Publications

Citation Report of Publications
Total Publications	82
Sum of the Times Cited	875
Sum of Times Cited without self-citations	637
Citing Articles	614
Citing Articles without self-citations	545
Average Citations per Item	10.67
h-index	15
Published Items in Each Year

Citations in Each Year

資料來源: Web of Science

Peer-reviewed Journal Publications

Item

Title

Times Cited

2025
[01]	David M.-T. Kuo, "Temperature-stable tunneling current in serial double quantum dots: insights from nonequilibrium green functions and Pauli spin blockade" , Physical Chemistry Chemical Physics , 27(10), 5238-5248 (2025). [IF 2.9]	0
[01]	David M.-T. Kuo, "Topological states in finite graphene nanoribbons tuned by electric fields" , Journal of Physics: Condensed Matter , 37, 085304 (2025). [IF 2.3]	1

2024
[01]	David M.-T. Kuo, "Thermoelectric properties of armchair graphene nanoribbons with array characteristics" , RSC advances, 14(5), 3513-3518 (2024). [IF 3.9]	5
[02]	David M.-T. Kuo, "Charge transport through the multiple end zigzag edge states of armchair graphene nanoribbons and heterojunctions" , RSC advances, 14(28), 20113–20119 (2024). [IF 3.9]	2
[03]	David M.-T. Kuo, "Impact of valley degeneracy on the thermoelectric properties of zig-zag graphene nanoribbons with staggered sublattice potentials and transverse electric fields" , Physical Chemistry Chemical Physics, 26(43), 27591-27601 (2024). [IF 2.9]	1

2023
[01]	David M.-T. Kuo, "Effects of metallic electrodes on the thermoelectric properties of zigzag graphene nanoribbons with periodic vacancies" , J. Phys.: Condens. Matter, 35, 305301 (2023). [IF 2.745]	4
[02]	David M.-T. Kuo, "Effects of coulomb blockade on the charge transport through the topological states of finite armchair graphene nanoribbons and heterostructures" , Nanomaterials, 13, 1757 (2023). [IF 5.3]	3
[03]	Po-Yu Hong, Chi-Cheng Lai, Ting Tsai, Horng-Chih Lin, Thomas George, David M.-T. Kuo& Pei-Wen Li, "Determination of exciton binding energy using photocurrent spectroscopy of Ge quantum-dot single-hole transistors under CW pumping" , Scientific Reports, 13, 14333 (2023). [IF 3.8]	4
[04]	David M.-T. Kuo, "Thermal rectification through the topological states of asymmetrical length armchair graphene nanoribbons heterostructures with vacancies" , Nanotechnology 34, 505401 (2023). [IF 2.9]	3

2022
[01]	David M.-T. Kuo, Yia-Chung Chang, "Contact Effects on Thermoelectric Properties of Textured Graphene Nanoribbons" , Nanomaterials, 12, 3357 (2022). [IF 5.719]	8

[02]

David M.-T. Kuo, "Effects of zigzag edge states on the thermoelectric properties of finite graphene nanoribbons" , Jpn. J Appl. Phys. 61, 075001 (2022). [IF 1.491]

2021
[01]	David M.-T. Kuo, "Thermolelectric properties of finite two-dimensional quantum dot arrays with band-like electronic states" , Physica E. 126, 114406 (2021). [IF 3.57]	0

[02]

David M.-T. Kuo, "High thermoelectric figure of merit of quantum dot array quantum wires " , Jpn. J Appl. Phys. 60, 075001 (2021). [IF 1.38].

2020
[01]	David M.-T. Kuo, " Thermoelectric and electron heat rectification properties of quantum dot superlattice nanowire arrays" , AIP Advances 10,045222 (2020). [IF 1.579]	8

[02]

David M.-T. Kuo, Yia-Chung Chang, "Superlattice nanowire heat engines with direction-dependent power output and heat current " , Physica E. 115, 113671 (2020).

