WANG RESEARCH GROUP

Journal (peer reviewed)

1. N. Dahal, J. A. Osterberg, B. Braun, T. P. Caldwell, R. Divan, S. W. Harcum, and
P. Wang, “Spectroscopic analysis of Candida species, viability, and antifungal
drug effects with a microwave flow cytometer,” IEEE Journal of
Electromagnetics, RF and Microwaves in Medicine and Biology (in press), 2022

2. Jeffrey A.Osterberg, Jillian Milanes, JamesMorris, and PingshanWang,
“Detection of Trypanosoma brucei by microwave cytometry,” Sensors and
Actuators Reports 4 (2022) 100074

3. Duye Ye, Gabriel Cutter, Tom Caldtom, Sarah Harcum, and Pingshan Wang,
“Radiofrequency Non-Thermal Effect on Colony Growth of Yeast
Saccharomyces Cerevisiae,” IEEE Journal of Electromagnetics, RF and
Microwaves in Medicine and Biology, vol. 6, no. 1, p. 52, 2022

4. Jeffrey A. Osterberg, Neelima Dahal, Ralu Divan, Christina S. Miller, David
Moline, Thomas P. Caldwell, Xianzhong Yu, Sarah W. Harcum, and Pingshan
Wang, “Microwave sensing of yeast cell species and viability,” IEEE

Transactions on Microwave Theory and Techniques, vol. 69, no. 3, p. 1875,2021

5. Duye Ye, Omkar Omkar, Pingshan Wang, “A Dual-mode Microwave Resonator
for Liquid Chromatography Applications,” IEEE Sensors Journal, vol. 21, no. 2,
p. 1222, 2020

6. Duye Ye, Md Saiful Islam, Guofen Yu, and Pingshan Wang, “A Single-line
Single-channel Method with Closed-form Formulas for the Characterization of
Dielectric Liquids,” vol. 67, no. 6, IEEE Transactions on Microwave Theory and
Techniques, 2019, pp. 2443-2450

7. Yan Cui, William F. Delaney, Taghi Darroudi, and Pingshan Wang, “Microwave
measurement of giant unilamellar vesicles in aqueous solution”, Scientific
Reports, vol. 8, 497, 2018. DOI:10.1038/s41598-017-18806-9

8. Duye Ye, Weizheng Wang, David Moline, Feng Chen, Pingshan Wang, "A
Microwave Flow Detector for Gradient Elution Liquid Chromatography,"
Analytical Chemistry, vol. 89, 2017, pp. 10761-10768

9. Hao Li, Zhe Chen, Nikolay Borodinov, Yongzhi Shao, Igor Luzinov, Guofen Yu,
and Pingshan Wang, “Multi-Frequency Measurement of Volatile Organic
Compounds With a Radio-Frequency Interferometer,” IEEE Sensors Journal,
Vol. 17, no. 11, pp. 3323-3331, 2017

10. Zhe Chen, Jiwei Sun and Pingshan Wang, “Broadband ESR Spectroscopy With a
Tunable Interferometer,” vol. 53, no. 8, IEEE Transactions on Magnetics , 2017,
DOI: 10.1109/TMAG.2017.2697405 

11. Yan Cui and Pingshan Wang, “Auto-Tuning and Self-Calibration of High-
Sensitivity Radio Frequency Interferometers,” IEEE Microwave and Wireless
Components Letters, vol. 26, no. 11, pp. 957-959, 2016

​

12. Yan Cui, Anne K. Kenworthy, Michael Edidin, Ralu Divan, Daniel Rosenmann,
and Pingshan Wang, “Analyzing single giant unilamellar vesicles with a slotline-
based radio-frequency nanometer sensor,” IEEE Transactions on Microwave
Theory and Techniques, vol. 64, no. 4, pp. 1339-1347, 2016

13. Jeffrey Osterberg and Pingshan Wang, “Two-stage radio-frequency interferometer
sensors,” Applied Physics Letters, 107, 172907 (2015)

14. Yongzhi Shao, Zhe Chen, and Pingshan Wang, “Exploiting Filter Stop Band for
Radio Frequency Interferometer Operations,” IEEE Sensors Journal, 2015, DOI:
10.1109/JSEN.2015.2449731

