Confocal Microscopy of Electronic Devices James Saczuk Consumer Optical Electronics EE594 02/22/2000
Introduction! Review of confocal principles! Why is CM used to examine electronics?! Several methods of CM are used, what are they?! What kind of data is gathered and what analysis can be performed on it?! What is new in the field of CM?! Conclusions
Confocal Microscopy Basics! CM is used to produce high resolution, three dimensional images of specimens of various thickness.! How does it work, what resolution can we achieve? More
Confocal Microscopy Optics Patent Diagram Minsky (US Patent 03013467)
Design Rules for Target Resolution! Confocal lateral resolution is related to the lateral resolution of the objective lens, which is a function of a NA, the confocal pinhole size and the wavelength of the projected light by the equation:! As the pinhole size approaches?, the resolution improves by a factor of?2.
Why use C.M. to Characterize Electronics?! Non-intrusive, thus non-destructive.! Provide a method to correlate electrical and tomographical data.! Viewing of switching events at the materials level.! Establish fault conditions with great precision for failure analysis.
Methods of Confocal Microscopy! LASER Scanning! Fluorescence Mapping! Single and Multi-Photon Optical Beam Induced Current Mapping! Near Field OBIC Imaging! Future Technologies
LASER Scanning Confocal Microscopy! LASER sources: Ar+ 488/514nm Solid State 523nm HeNe 633nm! Source is selected based on the specimen s properties to be examined.! Long pass filter in detector used to protect operator.
LASER Scanning C.M. Optical Schematic
LASER Scanning C.M. System Diagram
CM Scanning versus Wide Field Microscopy
Simplified Scan of 2D Specimen with S.M.
Data from 3D S.M. Compiled for Viewing
LSCM Image of LEPSi Wafer 200x200µm field of view Imaged at 488nm, emission above 550nm
Fluorescence Mapping! Light source is selected to support fluorescence of the material being observed, and/or the fluorophore added to the sample.! The use of ultrafast lasers, optical parametric oscillators and optical parametric amplifiers provide for fluorescence imaging without the addition of dyes, stains or other fluorophores.! Typically a mode locked Ti:Sapphire LASER is used at IR wavelengths.
Fluorescence Process Photons excite the electrons of a fluorophore to a higher energy level. As these electrons descend to a low level they emit photons of a shorter wavelength than the excitation Emission spectra and excitation spectra for common fluorescence
Fluorescence Mapping Analysis! Fluorophore Emission Table
LSCM Fluorescence Image of LEPSi Wafer Light-Emitting Porous Silicon wafer excited at 488 nm, emission above 550 nm 7.5x7.5mm field of view
Optical Beam Induced Current! Uses apparatus similar to conventional LSCM! 1, 2 and 3 photon OBIC! LASER sources are 633 and 1152nm HeNe! New techniques use 120fs pulse, 80MHz repetition rate, tunable, mode locked Ti:Sapphire lasers (Spectra-Physics, Opal)! Imaging through the substrate of electronic devices allows examination for failure analysis without possible damage from decapsulation.
Optical Beam Induced Current Apparatus
Optical Beam Induced Current Capabilities! Very low power, 1-10mW @ the focal point! Excellent response in highly doped semiconductors where one photon absorption occurs below the bandgap of Si due to excess charge carriers.! Long dwell time of the sample image, ~10µS, compared to ~1nS for others.! Out of focus background current eliminated as compared to the one photon method
Optical Beam Induced Current Samples
Optical Beam Induced Current Samples
Optical Beam Induced Current Samples
Optical Beam Induced Current Samples
Optical Beam Induced Current Samples Vcc = 5 VDC Vcc = 0 VDC
Optical Beam Induced Current Samples
Near Field OBIC Imaging! Use a near field optical probe to sense and excite the specimen! Tapered optical fibers are used as the probes! Resolution can approach 10nm! A tunable Ar+ pumped Ti:Sapphire LASER is used to provide optical excitation through the fiber! A scanning microscopy method that has evolved from LSCM OBIC
Near Field OBIC Imaging
Near Field OBIC Imaging
The Near Future...! Confocal imaging of transparent objects! Second harmonic generation limited to crystals & structured media! Third harmonic generation all materials generate 3rd harmonic light in the beam waste when an excitation source (LASER) is tightly focused at a point in the material requires ultrafast pulses with? >1µm 3rd harmonic detection at 400nm for 1.2µm excitation
Third Harmonic Generation THG in a homogenous sample shows the beam waste summing to zero because the 3rd harmonics on each side of the beam waste are exactly out of phase Out of phase beam waste occurs near the interface between materials with different 3rd order susceptibilities or indices of refraction. The interference patterns can be mapped to produce a stereoscopic image of the specimen.
Conclusions! Confocal microscopy applications are developing steadily with the availability of cheaper, more user friendly, ultrafast laser systems.! The technology and expertise to use these systems for electronic component characterization and failure analysis will be in demand as electronics continue to proliferate in the consumer market.
References! http://glu.ls.utsa.edu/clsm/chpt2.html dzf! http://www.zeiss.com/micro/products/! http://www.science.uwaterloo.ca/physics/research/confocal/scapp.html#sc! http://photon.bu.edu/selim/papers/jqe-95/node1.html! http://www.cs.ubc.ca/spider/ladic/overview.html! http://www.chips.ibm.com:80/services/asg/capabilities/asweb07.html#obic