2018
[01]	David M.-T. Kuo, Chih-Chieh Chen, Yia-Chung Chang, "Optimizing thermoelectric efficiency of superlattice nanowires at room temperature" , Physica E. 102, 39 (2018). [IF 2.399]	1

2017
[01]	David M.-T. Kuo, Chih-Chieh Chen, Yia-Chung Chang, "Large enhancement in thermoelectric efficiency of quantum dot junctions due to increase of level degeneracy ", Phys. Rev. B 95,075432 (2017).[IF 3.836]	21

2015
[01	Yen-Chun Tseng, David M.-T. Kuo, Yia-Chung Chang, and Chia-Wei Tsai, "Thermoelectric effects of quantum dot arrays embedded in nanowires ", Sci. Lett. 4, 192 (2015).	1
[02]	Chih-Chieh Chen, David M. T. Kuo, and Yia-chung Chang, "Quantum interference and structure-dependent orbital-filling effects on the thermoelectric properties of quantum dot molecules", Phys. Chem. Chem. Phys. 17, 19386-19393 (2015). [IF 4.493]	3
[03]	Chih-Chieh Chen, Yia-chung Chang, and David M. T. Kuo, "Quantum interference and electron correlation in charge transport through triangular quantum dot molecules" ,Phys. Chem. Chem. Phys. 17, 6606-6611 (2015). [IF 4.493]	2

2014
[01]	David M. T. Kuo and Yia-chung Chang, "Long-distance coherent tunneling effect on the charge and heat currents in serially coupled triple quantum dots" ,Phys. Rev. B 89, 115416 (2014). [IF 3.736]	8

2013
[01]	Yen-Chun Tseng, David M.-T. Kuo, Yia-Chung Chang, and Yan-Ting Lin, "Heat rectification effect of serially coupled quantum dots" ,Appl. Phys. Lett 103, 053108 (2013). [IF 3.515]	10
[02]	David M.-T. Kuo and Yia-Chung Chang, "Thermoelectric properties of a chain of coupled quantum dots embedded in a nanowire" ,J. Vac. Sci. Technol. B 31, 04D108 (2013). [IF 1.358]	2
[03]	David M.-T. Kuo, "Tunneling Current Spectra of a Metal Core/Semiconductor Shell Quantum Dot Molecule" ,Jpn. J. Appl. Phys. 52, 065001(2013). [IF 1.057]	1
[04]	David M-T Kuo and Yia-Chung Chang, "Thermoelectric properties of a quantum dot array connected to metallic electrodes" ,Nanotechnology 24, 175403 (2013). [IF 3.672]	10
[05]	Yen-Chun Tseng, David M.-T. Kuo , and Yia-Chung Chang, "Effects of valence-band mixing and strain on thermoelectric properties of p-type quantum wells" ,J. Appl. Phys. 113, 113706 (2013). [IF 2.185]	2
[06]	Yen-Chun Tseng and David M.-T. Kuo, "Current Rectification and Seebeck Coefficient of Serially Coupled Double Quantum Dots" ,Jpn. J Appl. Phys. 52, 014002 (2013). [IF 1.057]	0

2012
[01]	David M. T. Kuo and Yia-Chung Chang, "Effects of interdot hopping and Coulomb blockade on the thermoelectric properties of serially coupled quantum dots" ,Nanoscale Res. Lett. 7, 257 (2012). [IF 2.524]	12

2011
[01]	David M.-T. Kuo, Shiue-Yuan Shiau, and Yia-chung Chang, "Theory of spin blockade, charge ratchet effect, and thermoelectrical behavior in serially coupled quantum dot system" ,Phys. Rev. B 84, 245303 (2011). [IF 3.691]	31
[02]	Shiue-Yuan Shiau, Yia-Chung Chang, and David M.-T. Kuo, "Bistability in the tunneling current through a ring of n coupled quantum dots" ,J. Phys. Soc. Jap. 80, 114717 (2011). [IF 2.364]	0
[03]	David M.-T. Kuo and Yia-chung Chang, "Bipolar thermoelectric effect in a serially coupled quantum dot system " ,Jpn. J. Appl. Phys. 50 , 105003 (2011). [IF 1.058]	4
[04]	David M.-T. Kuo, "Thermoelectric Properties of Double Quantum Dots Embedded in a Nanowire" ,Jpn. J. Appl. Phys. 50 , 025003 (2011). [IF 1.058]	2

