Yong-Il Ko1, Min-Jae Kim1, Dong-Yun Lee1, Jungtae Nam1, A-Rang Jang2,3, Jeong-O Lee3, Keun-Soo Kim1. 1. Department of Physics and Graphene Research Institute, Sejong University, Seoul 05006, Korea. 2. Department of Electrical Engineering, Semyung University, Jecheon 27136, Korea. 3. Advanced Materials Division, Korea Research Institute of Chemical Technology (KRICT), Gajeong-ro 141, Daejeon 34114, Korea.
Abstract
Carbon nanomaterials have attracted significant research attention as core materials in various industrial sectors owing to their excellent physicochemical properties. However, because the preparation of carbon materials is generally accompanied by high-temperature heat treatment, it has disadvantages in terms of cost and process. In this study, highly sensitive carbon nanomaterials were synthesized using a local laser scribing method from a copper-embedded polyacrylonitrile (CuPAN) composite film with a short processing time and low cost. The spin-coated CuPAN was converted into a carbonization precursor through stabilization and then patterned into a carbon nanomaterial of the desired shape using a pulsed laser. In particular, the stabilization process was essential in laser-induced carbonization, and the addition of copper promoted this effect as a catalyst. The synthesized material had a porous 3D structure that was easy to detect gas, and the resistance responses were detected as -2.41 and +0.97% by exposure to NO2 and NH3, respectively. In addition, the fabricated gas sensor consists of carbon materials and quartz with excellent thermal stability; therefore, it is expected to operate as a gas sensor even in extreme environments.
Carbon nanomaterials have attracted significant research attention as core materials in various industrial sectors owing to their excellent physicochen class="Chemical">mical properties. However, because the preparation of carbon materials is generally accompanied by high-temperature heat treatment, it has disadvantages in terms of cost and process. In this study, highly sensitive carbon nanomaterials were synthesized using a local laser scribing method from a copper-embedded polyacrylonitrile (CuPAN) composite film with a short processing time and low cost. The spin-coated CuPAN was converted into a carbonization precursor through stabilization and then patterned into a carbon nanomaterial of the desired shape using a pulsed laser. In particular, the stabilization process was essential in laser-induced carbonization, and the addition of copper promoted this effect as a catalyst. The synthesized material had a porous 3D structure that was easy to detect gas, and the resistance responses were detected as -2.41 and +0.97% by exposure to NO2 and NH3, respectively. In addition, the fabricated gas sensor consists of carbon materials and quartz with excellent thermal stability; therefore, it is expected to operate as a gas sensor even in extreme environments.
Authors: Suzi Deng; Verawati Tjoa; Hai Ming Fan; Hui Ru Tan; Dean C Sayle; Malini Olivo; Subodh Mhaisalkar; Jun Wei; Chorng Haur Sow Journal: J Am Chem Soc Date: 2012-02-27 Impact factor: 15.419
Authors: Keun Soo Kim; Yue Zhao; Houk Jang; Sang Yoon Lee; Jong Min Kim; Kwang S Kim; Jong-Hyun Ahn; Philip Kim; Jae-Young Choi; Byung Hee Hong Journal: Nature Date: 2009-01-14 Impact factor: 49.962
Authors: Piran R Kidambi; Bernhard C Bayer; Raoul Blume; Zhu-Jun Wang; Carsten Baehtz; Robert S Weatherup; Marc-Georg Willinger; Robert Schloegl; Stephan Hofmann Journal: Nano Lett Date: 2013-09-24 Impact factor: 11.189