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Acoustic microscopy

September 05, 2023

Acoustic microscopy is microscopy that employs very high or ultra high frequency ultrasound. Acoustic microscopes operate non-destructively and penetrate most solid materials to make visible images of internal features, including defects such as cracks, delaminations and voids.

History Edit

The notion of acoustic microscopy dates back to 1936 when S. Ya. Sokolov[1] proposed a device for producing magnified views of structure with 3-GHz sound waves. However, due to technological limitations at the time, no such instrument could be constructed, and it was not until 1959 that Dunn and Fry[2] performed the first acoustic microscopy experiments, though not at very high frequencies.

The scientific literature shows very little progress toward an acoustic microscope following the Dunn and Fry experiments up until about 1970 when two groups of activity emerged, one headed by C.F. Quate (Stanford University) and the other by A. Korpel and L.W. Kessler (Zenith Radio Research Labs). The first efforts to develop an operational acoustic microscope concentrated upon high-frequency adaptations of low-frequency ultrasonic visualization methods. One early system employed Bragg diffraction imaging,[3] which is based upon direct interaction between an acoustic-wave field and a laser light beam. Another example was based on variations of the Pohlman cell.[4] The original device is based upon a suspension of asymmetric particles in a thin fluid layer which, when acted upon by acoustic energy, produce visual reflectivity changes. Cunningham and Quate[5] modified this by suspending tiny latex spheres in a fluid. Acoustic pressure caused population shifts which were visually detectable. Kessler and Sawyer[6] developed a liquid crystal cell that enabled sound to be detected by hydrodynamic orientation of the fluid. In 1973, the Quate group began the development of a concept,[7] which utilized the first scanning acoustic microscope (SAM) with a confocal pair of 50 MHz ultrasonic lenses for focusing and detecting the ultrasonic energy. In 1974, this concept was realized by R. A. Lemons and C. F. Quate at the Microwave Laboratory of Stanford University. Advancements of this instrument, a scanning acoustic microscope, have to do with achieving very high resolution, novel modes of imaging, and applications. The SAM was commercially introduced by Leitz Corp and by Olympus Corp. In 1970, the Korpel and Kessler group began to pursue a scanning laser detection system for acoustic microscopy.[8] In 1974, the activity was shifted to another organization under Kessler (Sonoscan Inc), where practical aspects of the instrument were developed. This instrument, the scanning laser acoustic microscope (SLAM), was made commercial available in 1975.[9]

In 1980, first high-resolution (with a frequency up to 500 MHz) through-transmission mode SAM was built by Roman Maev and his students at his Laboratory of Biophysical Introscopy of the Russian Academy of Sciences.[10] First commercial SAM ELSAM with the broad frequency range from 100 MHz up to ultra high 1.8 GHz was built at the Ernst Leitz GmbH (Wetzlar, Germany) by the group led by Martin Hoppe and his consultants Abdullah Atalar (Stanford Univ.,USA), Roman Maev(Russian Academy of Sciences, Russia), at University College London by Mehrdad Nikoonahad[11][12] and later by Andrew Briggs (Oxford Univ., Great Britain.).[13][14]

At the same time, in 1984, Kessler's group completed development of the C-SAM concept instrument[15] which operated in the reflection mode, as well as the through-transmission (only) mode of the SLAM. Using the same transducer to pulse ultrasound and receive the return echoes meant that the acoustic image could easily be constrained to a depth of interest. This design was the precursor of essentially all of the acoustic microscopes in use today, and was the development that made possible numerous later advances such as cross-sectional acoustic imaging, three-dimensional acoustic imaging, and others.