2010
[01]	David M.-T. Kuo and Yia-Chung Chang, "Thermoelectric Effects of Multiple Quantum Dot Junctions in the Nonlinear Response Regime" ,Jpn. J. Appl. Phys. 49, 064301 (2010). [IF 1.024]	3
[02]	David M.-T. Kuo and Yia-Chung Chang, "Thermoelectric and thermal rectification properties of quantum dot junctions" ,Phys. Rev. B 81, 205321 (2010). [IF 3.774]	137
[03]	David M.-T. Kuo, "Thermoelectric Effects of Molecular Quantum Dot Junctions with Strong Electron Phonon Interactions" ,Jpn. J. Appl. Phys. 49, 095205 (2010). [IF 1.024]	5
[04]	David M.-T. Kuo, "Thermal Rectification Effects of Multiple Semiconductor Quantum Dot Junctions" ,Jpn. J. Appl. Phys. 49, 105202 (2010). [IF 1.024]	3

2009
[01]	David M.-T. Kuo, "Thermoelectric Properties of Multiple Quantum Dot Junction System" ,Jpn. J. Appl. Phys. 48, 125005 (2009). [IF 1.138]	13
[02]	David M.-T. Kuo and Yia-Chung Chang, "Bistable States of Quantum Dot Array Junctions for High-Density Memory" ,Jpn. J. Appl. Phys. 48, 104504 (2009). [USA patent 7972878 ] [IF 1.138]	1
[03]	Wei-Ting Lai, David M. T. Kuo, and Pei-Wen Li, "Transient current through a single germanium quantum dot" ,Physica E. 41, 886 (2009). [IF 1.177]	15
[04]	David M. T. Kuo and Yia-Chung Chang, "Multi-peak negative differential resistance device consisting of multiple quantum dots sandwiched between two metallic electrodes" ,Physica E. 41, 395 (2009). [IF 1.177]	5

2008
[01]	David M.-T. Kuo, "Negative Differential Resistance Arising from Tunneling Current through Multiple Quantum Dots" ,Jpn. J Appl Phys. 47. 8291 (2008). [IF 1.309](SCI)	5
[02]	David M.-T. Kuo, "Tunneling current through multiple degenerate states of individual quantum dots", Jpn. J Appl Phys. 47, 5358 (2008). [IF 1.309](SCI)	1
[03]	David M.-T. Kuo and Yia-Chung Chang, "Theory of electron tunneling through a scanning tunneling microscopy-tip/quantum dot junction", J. Vac. Sci. Technol B 26, 1483 (2008). [IF 1.445]	0
[04]	R. B. Chiou and David M. T. Kuo, "Effects of composite InGaAs and InAlAs layers on the emission wavelengths of quantum dots" ,Chin. J. Phys. 46, 348 (2008). [IF 0.27](SCI)	1
[05]	Yia-Chung Chang and David M.-T. Kuo, "Theory of charge transport in a quantum dot tunnel junction with multiple energy levels" ,Phys. Rev. B 77, 245412 (2008). [IF 3.322]	38

2007
[01]	Gwong-Liang Chen, David M. T. Kuo, Wai-Ting Lai, and Pei-Wen Li, "Tunneling spectroscopy of a germanium quantum dot in single-hole transistor with self-aligned electrodes" ,Nano. Tech. 18, 475402 (2007). [IF 3.0] (SCI)	24
[02]	David M. T. Kuo and Yia-Chung Chang, "Tunneling current spectroscopy of a nanostructure junction involving multiple energy levels" ,Phys. Rev. Lett. 99. 086803 (2007). [IF 7.1](SCI)(selected by virtual journal in science and technology)	38
[03]	Y. C. Hsu, W. T. Lai, P. W. Li , and David M. T. Kuo, "Room-temperature observation of current bistability and fine structures in germanium quantum dots/SiO2 resonant tunneling diodes" ,Physica E, 38. 135 (2007). [IF 1.2] (SCI)	3

