Dead-Zone

Can Cui, Lvye Gao, Pengbo Zhao, Menghan Yang, Lifu Liu, Yu Ma, Guangyao Huang, Shengtong Wang, Linbin Luo, Xinghui Li

Abstract

This paper presents a novel heterodyne grating interferometer designed to meet the precise measurement requirements of next-generation lithography systems and large-scale atomic-level manufacturing. Utilizing a dual-frequency light source, the interferometer enables simultaneous measurement of three degrees of freedom. Key advancements include a compact zero Dead-Zone optical path configuration, significantly enhancing measurement reliability by mitigating the impact of light source fluctuations and air refractive index variations. A comprehensive crosstalk error analysis was conducted, resulting in a robust correction algorithm that reduces errors to below 5%. Performance testing of the prototype, size of 90mm*90mm*40mm, demonstrated exceptional resolution (0.25 nm in the XY-axis and 0.3 nm in the Z-axis), superior linearity (6.9e-5, 8.1e-5 and 16.2e-5 for the X, Y, and Z axes, respectively), high repeatability (0.8 nm/1000 nm for the three axes) and stability (20 nm for the XY-axis and 60 nm for the Z-axis over 1000 seconds). Comparative analysis with existing measurement sensors highlights the proposed method's significant advantages in integration, multidimensional capabilities, and is expected to be widely used in fields such as integrated circuits, atomic-level manufacturing and aerospace technology.

Towards Large Scale Atomic Manufacturing: Heterodyne Grating Interferometer with Zero Dead-Zone

Abstract

This paper presents a novel heterodyne grating interferometer designed to meet the precise measurement requirements of next-generation lithography systems and large-scale atomic-level manufacturing. Utilizing a dual-frequency light source, the interferometer enables simultaneous measurement of three degrees of freedom. Key advancements include a compact zero Dead-Zone optical path configuration, significantly enhancing measurement reliability by mitigating the impact of light source fluctuations and air refractive index variations. A comprehensive crosstalk error analysis was conducted, resulting in a robust correction algorithm that reduces errors to below 5%. Performance testing of the prototype, size of 90mm*90mm*40mm, demonstrated exceptional resolution (0.25 nm in the XY-axis and 0.3 nm in the Z-axis), superior linearity (6.9e-5, 8.1e-5 and 16.2e-5 for the X, Y, and Z axes, respectively), high repeatability (0.8 nm/1000 nm for the three axes) and stability (20 nm for the XY-axis and 60 nm for the Z-axis over 1000 seconds). Comparative analysis with existing measurement sensors highlights the proposed method's significant advantages in integration, multidimensional capabilities, and is expected to be widely used in fields such as integrated circuits, atomic-level manufacturing and aerospace technology.

Paper Structure

This paper contains 18 sections, 7 equations, 11 figures.

Table of Contents

  1. Introduction
  2. Design and Measurement Principle
  3. Optical Design
  4. Measurement Principle
  5. Zero Dead-Zone Optical Path
  6. System and Experiments
  7. Prototype System
  8. Laser Source
  9. Measurement System
  10. Performance Test and Results
  11. Resolution
  12. Linearity
  13. Stability
  14. Repeatability
  15. Error Analysis and Correction
  16. ...and 3 more sections

Figures (11)

  • Figure 1: Framework of grating interferometer system for 3-DOF measurement, where "a, b, c...m" represent the propagation order of the light path. PPLN: Periodically Poled Lithium Niobate; HWP: Half-Wave Plate; QWP: Quarter Wave Plate; COL: Fiber Coupler; AOM: Acousto-Optic Modulator; P: Polarizer; PBS: Polarizing Beam Splitter; PD: Photo Detector; PZT: Piezoelectric Stage.
  • Figure 2: XYZ-axis measurement error caused by Dead-Zone.
  • Figure 3: Light propagation path in the XOZ plane.
  • Figure 4: Prototype of grating interferometer system for 3D measurement. (a) Heterodyne dual frequency light source. (b) Measurement system, including reading head, 2D grating, 3-DOF Piezoelectric Stage (PZT) and real-time processing display module.
  • Figure 5: Beam profiler test results of light sources. (a) Top view of Beam. (b) 3D view of Beam.
  • ...and 6 more figures