top of page

 



I. SCI papers:

1.  Ni3S2/carbon nanotube nanocomposite as electrode material forhydrogen evolution reaction in alkaline electrolyte and enzyme-freeglucose detection

Tsung-Wu Lin∗, Chia-Jui Liu, Chao-Shuan Dai, Applied Catalysis B: Environmental 154–155 (2014) 213–220

 

 

 

2. Hierarchically Structured Ni3S2/Carbon Nanotube Composites as High Performance Cathode Materials for Asymmetric Supercapacitors

Chao-Shuan Dai , Pei-Yi Chien , Jeng-Yu Lin ,Shu-Wei Chou , Wen-Kai Wu , Ping-Hsuan Li ,Kuan-Yi Wu , and Tsung-Wu Lin * ACS Appl. Mater. Interfaces, 2013, 5 (22), pp 12168–12174

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

3.   Dye-sensitized solar cells with high-performance polyaniline/multi-wall carbon nanotube counter electrodes electropolymerized by a pulse potentiostatic technique

Yaoming Xiao, Jeng-Yu Lin, Jihuai Wu, Sheng-Yen Tai, Gentian Yue, Tsung-Wu Lin Journal of Power Sources, In Press, 2013.





4.    Facile synthesis of MoS3/carbon nanotube nanocomposite with high catalytic activity toward hydrogen evolution reaction

Tsung-Wu Lin∗, Chia-Jui Liu, Jeng-Yu Lin
Applied Catalysis B: Environmental , 2013, 134–135, 75–82.


5.      Facile synthesis of MoS2/graphene nanocomposite with high catalytic activity toward triiodide reduction in dye-sensitized solar cells
Chia-Jui Liu,1 Sheng-Yen Tai,1 Shu-Wei Chou, Ya-Chu Yu, Kai-Di Chang, Shuei Wang, Forest Shih-Sen Chien, Jeng-Yu Lin* and Tsung-Wu Lin*

J. Mater. Chem., 2012, 22, 21057-21064
1. These authors contributed equally to this work

6.    Few-layer MoS2 nanosheets coated onto multi-walled carbon nanotubes as a low-cost and highly electrocatalytic counter electrode for dye-sensitized solar cells
Sheng-Yen Tai,1 Chia-Jui Liu,1 Shu-Wei Chou, Forest Shih-Sen Chien, Jeng-Yu Lin* and Tsung-Wu Lin*

J. Mater. Chem., 2012, 22, 24753-24759
1. These authors contributed equally to this work


7.  Synthesis of Large-Area MoS2 Atomic Layers with Chemical Vapor Deposition

Y. H. Lee,1 X. Q. Zhang,1 W. Zhang, M. T. Chang, C. T. Lin, K. D. Chang, Y. C. Yu, T. W. Wang, C. S. Chang, L. J. Li*, and T. W. Lin*,, 2012, Advanced Materials. 2012,24, 2320-2325 , 5-year IF= 11.306, ▲=0.


(1.    These authors contributed equally to this work.)

8.   “Converting Graphene Oxide Monolayers into Boron Carbonitride Nanosheets (BCN) by Substitutional Doping”

T. W. Lin,*1 C. Y. Su,1 X. Q. Zhang, W. Zhang, Y. .H. Lee, C. W. Chu, H. Y. Lin, M. T. Chang. F. R. Chen, and L. J. Li*,  2012, Small. 2012, 8, 1384-91. 5-year IF= 8.057, ▲=0.


(1.    These authors contributed equally to this work.)

Converting Graphene Oxide Monolayers into Boron Carbonitride Nanosheets
(BCN) by Substitutional Doping

9.     Growth Selectivity of Hexagonal-Boron Nitride Layers on Ni with Various Crystal Orientations”, 

Y. H. Lee*, K. K. Liu, A. Y. Lu, C. Y. Wu, C. T. Lin, W. Zhang, C.Y. Su, C. L. Hsu, T. W. Lin, K. H. Wei, Y. Shi, and L.J. Li*,  2012, RSC Advances., 2, 111- 115, ▲=0.

 


10.      Surfactin Structures at Interfaces and in Solution: The Effect of pH and Cations”,

H. H. Shen*, T. W. Lin, R. K. Thomas, D. J. F. Taylor, and J. Penfold,  2011, Journal of Physical Chemistry B, 115, 4427- 4435, 5-year IF= 4.425, ▲=2.

 


11.      Surface potential variations on a silicon nanowire transistor in biomolecular modification and detection”,

C. C. Tsai, P. L. Chiang , C. J. Sun, T. W. Lin, M. H. Tsai, Y. C. Chang, and Y. T. Chen*,  2011, Nanotechnology, 22, 135503-135511, 5-year IF=3.838, ▲=2.

