Thin Film Deposition and PVD PDF

Summary

This document provides an overview of thin film deposition techniques, including PVD, CVD, evaporation, sputtering, and electron beam evaporation. It discusses various deposition methods and their applications in areas like IC fabrication and other technological fields. The document highlights the significance of controlling film properties and cost-effectiveness in material science applications.

Full Transcript

Thin Film Deposition
Any technologies available to deposit thin layers of material onto a
substrate of different material.
Such technologies are used to achieve the desired properties of the thin
film without affecting the bulk properties of the substrate.
Thin film deposition belongs to the larger area of surface coating
technologies & phenomena as it alters & improves the properties of the
substrate material by treating the surface only for the deposited film
properties & highly cost effectiveness.
For example, a steel cutter but can be hardened by diamond coating or a
steel drill bit hardened by titanium coating.
The applications can only be limited by material science or our
imagination.
 Thin Film Deposition
With the help of photolithography & etching, many layers can be
deposited & patterned on top of each other in IC fabrication.
 Thin Film Deposition Techniques
Categorized into Physical Vapour Deposition (PVD) & Chemical Vapour
Deposition (CVD).

PVD Techniques:
Evaporation
Sputtering

CVD Techniques:
Atmospheric Pressure CVD (APCVD)
Low Pressure CVD (LPCVD)
Plasma Enhanced CVD (PECVD)
Electron Beam Evaporation
 Evaporation
Vacuum process.
Involves heating of materials
to the point of vaporization.
The evaporated material
vaporizes, transported by
line of sight to & solidifies on
the substrate.
It follows the 2R (2x Radius)
& 1R circumference for
uniformity & perpendicular
deposition respectively (to be
covered in Advanced Wafer Fabrication
Technology).
 Electron-Beam Evaporation
Tungsten heater or high-intensity electron
beam (EB Gun) is used to heat up the
material.
EB is preferred method for IC as there is
no contamination from the tungsten
filament. Tungsten heating evaporation
only good for metal & non-metals of low
melting point & use in car lights &
decorative coatings
Only EB can be used to evaporate metal
or dielectrics with high melting point.
 Sputtering
Vacuum process.
Plasma (ionised gas) of argon by
Magnetron (Combine Electric &
Magnetic Field).
Argon ions bombard the Target
(material to deposit) to knock out &
dislodge the atoms at the surface.
Ejected atoms deposit on the
substrate.
Conductive materials use DC or RF
power source.
Non conductive materials can only
use RF power source
Ion Beam Sputtering to be covered in Advanced Wafer Fabrication Technology
 Sputtering
Depending on the configuration for differing advantages & disadvantages
based on placement of the Target & Substrate:
Down Sputtering
Up Sputtering
Side Sputtering
 EB Evaporation versus Sputtering
EB Evaporation
Uniformity only with planetary design (to be covered in Advanced Wafer Fabrication Technology).
Moderate film density, stress & adhesion.
High deposition rate for metal & dielectrics
Good directionality (so can do lift off technique)
High material utilization
Uses: laser optics, solar panels, optical coatings & lift off technique for MEMS
(to be covered in Advanced Wafer Fabrication Technology)

Sputtering
Excellent uniformity without need for planetary design
Good film density, stress & adhesion
High deposition rate for metals only
Low directionality (so cannot do lift off technique)
High system cost & complexity
Uses: media & DLC in HDD, specific optical & electrical properties