The semiconductor industry needs to fit ever more devices per unit area to improve their performance; hence a trend towards increasingly complex structures by varying material combinations and 3D geometries with increasing aspect ratios. The new materials used may be optically opaque, posing problems for traditional optical metrology methods. One solution is to use acoustical waves, which present the double advantage of not being hampered by optically opaque layers and allowing for penetration depths of 10’s of μm at sub-μm wavelengths; which is considerably larger than most traditional optical methods (O(100 nm’s - μm’s)). Here, we present a novel acoustic metrology method using GHz ultrasound waves to measure deeply buried subsurface features (<5 μm). The concept consisted of a GHz acoustic transducer integrated above the tip of a custom designed probe, which is then scanned across a sample. The method uses non-damaging solid-solid contact without the need for liquid coupling layers – in contrast to conventional acoustical microscopy. This allows for the use of much higher acoustic frequencies, hence higher on-axis resolutions. The transducer is used in pulse-echo mode and a stage controller is used to move the probe for scanning. An experimental setup was built with a 4 GHz transducer and tested successfully on 1.5-2 μm size features buried below a 5 μm PMMA or 10 μm SiO2 layer, respectively. A good match was further obtained between the measurements and the model predictions. These results demonstrated the feasibility of the new method, opening new opportunities for metrology and inspection applications.
In order to extract ever more performance from semiconductor devices on the same device area, the semiconductor industry is moving towards device structures with increasingly complex material combinations and 3D geometries. To ensure cost effective fabrication of next generation devices, metrology solutions are needed that tackle the specific challenges that come from these developments such as 3 dimensional imaging of structures and imaging of deeply buried structures under arbitrary, complex layers. Compared to existing metrology solutions for high end manufacturing, ultrasonic inspection techniques have advantages: they are unaffected by optically opaque layers, the acoustic wavelength (60nm @ 100GHz in SiO2) can be smaller than optical wavelengths and the measurement depth can be larger. However, traditional acoustic microscopy tops out at a few GHz due to manufacturing tolerances and the required liquid couplant. We propose to combine very high frequency ultrasound with scanning probe microscopy. By locating the transducer above the cantilever tip, it guides sound into the sample with a dry tip-sample contact. This allows for very high acoustic frequencies and a resolution of O(wavelength).
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