Since then, many improvements to Acoustic Microscopy Systems have been made to enhance resolution, image quality and accuracy.[16][17][18]

Types of acoustic microscopes Edit

In the half-century since the first experiments directly leading to the development of acoustic microscopes, at least three basic types of acoustic microscope have been developed. These are the scanning acoustic microscope (SAM), confocal scanning acoustic microscope (CSAM), and C-mode scanning acoustic microscope (C-SAM).[19]

More recently acoustic microscopes based around picosecond ultrasonics systems have demonstrated acoustic imaging in cells using sub-optical wavelengths working with ultrasonic frequencies into the multi-GHz. Since the vast majority of acoustic microscopes in use today are C-SAM type instruments, this discussion will be limited to these instruments.[20]

Behavior of ultrasound in materials Edit

Ultrasound is broadly defined as any sound having a frequency above 20 kHz, which is approximately the highest frequency that can be detected by the human ear. However, the acoustic microscopes emit ultrasound ranging from 5 MHz to beyond 400 MHz so that micrometre size resolution can be achieved. The ultrasound that penetrates a sample may be scattered, absorbed or reflected by the internal features or the material itself. These actions are analogous to the behavior of light. Ultrasound that is reflected from an internal feature, or (in some applications) that has traveled through the entire thickness of the sample, is used to make acoustic images.

Sample types and preparation Edit

Samples need no special treatment before acoustic imaging, but they should be able to withstand at least brief exposure to water or to another fluid, since air is a very poor transmitter of high frequency acoustic energy from the transducer. The sample may be completely immersed in the water, or scanned with a narrow stream of water. Alternately, alcohols and other fluids can be used so as to not contaminate the sample. Samples typically have at least one flat surface that can be scanned, although cylindrical and spherical samples can also be scanned with the proper fixtures. In the following paragraphs, the sample being described is a plastic-encapsulated integrated circuit.

Ultrasonic frequencies Edit

The ultrasonic frequencies pulsed into samples by the transducers of acoustic microscopes range from a low of 10 MHz (rarely, 5 MHz) to a high of 400 MHz or more. Across this spectrum of frequencies there is a trade-off of penetration and resolution. Ultrasound at low frequencies such as 10 MHz penetrates deeper into materials than ultrasound at higher frequencies, but the spatial resolution of the acoustic image is less. On the other hand, ultrasound at very high frequencies do not penetrate deeply, but provide acoustic images having very high resolution. The frequency chosen to image a particular sample will depend on the geometry of the part and on the materials involved.

The acoustic image of the plastic-encapsulated IC below was made using a 30 MHz transducer because this frequency provides a good compromise between penetration and image resolution.

Scanning process Edit

 
In the acoustic image ultrasound was pulsed through the black mold compound (plastic), and reflected from the interface between the overlying mold compound and the top surface of the silicon die, the top surface of the die paddle, delaminations (red) on top of the die paddle, and the outer portion (lead fingers) of the lead frame.
 
Side-view diagram

The ultrasonic transducer raster-scans the top surface of the sample. Several thousand pulses enter the sample each second. Each pulse may be scattered or absorbed in passing through homogeneous parts of the sample. At material interfaces, a portion of the pulse is reflected back to the transducer, where it is received and its amplitude recorded.

The portion of the pulse that is reflected is determined by the acoustic impedance, Z, of the each material that meets at the interface. The acoustic impedance of a given material is the material's density multiplied by the speed of ultrasound in that material. When a pulse of ultrasound encounters an interface between two materials, the degree of ultrasonic reflection from that interface is governed by this formula:

 

where R is the fraction of reflection, and z1 and z2 are the acoustic impedances of the two materials, analogous to refractive index in light propagation.

If both materials are typical solids, the degree of reflection will be moderate, and a significant portion of the pulse will travel deeper into the sample, where it may be in part reflected by deeper material interfaces. If one of the materials is a gas such as air – as in the case with delaminations, cracks and voids – the degree of reflection at the solid-to-gas interface is near 100%, the amplitude of the reflected pulse is very high, and practically none of the pulse travels deeper into the sample.

Gating of the return echoes Edit

A pulse of ultrasound from the transducer travel nanoseconds or microseconds to reach an internal interface and are reflected back to the transducer. If there are several internal interfaces at different depths, the echoes arrive at the transducer at different times. Planar acoustic images do not often use all return echoes from all depths to make the visible acoustic image. Instead, a time window is created that accepts only those return echoes from the depth of interest. This process is known as "gating" the return echoes.

 
In the plastic-encapsulated IC, gating was on a depth that included the silicon die, the die paddle and the lead frame.
 
