This dissertation reports on the synthesis of vertically aligned carbon nanotube carpets/carbon nanocoils, the measurement of their electro and electro-thermal properties, and some of their electro-thermal applications. Vertically aligned multi-walled carbon nanotube (VACNT) carpets have been synthesized on metal thin films and isolating substrates without the use of a pre-deposited catalyst. We used ferrocene as precursor powder catalyst and acetylene as a carbon source to grow VACNT carpets using three-temperature-zone chemical vapor deposition (TTZ-CVD). Tuning the carrier gas Ar flow rate and the sublimation time of ferocene in the TTZ-CVD extended the lifetime of the catalyst, increasing the efficiency of growth. By controlling the growth parameters, the growth of VACNT carpets on selective substrate can be controlled. Radial growth of carbon nanocoils (R-CNCs) on stainless steel (SS) wire has been achieved using thermal chemical vapor deposition from acetylene. A solution of tin acetate in ethanol with molarities of 0.01-0.2 M was coated on SS wire and oxidized as an active catalyst in air at 600-1000ºC. It was found that SS wire oxidized at 900ºC for 30 min with a tin solution of 0.1M exhibited the highest catalytic activity. Growing R-CNCs on metal wire provides excellent electrical contact, good alignment, and ease of handling and manipulation. VACNT carpets have been synthesized onto commercially available aluminum foil without the use of a pre-deposited catalyst. A high-sensitivity flexible strain sensor is used Al foils and VACNT carpets. The sensor allows change in contact resistance between the VACNT carpets to detect lengthwise strain. Experimental results show the sensor measures a strain as small as 0.0028%. The measured gauge factor of the sensor is 296. The demonstrated flexible sensors have high sensitivity and quality, which is beneficial in mass production. VACNT carpets were existed a high heating efficiency using the low power. A heating-resistance device of VACNT carpets has a heating efficiency higher than that of a heating device having a different shape and materials, which can be fabricated in a simple process. On the other hand, this work has a high heating efficiency using a low power. The heating-resistance can achieve over 400℃/W. Moreover, the heating device of VACNT carpets can be easily transferred onto any kind of substrate for wide applications, which is a material that converts electric energy to heat energy and transfers energy by radiating the heat to the objects. The heating device of VACNT carpets is widely used for various home appliances or general industrial fields.