Abstract
In this work, we studied the electro-optical properties of high-aligned carbon nanotubes deposited at room temperature. For this, we used the High Density Plasma Chemical Vapor Deposition system. This system uses a new concept of plasma generation: a planar coil is coupled to an RF system for plasma generation. This was used together with an electrostatic shield, for plasma densification, thereby obtaining high-density plasmas. The carbon nanotubes were deposited using pure methane plasmas. Three methods were used for the surface modification of the sample: reference substrate (silicon wafer only submitted to a chemical cleaning), silicon wafer with surface roughness generated by plasma etching, silicon wafer with a thin iron film and silicon wafer with diamond nano powder used as precursor materials. For each kind of silicon wafer surface, the carbon nanotubes were deposited with two different deposition times (two and three hours). The carbon nanotubes structural characteristics were analyzed by Atomic Force Microscope and Scanning Electronic Microscope. The carbon nanotubes electrical characteristics were observed by Raman Spectroscopy and the carbon nanotubes electro-optical properties were analyzed by current vs voltage electrical measurements and photo-luminescence spectroscopy measurements. The photoelectric effect in the carbon nanotubes were determined by photo-induced current measurements. In this work, we obtained carbon nanotubes with semiconductor properties and carbon nanotubes with metallic properties. The electro-optical effects depend strongly on the substrate preparation and the deposition parameters of the carbon nanotubes. The carbon nanotubes are high aligned and show singular properties that can be used for many applications.
Highlights
Carbon nanotubes (CNTs) were discovered in 1991
The CNTs deposited on silicon wafers with diamond powder, on etched silicon wafers by plasma and on silicon wafers only submitted to a chemical cleaning, showed semiconducting features
Using Raman spectroscopy, Atomic Force Microscope (AFM), SEM, photoluminescence measurements, optical absorption measurements, I vs V measurements, and photoinduced current measurements, it was possible to prove parameters used in the process influence the structural and electro-optical proprerties of the CNTs obtained in this work
Summary
Carbon nanotubes (CNTs) were discovered in 1991. Remarkable progress has been made in the ensuing 14 years, including the discovery of the two basic types of nanotube (single-wall and multiwall). The CNTs exhibit excellent properties for many applications, including: electrical, electro-optical, optical, optoelectronic, mechanical, electromechanical, magnetic, electromagnetic, chemical, electrochemical, thermal and thermoelectric properties [2]. Carbon nanotubes are a unique and novel material with many interesting properties in the electronic, mechanical and optical domains. Their incredible strength (a consequence of the famously strong carbon bond in the tubular structure) poses further advantages in nanomechanic applications. They exhibit photoluminescence, electroluminescence, photoconductivity, and optical nonlinearity, as well as strong and interesting excitonic effects [3]
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