Critical-Dimension Measurement using Multi-Angle-Scanning Method in Atomic Force Microscope

Murayama, Kazuro; Gonda, Satoshi; Koyanagi, Hajime; Terasawa, Tsuneo; Hosaka, Sumio

doi:10.1143/jjap.45.5928

Cited by 22 publications

(24 citation statements)

References 12 publications

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“…And the measured 16 is an estimation of the cantilever tilt angle, which is designed to be 12 in the AFM used in the experiments. 15 Therefore, the dynamic convolution model is of special significance to precisely and quantitatively measure the sharp nanostructures and will be especially useful in CD measurements 16,17 and in the probe characterization. 7,18 For the critical dimension measurements in dynamic mode, the amplitude effect should be removed to get more accurate results.…”

Section: Resultsmentioning

confidence: 99%

Cantilever Tilt Causing Amplitude Related Convolution in Dynamic Mode Atomic Force Microscopy

et al. 2011

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Section: Resultsmentioning

confidence: 99%

Cantilever Tilt Causing Amplitude Related Convolution in Dynamic Mode Atomic Force Microscopy

et al. 2011

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“…The VAP method is similar to a step-in measurement method proposed in [8], and the difference is that the "VAP" method can work both in contact and dynamic modes. Using the VAP method, the structure is measured point by point.…”

Section: Probing and Measurement Strategymentioning

confidence: 99%

New developments at PTB in 3D-AFM with tapping and torsion AFM mode and vector approach probing strategy

et al. 2011

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A new 3D-AFM for true 3D measurements of nano structures has been developed at Physikalisch TechnischeBundesanstalt, the national metrology institute of Germany. In its configuration, two piezo actuators are applied to drive the AFM cantilever near its vertical and torsional resonant frequencies. In such a way, the AFM tip can probe the surface with a vertical and/or a lateral oscillation, offering high 3D probing sensitivity. For enhancing measurement flexibility as well as reducing tip wear, a so called "vector approach probing" (VAP) method has been applied. The sample is measured point by point using this method. At each probing point, the tip is approached towards the surface in its normal direction until the desired tip-sample interaction is detected and then immediately withdrawn from the surface. Preliminary experimental results show promising performance of the developed system. The measurement of a line structure of 800 nm height employing a super sharp AFM tip is performed, showing a repeatability of its 3D profiles of better than 1 nm (p-v). A single crystal critical dimension reference material (SCCDRM) having features with almost vertical sidewall is measured using a flared AFM tip. Results show that the feature has averaged left and right sidewall angles of 88.64° and 88.67°, respectively. However, the feature width non-uniformity may reach 10 nm within the measurement range of 1 μm. The standard deviation of the averaged middle CD values of 7 repeated measurements reaches 0.35 nm. In addition, an investigation of long term measurement stability is performed on a PTB photomask. The results shows that the 3D-AFM has a drift rate of about 0.00033 nm per line, which confirms the high measurement stability and the very low tip wear.

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“…AFM cantilevers with special tips have been applied in different measurement ways. Murayama et al have developed a multiangle step in method with a sharpened tip [ 14 , 15 ]. In their method, the tip probed the surface point-by-point at different angles in a static mode.…”

Section: Introductionmentioning

confidence: 99%

Three-Dimensional Atomic Force Microscopy for Sidewall Imaging Using Torsional Resonance Mode

Liu

Zhang

et al. 2018

Scanning

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This article presents an atomic force microscopy (AFM) technique for true three-dimensional (3D) characterization. The cantilever probe with flared tip was used in a home-made 3D-AFM system. The cantilever was driven by two shaking piezoceramics and oscillated around its vertical or torsional resonance frequency. The vertical resonance mode was used for upper surface imaging, and the torsional resonance mode was used for sidewall detecting. The 3D-AFM was applied to measure standard gratings with the height of 100 nm and 200 nm. The experiment results showed that the presented 3D-AFM technique was able to detect the small defect features on the steep sidewall and to reconstruct the 3D topography of the measured structure.

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Critical-Dimension Measurement using Multi-Angle-Scanning Method in Atomic Force Microscope

Cited by 22 publications

References 12 publications

Cantilever Tilt Causing Amplitude Related Convolution in Dynamic Mode Atomic Force Microscopy

Cantilever Tilt Causing Amplitude Related Convolution in Dynamic Mode Atomic Force Microscopy

New developments at PTB in 3D-AFM with tapping and torsion AFM mode and vector approach probing strategy

Three-Dimensional Atomic Force Microscopy for Sidewall Imaging Using Torsional Resonance Mode

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