Still scanning the top of the sample, the gating of the return echoes was then changed to include only the plastic encapsulant (mold compound) above the die. The resulting acoustic image is shown above. It shows the structure of the particle-filled plastic mold compound, as well as the circular mold marks at the top surface of the component. The small white features are voids (trapped bubbles) in the mold compound. (These voids are also visible in the previous image as dark acoustic shadows.)
 
Gating was then changed to include only depth of the die attach material that attaches the silicon die to the die paddle. The die, the die paddle, and other features above and below the die attach depth are ignored. In the resulting acoustic, shown above slightly magnified, the red areas are voids (defects) in the die attach material.

Finally, the plastic-encapsulated IC was flipped over and imaged from the back side. The return echoes were gated on the depth where the backside mold compound interfaces with the back side of the die paddle. The small black dots in the acoustic image above are small voids (trapped bubbles) in the mold compound.

Other image types Edit

The acoustic images shown above are all planar images, so named because they make visible a horizontal plane within the sample. The acoustic data received in the return echo signals can also be used to make other types of images, including three-dimensional images, cross-sectional images, and thru-scan images.

Range of applications Edit

The samples imaged by acoustic microscopes are typically assemblies of one or more solid materials that have at least one surface that is either flat or regularly curved. The depth of interest may involve an internal bond between materials, or a depth at which a defect may occur in a homogeneous material. In addition, samples may be characterized without imaging to determine, e.g., their acoustic impedance.

Because of their ability to find visualize features non-destructively, acoustic microscopes are widely used in the production of electronic components and assemblies for quality control, reliability and failure analysis. Usually the interest is in finding and analyzing internal defects such as delaminations, cracks and voids, although an acoustic microscope may also be used simply to verify (by material characterization or imaging, or both) that a given part or a given material meets specifications or, in some instances, is not counterfeit.[21] Acoustic microscopes are also used to image printed circuit boards[22] and other assemblies.

There are in addition numerous applications outside of electronics. In many industries, products that involve tubing, ceramic materials, composite materials or various types of bonded joints, including adhesive layers and different welds may be imaged acoustically.

The assembly of numerous medical products uses acoustic microscopes to investigate internal bonds and features. For example, a polymer film may be imaged to examine its bond to a multi-channel plastic plate used in blood analysis. SAM can provide data on the elasticity of cells and both, hard and soft tissues, which can give useful information on the physical forces holding structures in a particular shape and the mechanics of structures such as the cytoskeleton.[3][4] These studies are particularly valuable in investigating processes such as cell motility.[5][6]

Another promising direction was initiated by different groups in the world to design and build portable hand-held SAM for subsurface 3D imaging and diagnostics of soft and hard tissues[20][23] and this direction currently is successfully developing with the goal to implement those methods into the clinical and cosmetology practice.

Also during last decade was expressed an interest to apply acoustic microscopy methods for 3D non-invasive inspection of the paint layers of painted art and other art and culture heritage objects.[24][25]