1996~2006
[01]	W. S. Liu, David M T Kuo, J. I. Chyi, W. Y. Chen , H. S. Chang, and T. M. Hsu, "Enhanced thermal stability and emission intensity of InAs quantum dots covered by an InGaAsSb strain-reducing layer" ,Appl. Phys. Lett. 89, 243103 (2006). [IF 3.4] (SCI)	42
[02]	P. W. Li ,David M. T. Kuo, and Y. C.Hsu, "Photoexcitation effects on Ge quantum dot resonant tunneling diodes" ,Appl. Phys. Lett. 89, 133105 (2006). [IF 3.4] (SCI)	5
[03]	David M. T. Kuo, "Light-emitting current of electrically driven single-photon sources" ,Phys. Rev. B 74, 115311 (2006). (SCI) [IF 3.3]	3
[04]	P. W. Li , David M. T. Kuo, W. M. Liao, and W. T. Lai, "Study of tunneling currents through germanium quantum dot single-hole and -electron transistors" ,Appl. Phys. Lett. 88, 213117 (2006) [IF 3.4] (SCI)	12
[05]	W. M. Liao, P. W. Li, David M. T. Kuo and W. T. Lai, "Room-temperature transient carrier transport in germanium single-hole/electron transistors" ,Appl. Phys. Lett. 88, 1821091 (2006). [IF 3.4] (SCI)	8
[06]	David M. T. Kuo, "Stark effect on the exciton complexes of a single quantum dot embedded in a p-n junction" ,Jpn. J. Appl. Phys. 45, 3927 (2006). [IF 1.3] (SCI)	1
[07]	David M T Kuo and P. W. Li, "Effect of interdot Coulomb repulsion effect on the charge transport of parallel double single electron transistors" ,Jpn. J. Appl. Phys. 45, 2881 (2006). [IF 1.2] (SCI)	1
[08]	David M. T. Kuo, "Fano interference effect on the transition spectrum of single-electron transistors" ,Phys. Rev. B 73, 155331 (2006). [IF 3.1] (SCI)	0
[09]	David M T Kuo, "Infrared wavelength quantum communications based on single electron transistors" ,Int. J. Quanum Inform. 03, 163 (2005).	1
[10]	David M. T. Kuo and P. W. Li, "Tunneling Current through a Single Germanium Quantum Dot" ,Jpn. J. Appl. Phys. 44, 6429 (2005) . [IF 1.2]	4
[11]	David M. T. Kuo and Yia-Chung Chang, "Tunneling current and emission spectrum of a single electron transistor under optical pumping" ,Phys. Rev. B 72, 085334 (2005) [IF 3.1](selected by virtual journal in science and technology) (SCI)	20
[12]	David M. T. Kuo, "Effect of interlevel Coulomb interactions on the tunneling current through a single quantum dot" ,Physica E 27, 355 (2005). [IF 0.8]	2
[13]	David M. T. Kuo and Y. C. Chang, "Electrically-driven Spontaneous Emission Spectrum of a Single Quantum Dot" ,J. Phys. Soc. Jpn. 74, 690 (2005). [IF 2.3]	2
[14]	David M. T. Kuo, "Single electron transistors for infrared wavelength quantum communications" ,Jpn . J. Appl. Phys. 43, L1607 (2004). [IF 1.3]	1
[15]	P. W. Li, David M. T. Kuo, W. M. Liao, S. S. Tseng, P. S. Chen, and M. –J. Tsai, "Optical and electronic properties of Ge quantum dots formed by selective oxidation of S SiGe/Si-on-Insulator" ,Jpn. J. Appl. Phys. 43, 7788 (2004). [IF 1.3]	16
[16]	P. W. Li, W. M. Liao, David M. T. Kuo, W. C. Tsai, S. W. Lin, P. S. Chen, S. C. Lu, and M. –J. Tsai, "Fabrication of a Germanium Quantum-dot Single Electron Transistor with Large Coulomb-blockade Oscillations at Room Temperatures" ,Appl. Phys. Lett. 85, 1532 (2004). [IF 4.0]	51
