The Experts below are selected from a list of 222 Experts worldwide ranked by ideXlab platform
Olivier Guillou - One of the best experts on this subject based on the ideXlab platform.
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Reversible Luminescence Modulation upon an Electric Field on a Full Solid-State Device Based on Lanthanide Dimers
ACS Applied Materials & Interfaces, 2016Co-Authors: Jie Shang, Liang Pan, Hongwei Tan, Bin Chen, Gang Liu, Gang Huang, Kevin Bernot, Olivier GuillouAbstract:Switching luminescence of lanthanide-based molecules through an external electric field is considered as a promising approach toward novel functional molecule-based Devices. Classic routes use casted films and liquid electrolyte as media for redox reactions. Such protocol, even if efficient, is relatively hard to turn into an effective solid-State Device. In this work, we explicitly synthesize lanthanide-based dimers whose luminescent behavior is affected by the presence of Cu2+ ions. Excellent evaporability of the dimers and utilization of Cu2+-based solid-State electrolyte makes it possible to reproduce solution behavior at the solid State. Reversible modulation of Cu2+ ions transport can be achieved by an electric field in a solid-State Device, where lanthanide-related luminescence is driven by an electric field. These findings provide a proof-of-concept alternative approach for electrically driven modulation of solid-State luminescence and show promising potential for information storage media in the ...
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Reversible Luminescence Modulation upon an Electric Field on a Full Solid-State Device Based on Lanthanide Dimers
ACS Applied Materials & Interfaces, 2016Co-Authors: Xiaohui Yi, Jie Shang, Liang Pan, Hongwei Tan, Bin Chen, Gang Liu, Gang Huang, Kevin Bernot, Olivier Guillou, Run-wei LiAbstract:Switching luminescence of lanthanide-based molecules through an external electric field is considered as a promising approach toward novel functional molecule-based Devices. Classic routes use casted films and liquid electrolyte as media for redox reactions. Such protocol, even if efficient, is relatively hard to turn into an effective solid-State Device. In this work, we explicitly synthesize lanthanide-based dimers whose luminescent behavior is affected by the presence of Cu(2+) ions. Excellent evaporability of the dimers and utilization of Cu(2+)-based solid-State electrolyte makes it possible to reproduce solution behavior at the solid State. Reversible modulation of Cu(2+) ions transport can be achieved by an electric field in a solid-State Device, where lanthanide-related luminescence is driven by an electric field. These findings provide a proof-of-concept alternative approach for electrically driven modulation of solid-State luminescence and show promising potential for information storage media in the future
Jie Shang - One of the best experts on this subject based on the ideXlab platform.
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Reversible Luminescence Modulation upon an Electric Field on a Full Solid-State Device Based on Lanthanide Dimers
ACS Applied Materials & Interfaces, 2016Co-Authors: Jie Shang, Liang Pan, Hongwei Tan, Bin Chen, Gang Liu, Gang Huang, Kevin Bernot, Olivier GuillouAbstract:Switching luminescence of lanthanide-based molecules through an external electric field is considered as a promising approach toward novel functional molecule-based Devices. Classic routes use casted films and liquid electrolyte as media for redox reactions. Such protocol, even if efficient, is relatively hard to turn into an effective solid-State Device. In this work, we explicitly synthesize lanthanide-based dimers whose luminescent behavior is affected by the presence of Cu2+ ions. Excellent evaporability of the dimers and utilization of Cu2+-based solid-State electrolyte makes it possible to reproduce solution behavior at the solid State. Reversible modulation of Cu2+ ions transport can be achieved by an electric field in a solid-State Device, where lanthanide-related luminescence is driven by an electric field. These findings provide a proof-of-concept alternative approach for electrically driven modulation of solid-State luminescence and show promising potential for information storage media in the ...
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Reversible Luminescence Modulation upon an Electric Field on a Full Solid-State Device Based on Lanthanide Dimers
ACS Applied Materials & Interfaces, 2016Co-Authors: Xiaohui Yi, Jie Shang, Liang Pan, Hongwei Tan, Bin Chen, Gang Liu, Gang Huang, Kevin Bernot, Olivier Guillou, Run-wei LiAbstract:Switching luminescence of lanthanide-based molecules through an external electric field is considered as a promising approach toward novel functional molecule-based Devices. Classic routes use casted films and liquid electrolyte as media for redox reactions. Such protocol, even if efficient, is relatively hard to turn into an effective solid-State Device. In this work, we explicitly synthesize lanthanide-based dimers whose luminescent behavior is affected by the presence of Cu(2+) ions. Excellent evaporability of the dimers and utilization of Cu(2+)-based solid-State electrolyte makes it possible to reproduce solution behavior at the solid State. Reversible modulation of Cu(2+) ions transport can be achieved by an electric field in a solid-State Device, where lanthanide-related luminescence is driven by an electric field. These findings provide a proof-of-concept alternative approach for electrically driven modulation of solid-State luminescence and show promising potential for information storage media in the future
Lei Jiang - One of the best experts on this subject based on the ideXlab platform.