See also Edit

References Edit

 
Wikimedia Commons has media related to Scanning acoustic microscopy.
  1. ^ S. Sokolov, USSR Patent no. 49 (31 August 1936), British Patent no. 477,139, 1937, and U.S. Patent 2,164,125, 1939.
  2. ^ Dunn, Floyd (1959). "Ultrasonic Absorption Microscope". The Journal of the Acoustical Society of America. 31 (5): 632–633. Bibcode:1959ASAJ...31..632D. doi:10.1121/1.1907767.
  3. ^ a b Korpel, A. (1966). "Visualization of the Cross Section of a Sound Beam by Bragg Diffraction of Light". Applied Physics Letters. 9 (12): 425–427. Bibcode:1966ApPhL...9..425K. doi:10.1063/1.1754639.
  4. ^ a b R. Pohlman, "Material illumination by means of acoustic optical imagery," Z. Phys., 1133 697, 1939. See also Z. Angew. Phys., vol. 1, p. 181, 1948.
  5. ^ a b J. A. Cunningham and C. F. Quate, "Acoustic interference in solids and holographic imaging," in Acoustical Holography, vol. 4, G. Wade, Ed., New York: Plenum, 1972, pp. 667–685.
  6. ^ a b Kessler, L. W. (1970). "Ultrasonic Stimulation of Optical Scattering in Nematic Liquid Crystals". Applied Physics Letters. 17 (10): 440–441. Bibcode:1970ApPhL..17..440K. doi:10.1063/1.1653262.
  7. ^ Lemons, R. A. (1974). "Acoustic microscope—scanning version". Applied Physics Letters. 24 (4): 163–165. Bibcode:1974ApPhL..24..163L. doi:10.1063/1.1655136.
  8. ^ A. Korpel and L. W. Kessler, "Comparison of methods of acoustic microscopy," in Acoustical Holography, vol. 3 by A. F. Metherell, Ed., New York: Plenum, 1971, pp. 23–43.
  9. ^ Kessler, L.W.; Yuhas, D.E. (1979). "Acoustic microscopy—1979". Proceedings of the IEEE. 67 (4): 526. Bibcode:1979IEEEP..67..526K. doi:10.1109/PROC.1979.11281. S2CID 30304663.
  10. ^ R. Gr. Maev, Principles and Future of Acoustic Microscopy, Proceedings of the Joint Soviet-West Germany International Symposium on Microscope Photometry and Acoustic Microscopy in Science, Moscow, Russia, 1-12, 1985.
  11. ^ Nikoonahad, Mehrdad (1984). "Recent Advances in High Resolution Acoustic Microscopy". Contemporary Physics. 25 (2): 129–158. Bibcode:1984ConPh..25..129N. doi:10.1080/00107518408230325.
  12. ^ Nikoonahad, Mehrdad (1984). "Reflection Acoustic Microscopy for Industrial NDE". Research Techniques in Nondestructive Testing (Edited by R.S. Sharppe). 7: 217–257. ISBN 0-12-639057-6.
  13. ^ M. Hoppe, R. Gr. Maev, Editors and Co-authors, Microscope Photometry and Acoustic Microscopy in Science, Proceedings of the FRG-USSR Symposium, Moscow, 231 pages, 1985
  14. ^ Hoppe, M., and Bereiter-Hahn, J., "Applications of scanning acoustic microscopy - survey and new aspects", IEEE Trans. Ultrason., Ferroelectr. Freq. Control, 32 (2), 289 –301 (1985)
  15. ^ "Acoustic Imaging and Acoustic Microscopes From Sonoscan Inc." Sonoscan. 11 July 2008
  16. ^ Briggs, Andrew (1992). Advanced in Acoustic Microscopy. Oxford University Press. ISBN 978-1-4615-1873-0.
  17. ^ Maev, Roman (2008). Acoustic Microscopy: Fundamentals and Applications. Wiley-VCH. ISBN 978-3-527-40744-6.
  18. ^ Maev, Roman (2013). Advances in Acoustic Microscopy and High Resolution Ultrasonic Imaging: From Principles to New Applications. Wiley-VCH. ISBN 978-3-527-41056-9.
  19. ^ Kessler, L.W., "Acoustic Microscopy", Metals Handbook, Vol. 17 – Nondestructive Evaluation and Quality Control, ASM International, 1989, pp. 465–482.
  20. ^ a b R.Gr. Maev, Editor and Co-author, Advances in Acoustic Microscopy and High Resolution Ultrasonic Imaging: From Principles to New Applications, Monograph, 14 Chapters, 400 pages, Wiley & Son - VCH, April 2013
  21. ^ Tulkoff, Cheryl. "Counterfeit Protection & Detection Strategies: When to Do It / How to Do It" (PDF). DfR Solutions.
  22. ^ O'Toole, Kevin; Esser, Bob; Binfield, Seth; Hillman, Craig; Beers, Joe (2009). "Pb-Free Reflow, PCB Degradation, and the Influence of Moisture Absorption" (PDF). APEX.
  23. ^ Vogt, M., and Ermert, H., "Limited-angle spatial compounding imaging of skin with high-frequency ultrasound", IEEE Trans. Ultrason., Ferroelectr. Freq. Control, 55 (9), 1975 –1983 (2011).
  24. ^ Georgios Karagiannis, Dimitrios Alexiadis, Argirios Damtsios, Georgios Sergiadis and Christos Salpistis, 3D non-destructive "sampling" of art objects, IEEE instrumentation and measurements, vol.60, issue 9, Pages 1-28, September 2011.
  25. ^ D. Thickett, C.S. Cheung, H. Liang, J. Twydle, R.Gr. Maev, D. Gavrilov, Using non-invasive non-destructive techniques to monitor cultural heritage objects, Insight Magazine, 59 (5): 230–234, 2017