[17]	David M. T. Kuo and Y. C. Chang, "Spontaneous spins polarized tunneling current through a quantum dot array", Chin. J. Phys. 42, 281 (2004)”. [IF 0.2]	0
[18]	David M. T. Kuo and Y. C. Chang, "Emission spectrum of a single quantum dot embedded in a p-n junction" ,Phys. Rev. B 69, Rapid communications 041306 (2004). [IF 3.1](selected by virtual journal in science and technology)	7
[19]	Y. C. Chang and David M. T. Kuo, "Effects of electron correlation on the photocurrent in quantum dot infrared photodetectors" ,Appl. Phys. Lett. 83, 156 (2003) [IF 4.0]	4
[20]	David M. T. Kuo and Y. C. Chang, "Effects of Coulomb blockade on the photocurrent in quantum dot infrared photodetectors" ,Phys. Rev. B 67, 035313 (2003) [IF 3.1]	5
[21]	David M. T. Kuo and Y. C. Chang, "Tunneling current through a quantum dot with strong electron-phonon interaction" ,Phys. Rev. B 66, 085311 (2002)[IF 3.1]	45
[22]	David M. T. Kuo, G. Y. Guo and Y. C. Chang, "Tunneling current through a quantum dot array" ,Appl. Phys. Lett. 79, 3851 (2001) [IF 4.0]	22
[23]	David M. T. Kuo, Angbo Fang, and Y. C. Chang, "Theoretical modeling of dark current and photo-response for quantum well and quantum dot infrared detector" ,Infrared Phys & Tech 42, 433 (2001) [IF 1.0]	29
[24]	David M.T.Kuo and Y. C. Chang, “Dynamic behavior and inter-subband electro-absorption of double quantum wells”, Chin. J. Phys., 39, 75 (2001) [IF 0.2]	1
[25]	David M. T. Kuo and Y. C. Chang, "Electron tunneling rate in quantum dots under a uniform electric field" ,Phys. Rev. B 61, 11051 (2000) [IF 3.1]	72
[26]	David M. T. Kuo and Y. C. Chang, "Intersubband electroabsorption spectra of semiconductor quantum wells" ,J. Appl. Phys. 87, 2936 (2000) [IF 2.3]	6
[27]	David M. T. Kuo, G. S. Setlur and Y. C. Chang, "Optical conductivity and Raman spectra of coupled electron-phonon systems via bosonic algebra" ,Phys. Rev. B 61, 290 –298 (2000) [IF 3.3]	0
[28]	David M. T. Kuo and Y. C. Chang, "Dynamic behavior of electron tunneling and dark current in quantum well systems under electric field" ,Phys. Rev. B, 60, 15957 (1999) [IF 3.3]	22
[29]	Tzihong Chiueh and David M. T. Kuo, "Quasi – Periodic vertical structure in dusty plasma",Europhys. Lett. 46, 190 (1999) . [IF 2.2]	2
[30]	Tzihong Chiueh and David M. T. Kuo, "Nonlinear ionization waves" ,Phys. Rev. E 57, 4633 (1998) [IF 2.4]	0
[31]	David M. T. Kuo and C. D. Hu, "The electromagnetic response of gauge field model" ,Phys. Rev. B 54, 15402 (1996) [IF 3.3]	0
[32]	David M. T. Kuo and C. D. Hu, "The optical conductivity of gauge field model" ,Chin. J. Phys. 34, 642 (1996) [IF 0.2]	0
[33]	P. M. Hui and David M. T. Kuo, "Effects of density of states on superconductivity" ,Phys. Lett. A 160, 305 (1991) [IF 2.0]	3
[34]	David M. T. Kuo and P. M. Hui, "Effective electromagnetic response in superconductor-normal metal composites" ,Physica C, 174, 365 (1991) [IF 0.8]	2