15. Zhe Chen and Pingshan Wang, “Resonator and Filter Induced Slow Waves for
High-Sensitivity RF Interferometer Operations,” IEEE Sensors Journal, vol. 15,
no. 5, pp. 2993-2999, 2014

16. Yan Cui and Pingshan Wang, “The design and operation of ultra-sensitive and
tunable radio-frequency interferometers,” IEEE Transactions on Microwave
Theory and Techniques, vol. 62, no. 12, pp. 3172-3182, 2014

17. Chao Shen, Zhe Chen, Yongzhi Shao and Pingshan Wang, “Engineering spectrum
and dispersion with filters for high-sensitivity RF detections,” Applied Physics
Letters, vol. 105, p. 032902, 2014

18. Jiwei Sun, Haibo Wang, and Pingshan Wang, "A Spatial Sampling Based 13.3
Gs/s Sample-and-Hold Circuit" Review of Scientific Instruments, vol. 85, p.
094707, 2014

19. Jiwei Sun and Pingshan Wang, “On-chip Blumlein pulse generator,” Electronics
Letters, vol. 50, no. 12, 2014, DOI: 10.1049/el.2014.0485

20. Yan Cui, Yuxi He, and Pingshan Wang, “A quadrature-based tunable radio-
frequency sensor for the detection and analysis of aqueous solutions,” IEEE
Microwave and Wireless Components Letters, July, 2014, DOI:
10.1109/LMWC.2014.2316235

21. Jiwei Sun and Pingshan Wang, “Note: Complementary Metal-oxide-
semiconductor High Voltage Pulse Generation Circuits,” Review of Scientific
Instruments, vol. 84, no. 10, 2013, DOI: 10.1063/1.4827077

22. Yan Cui, Jiwei Sun, Yuxi he, Zheng Wang, and Pingshan Wang, “A simple,
tunable, and highly sensitive radio-frequency sensor,” Applied Physics Letters,
vol. 103, p. 062906, 2013

23. Shenghan Wang, Ralu Divan, Daniel Rosenmann, Leo E. Ocola, Jiwei Sun, and
Pingshan Wang, “Coplanar Waveguides With Nanometer Thick Gold Films,”
IEEE Microwave and Wireless Components Letters, vol. 23, no. 2, pp. 84-86,
2013. Digital Object Identifier: 10.1109/LMWC.2013.2238915

24. Jiwei Sun, Chaojiang Li, Yongtao Geng, and Pingshan Wang, “A Highly
Reconfigurable Low-Power CMOS Directional Coupler,” IEEE Transactions on
Microwave Theory and Techniques, vol. 60, no. 9, pp. 2815-2822, 2012.

​

25. Pengyu Chen, Yang Yang, Priyanka Bhattacharya, Pingshan Wang, and Pu Chun
Ke, “A Tris-Dendrimer for Hosting Diverse Chemical Species,” The Journal of
Physical Chemistry, vol. 115, 2011, pp. 12789–12796

26. Yongtao Geng, Huan Zou, Chaojiang Li, Jiwei Sun, Haibo Wang, and Pingshan
Wang, “Short Pulse Generation with On-Chip Pulse Forming Lines,” IEEE
Transactions on Very Large Scale Integrated Systems, vol. 20, no. 9, 2011,
DOI: 10.1109/TVLSI.2011.2160103  

27. Zou Huan, Geng Yong-Tao, Wang Ping-Shan, and Li Jia-Yin, “A comparison
study of on-chip short pulse generation circuits based on a coplanar waveguide,”
Chinese Phys. C, vol. 35, no. 3, p. 278 doi: 10.1088/1674-1137/35/3/012

28. Hanqiao Zhang, Ralu Divan, and Pingshan Wang, “Ferromagnetic resonance of a
single magnetic nanowire measured with an on-chip microwave interferometer,”
Review of Scientific Instruments, 82, no. 5, p. 054704, 2011

29. Hanqiao Zhang, Chaojiang Li, Wilson Pearson, Pingshan Wang, "Direct current
effects on 1/f noise in patterned permalloy films," Journal of Applied Physics, vol.
109, no. 7, 2011

