Development of Contact Materials for Semiconductor Devices. Significant Effects of Electrode Materials on Very Small Si-MOSFETs' Performance.

AbstractThe preparation of ferroelectric and high-dielectric perovskite materials, which is performed at high temperatures in oxidizing environments, imposes strong limitations on the choice of suitable electrode materials which can be used for integration of these materials with semiconductor devices. Because of the complex compositions of the perovskites and of some of the electrode materials the two can interact and result in the deterioration of the structures. The electrode materials have, therefore, to be used often in combination with suitable barriers which block diffusion of the elements of the perovskite and of the Si device and prevent interactions between the components. These requirements can result in complex, multilayered electrode/barrier structures that can affect the crystallization of the perovskite material and its electrical properties as well as the perovskite properties during subsequent processing steps (e.g. in forming gas anneals). The present paper will review the different electrode/barrier structures that have been proposed for integration of ferroelectric thin films with semiconductor devices and discuss their effects on the properties of ferroelectric and high-dielectric materials.

Download Full-text

Development of Electrode Materials for Semiconductor Devices

Materials Science Forum ◽

10.4028/www.scientific.net/msf.475-479.1705 ◽

2005 ◽

Vol 475-479 ◽

pp. 1705-1714

Author(s):

Masanori Murakami ◽

Yasuo Koide ◽

Miki Moriyama ◽

Susumu Tsukimoto

Keyword(s):

Ohmic Contact ◽

High Speed ◽

Electrode Materials ◽

Chemical Vapor ◽

Crystal Defects ◽

Atomic Scale ◽

Organic Chemical ◽

Contact Materials ◽

Low Resistance ◽

Metal Organic

Recent strong demands for optoelectronic communication and portable telephones have encouraged engineers to develop optoelectronic devices, microwave devices, and high-speed devices using heterostructural compound semiconductors. Although the compound crystal growth techniques had reached at a level to control the compositional stoichiometry and crystal defects on a nearly atomic scale by the advanced techniques such as molecular beam epitaxy and metal organic chemical vapor deposition techniques, development of ohmic contact materials (which play a key role to inject external electric current from the metals to the semiconductors) was still on a trial-and-error basis. Our research efforts have been focused to develop, low resistance, refractory ohmic contact materials using the deposition and annealing techniques for n-GaAs, p-ZnSe, InP, p-SiC p-CdTe etc. It was found the growth of homo- or hetero–epitaxial intermediate semiconductor layers (ISL) was essential for low resistance contact formation. The importance of hetero-structural ISL was given taking an example of n-type ohmic contact for GaAs.

Download Full-text