Low voltage scanning electron microscopy (SEM) metrology and inspection are performed by immersing the sample in an electric field; under this condition, when a scanning electron beam images a sample containing insulating features (like oxides and resist), a surface global charge builds up to offset the applied field and a transverse local field will form as a result of the scanning beam. The surface global charge is responsible for the voltage contrast and imaging properties, while local fields degrade image resolution. In this article we describe a simulation approach able to explain the imaging properties of charged surfaces and how resolution is affected by local fields. Using electron ray tracing in the column, the simulation follows both the emitted and primary electron trajectories outside the sample. In addition, Monte Carlo scattering simulation calculates the electron trajectory and charge deposition inside the sample. The resulting charge density is used to calculate the field inside and outsid...
[1]
E. Fabrizio,et al.
Secondary electron line scans over high resolution resist images: Theoretical and experimental investigation of induced local electrical field effects
,
1994
.
[2]
Arnold,et al.
Acoustic-phonon runaway and impact ionization by hot electrons in silicon dioxide.
,
1992,
Physical review. B, Condensed matter.
[3]
H. Seiler,et al.
Secondary electron emission in the scanning electron microscope
,
1983
.
[4]
R. Pease,et al.
Low Energy Electron/Atom Elastic Scattering Cross Sections from 0.1-30 keV
,
2006
.
[5]
Gian Francesco Lorusso,et al.
Simulations of scanning electron microscopy imaging and charging of insulating structures
,
2006
.
[6]
Gian Francesco Lorusso,et al.
Simulations of SEM imaging and charging
,
2004
.