September 05, 2023
acoustic, microscopy, microscopy, that, employs, very, high, ultra, high, frequency, ultrasound, acoustic, microscopes, operate, destructively, penetrate, most, solid, materials, make, visible, images, internal, features, including, defects, such, cracks, dela. Acoustic microscopy is microscopy that employs very high or ultra high frequency ultrasound Acoustic microscopes operate non destructively and penetrate most solid materials to make visible images of internal features including defects such as cracks delaminations and voids Contents 1 History 2 Types of acoustic microscopes 3 Behavior of ultrasound in materials 4 Sample types and preparation 5 Ultrasonic frequencies 6 Scanning process 6 1 Gating of the return echoes 7 Other image types 8 Range of applications 9 See also 10 ReferencesHistory EditThe notion of acoustic microscopy dates back to 1936 when S Ya Sokolov 1 proposed a device for producing magnified views of structure with 3 GHz sound waves However due to technological limitations at the time no such instrument could be constructed and it was not until 1959 that Dunn and Fry 2 performed the first acoustic microscopy experiments though not at very high frequencies The scientific literature shows very little progress toward an acoustic microscope following the Dunn and Fry experiments up until about 1970 when two groups of activity emerged one headed by C F Quate Stanford University and the other by A Korpel and L W Kessler Zenith Radio Research Labs The first efforts to develop an operational acoustic microscope concentrated upon high frequency adaptations of low frequency ultrasonic visualization methods One early system employed Bragg diffraction imaging 3 which is based upon direct interaction between an acoustic wave field and a laser light beam Another example was based on variations of the Pohlman cell 4 The original device is based upon a suspension of asymmetric particles in a thin fluid layer which when acted upon by acoustic energy produce visual reflectivity changes Cunningham and Quate 5 modified this by suspending tiny latex spheres in a fluid Acoustic pressure caused population shifts which were visually detectable Kessler and Sawyer 6 developed a liquid crystal cell that enabled sound to be detected by hydrodynamic orientation of the fluid In 1973 the Quate group began the development of a concept 7 which utilized the first scanning acoustic microscope SAM with a confocal pair of 50 MHz ultrasonic lenses for focusing and detecting the ultrasonic energy In 1974 this concept was realized by R A Lemons and C F Quate at the Microwave Laboratory of Stanford University Advancements of this instrument a scanning acoustic microscope have to do with achieving very high resolution novel modes of imaging and applications The SAM was commercially introduced by Leitz Corp and by Olympus Corp In 1970 the Korpel and Kessler group began to pursue a scanning laser detection system for acoustic microscopy 8 In 1974 the activity was shifted to another organization under Kessler Sonoscan Inc where practical aspects of the instrument were developed This instrument the scanning laser acoustic microscope SLAM was made commercial available in 1975 9 In 1980 first high resolution with a frequency up to 500 MHz through transmission mode SAM was built by Roman Maev and his students at his Laboratory of Biophysical Introscopy of the Russian Academy of Sciences 10 First commercial SAM ELSAM with the broad frequency range from 100 MHz up to ultra high 1 8 GHz was built at the Ernst Leitz GmbH Wetzlar Germany by the group led by Martin Hoppe and his consultants Abdullah Atalar Stanford Univ USA Roman Maev Russian Academy of Sciences Russia at University College London by Mehrdad Nikoonahad 11 12 and later by Andrew Briggs Oxford Univ Great Britain 13 14 At the same time in 1984 Kessler s group completed development of the C SAM concept instrument 15 which operated in the reflection mode as well as the through transmission only mode of the SLAM Using the same transducer to pulse ultrasound and receive the return echoes meant that the acoustic image could easily be constrained to a depth of interest This design was the precursor of essentially all of the acoustic microscopes in use today and was the development that made possible numerous later advances such as cross sectional acoustic imaging three dimensional acoustic imaging and others Since then many improvements to Acoustic Microscopy Systems have been made to enhance resolution image quality and