 


12.     Synthesis of silica nanotubes through chlorosilanization of single wall carbon nanotubes”, 

T. W. Lin*, and H. H. Shen,  2010, Nanotechnology, 21, 365604-365608, 5-year IF=3.838, ▲=2.

 


13.       Label-free detection of DNA using novel organic based electrolyte-insulator-semiconductor”, 

T. W. Lin, D. Kekuda, and C.W. Chu*,  2010, Biosensors and Bioelectronics, 25, 2706-2710, 5-year IF= 5.397, ▲=3.

 


14.      Label-free detection of protein-protein interactions using a calmodulin-modified nanowire transistor”, 

T. W. Lin, P. J. Hsieh, C. L. Lin, Y. Y. Fang, J. X. Yang, C. C. Tsai, P. L. Chiang, C. Y. Pan*, and Y. T. Chen*, 2010, Proceedings of the National Academy of Sciences U. S. A., 107, 1047-1052, 5-year IF= 10.591, ▲=12.

 


15.      Label-free detection of serum uric acid using novel high-k Sm2TiO5 membrane-based electrolyte-insulator-semiconductor”,

M. H. Wu1, T. W. Lin1, M. D. Huang, H. Y. Wang, and T. M. Pan*,  2010, Sensors and Actuators, B: Chemical, 146, 342-348, 5-year IF= 3.340, ▲=2.

(1.    These authors contributed equally to this work.)

 


16.  Large-scale synthesis of n-type gallium nitride nanowires using NiI2-decorated carbon nanotubes as a reactant”,T. W. Lin, S. Y. Choi*, Y. H. Kim, and M. L. H. Green*,  2010, Carbon, 48, 2401-2408, 5-year IF= 5.728, ▲=1.

 


17. Polyethylene glycol grafting and attachment of encapsulated magnetic iron oxide silica nanoparticles onto chlorosilanized single-wall carbon nanotubes”, 

T. W. Lin, C. G. Salzmann, L. Shao, C. H. Yu, M. L. H. Green, and S. C. Tsang*,  2009, Carbon, 47, 1415-1420, 5-year IF= 5.728, ▲=12.

 


18.  A reversible surface functionalized nanowire transistor to study protein-protein interactions”,

S. P. Lin, C. Y. Pan, K. C. Tseng, M. C. Lin, C. D. Chen, C. C. Tsai, S. H. Yu, Y.-C. Sun, T. W. Lin, and Y.-T. Chen*,  2009, Nano Today, 4, 235-243, 5-year IF= 13.396, ▲=12.

 


19. A simple method for the containment and purification of filled open-ended single wall carbon nanotubes using C60 molecules”, 

L. Shao, T. W. Lin, G. Tobias*, and M. L. H. Green,  2008, Chemical Communications, 2164-2166, 5-year IF= 5.582, ▲=8.

 


20.   Electrical detection of nitric oxide using single-walled carbon nanotubes network devices”, 

D. Fu, Y. Xu, L. J. Li*, S. G. Mhaisalkar, F. Y. C. Boey, T. W. Lin, Y. Chen, and S. Moochhala,2007, Carbon, 45, 1911-1914, 5-year IF= 5.728, ▲=19.

 


21. Crystal-encapsulation-induced band-structure change in single-walled carbon nanotubes: Photoluminescence and Raman spectra”, L. J. Li, T. W. Lin, J. Doig, I. B. Mortimer, J. G. Wiltshire, R. A. Taylor, J. Sloan, M. L. H. Green, and R. J. Nicholas*,  2006, Physical Review B, 74, 245418/1-5, 5-year IF= 3.364, ▲=13.

 


22.  Influence of double promotion on HDS catalysts prepared by urea-matrix combustion synthesis”, 

S. L. Gonzalez-Cortes*, T. C. Xiao, T. W. Lin, and M. L. H. Green, 2006, Applied Catalysis A: General, 302, 264-273, 5-year IF= 3.637, ▲=8.

 


23.  Self-reducible Cu(II) source reagents for the CVD of copper”,P. F. Hsu, Y. Chi*, T. W. Lin, C. S. Liu, A. J. Carty and S. M. Peng,  2001, Chemical Vapor Deposition, 7, 28-31, 5-year IF= 2.024, ▲=18.


II. Conference papers:


1.      T. W. Lin, S. Y. Choi, Y. H. Kim, and M. L. H. Green, Investigation on the role of carbon nanotubes in the synthesis of GaN nanowires, 7th International Conference on the Science and Application of Nanotubes, Nagano (Japan), June 18 – 23 (2006)
 
2.      T. W. Lin, C. G. Salzmann, and M. L. H. Green, Polyethylene glycol grafting and attachment of magnetic silica nanoparticles onto chlorosilanized single-wall carbon nanotubes, 7th International Conference on the Science and Application of Nanotubes, Nagano (Japan), June 18 – 23 (2006)

III. Patent



1. P. f. Hsu, T. W. Lin, C. S. Liu and A. J. Carty, Self-reducible and self-decomposing copper metalorganic complexes for deposition of electric conducting copper metal films, U. S. Patent Number: 6369256

bottom of page