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solid State dye sensitized photovoltaic Device with newly designed small organic molecule as hole conductor
Chemical Physics Letters, 2007Co-Authors: Yong Zhao, Xianliang Sheng, Qingguo He, Jin Zhai, Wei Chen, Lei JiangAbstract:Abstract A newly and interestingly small organic molecule, (R)-2,2′-dimethoxyl-3,3′-di(phenyl-4-yl-diphenyl-amine)-[1,1′]-binaphthyl, was introduced into solid-State electrolyte to assemble dye-sensitized photoelectrical cell. With optimized molecular structure and composite porous TiO 2 electrode, the solid-State Device without any additives in electrolyte converted light to electric efficiency with a 0.07%. Under the assistance of some functional small-molecules in the electrolyte, solid-State Devices showed an attractive conversion efficiency of 0.55%. In addition, the positive effects of functional additives on the photoelectrical performance, such as inhibiting interface charge recombination, improving hole-transporting properties and penetration of solid-State electrolyte, were discussed experimentally and theoretically in detail.
Run-wei Li - One of the best experts on this subject based on the ideXlab platform.
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Reversible Luminescence Modulation upon an Electric Field on a Full Solid-State Device Based on Lanthanide Dimers
ACS Applied Materials & Interfaces, 2016Co-Authors: Xiaohui Yi, Jie Shang, Liang Pan, Hongwei Tan, Bin Chen, Gang Liu, Gang Huang, Kevin Bernot, Olivier Guillou, Run-wei LiAbstract:Switching luminescence of lanthanide-based molecules through an external electric field is considered as a promising approach toward novel functional molecule-based Devices. Classic routes use casted films and liquid electrolyte as media for redox reactions. Such protocol, even if efficient, is relatively hard to turn into an effective solid-State Device. In this work, we explicitly synthesize lanthanide-based dimers whose luminescent behavior is affected by the presence of Cu(2+) ions. Excellent evaporability of the dimers and utilization of Cu(2+)-based solid-State electrolyte makes it possible to reproduce solution behavior at the solid State. Reversible modulation of Cu(2+) ions transport can be achieved by an electric field in a solid-State Device, where lanthanide-related luminescence is driven by an electric field. These findings provide a proof-of-concept alternative approach for electrically driven modulation of solid-State luminescence and show promising potential for information storage media in the future
Bin Chen - One of the best experts on this subject based on the ideXlab platform.
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Reversible Luminescence Modulation upon an Electric Field on a Full Solid-State Device Based on Lanthanide Dimers
ACS Applied Materials & Interfaces, 2016Co-Authors: Jie Shang, Liang Pan, Hongwei Tan, Bin Chen, Gang Liu, Gang Huang, Kevin Bernot, Olivier GuillouAbstract:Switching luminescence of lanthanide-based molecules through an external electric field is considered as a promising approach toward novel functional molecule-based Devices. Classic routes use casted films and liquid electrolyte as media for redox reactions. Such protocol, even if efficient, is relatively hard to turn into an effective solid-State Device. In this work, we explicitly synthesize lanthanide-based dimers whose luminescent behavior is affected by the presence of Cu2+ ions. Excellent evaporability of the dimers and utilization of Cu2+-based solid-State electrolyte makes it possible to reproduce solution behavior at the solid State. Reversible modulation of Cu2+ ions transport can be achieved by an electric field in a solid-State Device, where lanthanide-related luminescence is driven by an electric field. These findings provide a proof-of-concept alternative approach for electrically driven modulation of solid-State luminescence and show promising potential for information storage media in the ...
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Reversible Luminescence Modulation upon an Electric Field on a Full Solid-State Device Based on Lanthanide Dimers
ACS Applied Materials & Interfaces, 2016Co-Authors: Xiaohui Yi, Jie Shang, Liang Pan, Hongwei Tan, Bin Chen, Gang Liu, Gang Huang, Kevin Bernot, Olivier Guillou, Run-wei LiAbstract:Switching luminescence of lanthanide-based molecules through an external electric field is considered as a promising approach toward novel functional molecule-based Devices. Classic routes use casted films and liquid electrolyte as media for redox reactions. Such protocol, even if efficient, is relatively hard to turn into an effective solid-State Device. In this work, we explicitly synthesize lanthanide-based dimers whose luminescent behavior is affected by the presence of Cu(2+) ions. Excellent evaporability of the dimers and utilization of Cu(2+)-based solid-State electrolyte makes it possible to reproduce solution behavior at the solid State. Reversible modulation of Cu(2+) ions transport can be achieved by an electric field in a solid-State Device, where lanthanide-related luminescence is driven by an electric field. These findings provide a proof-of-concept alternative approach for electrically driven modulation of solid-State luminescence and show promising potential for information storage media in the future