accuracy 16 17 18 Types of acoustic microscopes EditIn the half century since the first experiments directly leading to the development of acoustic microscopes at least three basic types of acoustic microscope have been developed These are the scanning acoustic microscope SAM confocal scanning acoustic microscope CSAM and C mode scanning acoustic microscope C SAM 19 More recently acoustic microscopes based around picosecond ultrasonics systems have demonstrated acoustic imaging in cells using sub optical wavelengths working with ultrasonic frequencies into the multi GHz Since the vast majority of acoustic microscopes in use today are C SAM type instruments this discussion will be limited to these instruments 20 Behavior of ultrasound in materials EditUltrasound is broadly defined as any sound having a frequency above 20 kHz which is approximately the highest frequency that can be detected by the human ear However the acoustic microscopes emit ultrasound ranging from 5 MHz to beyond 400 MHz so that micrometre size resolution can be achieved The ultrasound that penetrates a sample may be scattered absorbed or reflected by the internal features or the material itself These actions are analogous to the behavior of light Ultrasound that is reflected from an internal feature or in some applications that has traveled through the entire thickness of the sample is used to make acoustic images Sample types and preparation EditSamples need no special treatment before acoustic imaging but they should be able to withstand at least brief exposure to water or to another fluid since air is a very poor transmitter of high frequency acoustic energy from the transducer The sample may be completely immersed in the water or scanned with a narrow stream of water Alternately alcohols and other fluids can be used so as to not contaminate the sample Samples typically have at least one flat surface that can be scanned although cylindrical and spherical samples can also be scanned with the proper fixtures In the following paragraphs the sample being described is a plastic encapsulated integrated circuit Ultrasonic frequencies EditThe ultrasonic frequencies pulsed into samples by the transducers of acoustic microscopes range from a low of 10 MHz rarely 5 MHz to a high of 400 MHz or more Across this spectrum of frequencies there is a trade off of penetration and resolution Ultrasound at low frequencies such as 10 MHz penetrates deeper into materials than ultrasound at higher frequencies but the spatial resolution of the acoustic image is less On the other hand ultrasound at very high frequencies do not penetrate deeply but provide acoustic images having very high resolution The frequency chosen to image a particular sample will depend on the geometry of the part and on the materials involved The acoustic image of the plastic encapsulated IC below was made using a 30 MHz transducer because this frequency provides a good compromise between penetration and image resolution Scanning process Edit nbsp In the acoustic image ultrasound was pulsed through the black mold compound plastic and reflected from the interface between the overlying mold compound and the top surface of the silicon die the top surface of the die paddle delaminations red on top of the die paddle and the outer portion lead fingers of the lead frame nbsp Side view diagramThe ultrasonic transducer raster scans the top surface of the sample Several thousand pulses enter the sample each second Each pulse may be scattered or absorbed in passing through homogeneous parts of the sample At material interfaces a portion of the pulse is reflected back to the transducer where it is received and its amplitude recorded The portion of the pulse that is reflected is determined by the acoustic impedance Z of the each material that meets at the interface The acoustic impedance of a given material is the material s density multiplied by the speed of ultrasound in that material When a pulse of ultrasound encounters an interface between two materials the degree of ultrasonic reflection from that interface is governed by this formula R z 2 z 1 z 2 z 1 displaystyle R frac left z 2 z 1 right left z 2 z 1 right nbsp where R is the fraction of reflection and z1 and z2 are the acoustic impedances of the two materials analogous to refractive index in light propagation If both materials are typical solids the degree of reflection will be moderate and a significant portion of the pulse will travel deeper into the sample where it may be in part reflected by