Co-reporter:Qi Li;Qi Zeng;Lina Gao;Zaka Ullah;Hui Li;Yufen Guo;Weiwei Li;Ying Shi;Guanhong Tao
Journal of Materials Chemistry A 2017 vol. 5(Issue 1) pp:155-164
Publication Date(Web):2016/12/20
DOI:10.1039/C6TA07508H
Life runs on energy and natural resources of energy are being used quickly. Artificial photosynthesis, in which sunlight is used to produce valuable chemicals from abundant natural resources, is considered as one of the auspicious ways to meet the current energy requirements. Here we report a 5,10,15,20-tetrakis(4-aminophenyl)porphyrin/graphene (TkisAPP/G) based photocatalyst with a significant and sensible design and structure for the production of formic acid from CO2. The urchin-like TkisAPP/G microspheres show remarkable enhancement in sunlight absorption and improve the light-harvesting efficiency. An effective approach has been adopted for electronic coupling to develop covalent bonding between porphyrin and graphene which increases the rate of the photoinduced charge transfer. For the fabricated photocatalyst, a 0.5% solar-to-formic acid conversion efficiency has been attained which is greater than that of natural photosynthesis.
Co-reporter:Qi Li, Yufen Guo, Weiwei Li, Shengqiang Qiu, Chao Zhu, Xiangfei Wei, Mingliang Chen, Chaojun Liu, Shutian Liao, Youpin Gong, Ananta Kumar Mishra, and Liwei Liu
Chemistry of Materials 2014 Volume 26(Issue 15) pp:4459
Publication Date(Web):July 22, 2014
DOI:10.1021/cm501473t
The exceptional thermal conductivity of graphene is expected to endow polymer composites with ultrahigh thermal conductivities, which can be even similar to those of some metals such as stainless steel and aluminum alloy. The thermal conductivities of composites prepared by dispersing multilayer graphene (MLG) in epoxy matrix increase only by an order of magnitude over the pure epoxy. However, the improvement has been limited since the large interfacial thermal resistance exists between graphene and the surrounding epoxy. We have reported an extraordinary increase in thermal conductivity of the MLG/epoxy composites through the fabrication of the vertically aligned and densely packed MLG in the epoxy matrix. The ultrahigh thermal conductivity of 33.54 W/(m K) has been achieved in the aligned MLG/epoxy composite (AG/E). The thermal conductivity of AG/E exhibits a positive temperature response related to the aligned structure while increasing the temperature from 40 °C to 90 °C.
Co-reporter:Youpin Gong;Xuemin Zhang;Guangtong Liu;Liqiong Wu;Xiumei Geng;Mingsheng Long;Xiaohui Cao;Yufen Guo;Weiwei Li;Jianbao Xu;Mengtao Sun;Li Lu
Advanced Functional Materials 2012 Volume 22( Issue 15) pp:3153-3159
Publication Date(Web):
DOI:10.1002/adfm.201200388
Abstract
Chemical vapor deposition (CVD) provides a synthesis route for large-area and high-quality graphene films. However, layer-controlled synthesis remains a great challenge on polycrystalline metallic films. Here, a facile and viable synthesis of layer-controlled and high-quality graphene films on wafer-scale Ni surface by the sequentially separated steps of gas carburization, hydrogen exposure, and segregation is developed. The layer numbers of graphene films with large domain sizes are controlled precisely at ambient pressure by modulating the simplified CVD process conditions and hydrogen exposure. The hydrogen exposure assisted with a Ni catalyst plays a critical role in promoting the preferential segregation through removing the carbon layers on the Ni surface and reducing carbon content in the Ni. Excellent electrical and transparent conductive performance, with a room-temperature mobility of ≈3000 cm2 V−1 s−1 and a sheet resistance as low as ≈100 Ω per square at ≈90% transmittance, of the twisted few-layer grapheme films grown on the Ni catalyst is demonstrated.
Co-reporter:Weiwei Li, Xiumei Geng, Yufen Guo, Jizan Rong, Youpin Gong, Liqiong Wu, Xuemin Zhang, Peng Li, Jianbao Xu, Guosheng Cheng, Mengtao Sun, and Liwei Liu
ACS Nano 2011 Volume 5(Issue 9) pp:6955
Publication Date(Web):August 11, 2011
DOI:10.1021/nn201433r
We develop graphene-based devices fabricated by alternating current dielectrophoresis (ac-DEP) for highly sensitive nitric oxide (NO) gas detection. The novel device comprises the sensitive channels of palladium-decorated reduced graphene oxide (Pd-RGO) and the electrodes covered with chemical vapor deposition (CVD)-grown graphene. The highly sensitive, recoverable, and reliable detection of NO gas ranging from 2 to 420 ppb with response time of several hundred seconds has been achieved at room temperature. The facile and scalable route for high performance suggests a promising application of graphene devices toward the human exhaled NO and environmental pollutant detections.Keywords: dielectrophoresis; graphene; highly sensitive; nitric oxide; reduced graphene oxide
Co-reporter:Qi Li, Qi Zeng, Lina Gao, Zaka Ullah, Hui Li, Yufen Guo, Weiwei Li, Ying Shi, Guanhong Tao and Liwei Liu
Journal of Materials Chemistry A 2017 - vol. 5(Issue 1) pp:NaN164-164
Publication Date(Web):2016/11/15
DOI:10.1039/C6TA07508H
Life runs on energy and natural resources of energy are being used quickly. Artificial photosynthesis, in which sunlight is used to produce valuable chemicals from abundant natural resources, is considered as one of the auspicious ways to meet the current energy requirements. Here we report a 5,10,15,20-tetrakis(4-aminophenyl)porphyrin/graphene (TkisAPP/G) based photocatalyst with a significant and sensible design and structure for the production of formic acid from CO2. The urchin-like TkisAPP/G microspheres show remarkable enhancement in sunlight absorption and improve the light-harvesting efficiency. An effective approach has been adopted for electronic coupling to develop covalent bonding between porphyrin and graphene which increases the rate of the photoinduced charge transfer. For the fabricated photocatalyst, a 0.5% solar-to-formic acid conversion efficiency has been attained which is greater than that of natural photosynthesis.