deeper material interfaces If one of the materials is a gas such as air as in the case with delaminations cracks and voids the degree of reflection at the solid to gas interface is near 100 the amplitude of the reflected pulse is very high and practically none of the pulse travels deeper into the sample Gating of the return echoes Edit A pulse of ultrasound from the transducer travel nanoseconds or microseconds to reach an internal interface and are reflected back to the transducer If there are several internal interfaces at different depths the echoes arrive at the transducer at different times Planar acoustic images do not often use all return echoes from all depths to make the visible acoustic image Instead a time window is created that accepts only those return echoes from the depth of interest This process is known as gating the return echoes nbsp In the plastic encapsulated IC gating was on a depth that included the silicon die the die paddle and the lead frame nbsp Still scanning the top of the sample the gating of the return echoes was then changed to include only the plastic encapsulant mold compound above the die The resulting acoustic image is shown above It shows the structure of the particle filled plastic mold compound as well as the circular mold marks at the top surface of the component The small white features are voids trapped bubbles in the mold compound These voids are also visible in the previous image as dark acoustic shadows nbsp Gating was then changed to include only depth of the die attach material that attaches the silicon die to the die paddle The die the die paddle and other features above and below the die attach depth are ignored In the resulting acoustic shown above slightly magnified the red areas are voids defects in the die attach material Finally the plastic encapsulated IC was flipped over and imaged from the back side The return echoes were gated on the depth where the backside mold compound interfaces with the back side of the die paddle The small black dots in the acoustic image above are small voids trapped bubbles in the mold compound Other image types EditThe acoustic images shown above are all planar images so named because they make visible a horizontal plane within the sample The acoustic data received in the return echo signals can also be used to make other types of images including three dimensional images cross sectional images and thru scan images Range of applications EditThe samples imaged by acoustic microscopes are typically assemblies of one or more solid materials that have at least one surface that is either flat or regularly curved The depth of interest may involve an internal bond between materials or a depth at which a defect may occur in a homogeneous material In addition samples may be characterized without imaging to determine e g their acoustic impedance Because of their ability to find visualize features non destructively acoustic microscopes are widely used in the production of electronic components and assemblies for quality control reliability and failure analysis Usually the interest is in finding and analyzing internal defects such as delaminations cracks and voids although an acoustic microscope may also be used simply to verify by material characterization or imaging or both that a given part or a given material meets specifications or in some instances is not counterfeit 21 Acoustic microscopes are also used to image printed circuit boards 22 and other assemblies There are in addition numerous applications outside of electronics In many industries products that involve tubing ceramic materials composite materials or various types of bonded joints including adhesive layers and different welds may be imaged acoustically The assembly of numerous medical products uses acoustic microscopes to investigate internal bonds and features For example a polymer film may be imaged to examine its bond to a multi channel plastic plate used in blood analysis SAM can provide data on the elasticity of cells and both hard and soft tissues which can give useful information on the physical forces holding structures in a particular shape and the mechanics of structures such as the cytoskeleton 3 4 These studies are particularly valuable in investigating processes such as cell motility 5 6 Another promising direction was initiated by different groups in the world to design and build portable hand held SAM for subsurface 3D imaging and diagnostics of soft and hard tissues 20 23 and this direction currently is successfully developing with the goal to implement those methods into the clinical and cosmetology practice Also during last decade was expressed an interest to apply acoustic microscopy methods for 3D non invasive inspection of the paint layers of painted art and other art and culture heritage objects 24 25 See also EditAcoustic interferometer Scanning near field ultrasound holography Ultrasound biomicroscopy Capacitive micromachined ultrasonic transducerReferences Edit nbsp Wikimedia Commons has media related to Scanning acoustic microscopy S Sokolov USSR Patent no 49 31 August 1936 British Patent no 477 139 1937 and U S Patent 2 164 125 1939 Dunn Floyd 1959 Ultrasonic Absorption Microscope The Journal of the Acoustical Society of America 31 5 632 633 Bibcode 1959ASAJ 31 632D doi 10 1121 1 1907767 a b Korpel A 1966 Visualization of the Cross Section of a Sound Beam by Bragg Diffraction of Light Applied Physics Letters 9 12 425 427 Bibcode 1966ApPhL 9 425K doi 10 1063 1 1754639 a b R Pohlman Material illumination by means of acoustic optical imagery Z Phys 1133 697 1939 See also Z Angew Phys vol 1 p 181 1948 a b J A Cunningham and C F Quate Acoustic interference in solids and holographic imaging in Acoustical Holography vol 4 G Wade Ed New York Plenum 1972 pp 667 685 a b Kessler L W 1970 Ultrasonic Stimulation of Optical Scattering in Nematic Liquid Crystals Applied Physics Letters 17 10 440 441 Bibcode 1970ApPhL 17 440K doi 10 1063 1 1653262 Lemons R A 1974 Acoustic microscope scanning version Applied Physics Letters 24 4 163 165 Bibcode 1974ApPhL 24 163L doi 10 1063 1 1655136 A Korpel and L W Kessler Comparison of methods of acoustic microscopy in Acoustical Holography vol 3 by A F Metherell Ed New York Plenum 1971 pp 23 43 Kessler L W Yuhas D E 1979 Acoustic microscopy 1979 Proceedings of the IEEE 67 4 526 Bibcode 1979IEEEP 67 526K doi 10 1109 PROC 1979 11281 S2CID 30304663 R Gr Maev Principles and Future of Acoustic Microscopy Proceedings of the Joint Soviet West Germany International Symposium on Microscope Photometry and Acoustic Microscopy in Science Moscow Russia 1 12 1985 Nikoonahad Mehrdad 1984 Recent Advances in High Resolution Acoustic Microscopy Contemporary Physics 25 2 129 158 Bibcode 1984ConPh 25 129N doi 10 1080 00107518408230325 Nikoonahad Mehrdad 1984 Reflection Acoustic Microscopy for Industrial NDE Research Techniques in Nondestructive Testing Edited by R S Sharppe 7 217 257 ISBN 0 12 639057 6 M Hoppe R Gr Maev Editors and Co authors Microscope Photometry and Acoustic Microscopy in Science Proceedings of the FRG USSR Symposium Moscow 231 pages 1985 Hoppe M and Bereiter Hahn J Applications of scanning acoustic microscopy survey and new aspects IEEE Trans Ultrason Ferroelectr Freq Control 32 2 289 301 1985 Acoustic Imaging and Acoustic Microscopes From Sonoscan Inc Sonoscan 11 July 2008 Briggs Andrew 1992 Advanced in Acoustic Microscopy Oxford University Press ISBN 978 1 4615 1873 0 Maev Roman 2008 Acoustic Microscopy Fundamentals and Applications Wiley VCH ISBN 978 3 527 40744 6 Maev Roman 2013 Advances in Acoustic Microscopy and High Resolution Ultrasonic Imaging From Principles to New Applications Wiley VCH ISBN 978 3 527 41056 9 Kessler L W Acoustic Microscopy Metals Handbook Vol 17 Nondestructive Evaluation and Quality Control ASM International 1989 pp 465 482 a b R Gr Maev Editor and Co author Advances in Acoustic Microscopy and High Resolution Ultrasonic Imaging From Principles to New Applications Monograph 14 Chapters 400 pages Wiley amp Son VCH April 2013 Tulkoff Cheryl Counterfeit Protection amp Detection Strategies When to Do It How to Do It PDF DfR Solutions O Toole Kevin Esser Bob Binfield Seth Hillman Craig Beers Joe 2009 Pb Free Reflow PCB Degradation and the Influence of Moisture Absorption PDF APEX Vogt M and Ermert H Limited angle spatial compounding imaging of skin with high frequency ultrasound IEEE Trans Ultrason Ferroelectr Freq Control 55 9 1975 1983 2011 Georgios Karagiannis Dimitrios Alexiadis Argirios Damtsios Georgios Sergiadis and Christos Salpistis 3D non destructive sampling of art objects IEEE instrumentation and measurements vol 60 issue 9 Pages 1 28 September 2011 D Thickett C S Cheung H Liang J Twydle R Gr Maev D Gavrilov Using non invasive non destructive techniques to monitor cultural heritage objects Insight Magazine 59 5 230 234 2017 Retrieved from https en wikipedia org w index php title Acoustic microscopy amp oldid 1139423906, wikipedia, wiki, book, books, library,

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