30. Huan Zou, Yongtao Geng, and Pingshan Wang, “Transmission Line Based Short
Pulse Generation Circuits in a 0.13μm CMOS Technology,” Review of Scientific
Instruments, vol. 82, 023301, 2011

31. Chaojiang Li, Fei Gong, and Pingshan Wang, “A Low-Power Active Inductor
with Improved Q-Factor and Its Application to Phase Shifter,” Analog Integrated
Circuits and Signal Processing, vol. 66, no. 2, pp. 303-307, 2011

32. Pingshan Wang, Haibo Wang, Yueran Gao, Yongtao Geng, George Thomas, and
Chaojiang Li, “A High-Speed Sample-and-Hold Circuit Based on CMOS
Transmission Lines,” Analog Integrated Circuits and Signal Processing, vol. 66,
pp. 245-254, 2011

33. Chaojiang Li, Fei Gong, and Pingshan Wang, “Analysis and Design of a High-Q
Differential Active Inductor with Wide Tuning Range,” IET Circuits, Devices &
Systems, Vol. 4, no. 6, pp. 486–495, 2010. doi: 10.1049/iet-cds.2010.0011

34. Chaojiang Li, Fei Gong, and Pingshan Wang, “A low-power ultra-wideband
CMOS power detector with an embedded amplifier,” IEEE Transactions on
Instrumentation and Measurement, vol. 99, pp. 1-9, 2010, doi:
10.1109/TIM.2010.2047131

35. Chunrong Song, and Pingshan Wang, “ High electric field effects on gigahertz
dielectric properties of water measured with microwave microfluidic devices ,”
Review of Scientific Instruments, vol. 81, p. 054702, 2010,
doi:10.1063/1.3405975

36. Hanqiao Zhang, Chaojiang Li, Axel Hoffmann, Ralu Divan, and Pingshan Wang,
“ Broadband Mag-Noise of Patterned Permalloy Thin Films ,” IEEE Transactions
on Magnetics, vol. 46, no. 6, pp. 2442-2445, 2010.
10.1109/TMAG.2010.2040071

​

37. Yang Yang, Hanqiao Zhang, Junjie Zhu, Gaoyan Wang, Tzuen-Rong Tzeng,
Xiangchun Xuan, Kama Huang and Pingshan Wang, “Distinguishing the viability
of a single yeast cell with an ultra-sensitive radio frequency sensor,” Lab on a
Chip, vol. 10, pp. 553-555, 2010, doi: 10.1039/b921502f

38. Chunrong Song and Pingshan Wang, “Fabrication of Sub-10 nm Planar
Nanofluidic Channels through Native Oxide Etch and Anodic Wafer Bonding,”
IEEE Transactions on Nanotechnology, vol. 9, no. 2, pp. 138-141, 2010. Doi:
10.1109/TNANO.2009.2038377

39. Huan Zou, Hanqiao Zhang, Chunrong Song, George Thomas, Haibo Wang,
Pingshan Wang, “Characterization and modeling of mitered coplanar waveguide
bends on silicon substrates,” International Journal of Electronics, vol. 97, no. 6,
pp. 715-727, 2010, DOI: 10.1080/00207211003646977

40. Hanqiao Zhang, Axel Hoffmann, Ralu Divan, and Pingshan Wang, “ Direct-
current effects on magnetization reversal properties of submicron-size Permalloy
patterns for radio-frequency devices ” Appl. Phys. Lett. 95, 232503 (2009);
doi:10.1063/1.3271777

41. Pingshan Wang, Hanqiao Zhang, Ralu Divan, Axel Hoffmann, “Tailoring High-
Frequency Properties of Permalloy Films via Submicron Patterning,” IEEE
Transactions on Magnetics, vol. 45, no. 1, pp. 71-74, 2009

42. Hanqiao Zhang, Chunrong Song and Pingshan Wang, “A new method for high-
frequency characterization of patterned ferromagnetic thin films,” Journal of
Applied Physics, vol. 105, p. 07E716, 2009

43. Chunrong Song and Pingshan Wang, “A radio frequency device for measurement
of minute dielectric property changes in microfluidic channels,” Applied Physics
Letters, vol. 94, p. 023901, 2009

44. Syed Azeemuddin, Ralu Divan, Axel Hoffmann, and Pingshan Wang, “Patterned
permalloy films for high frequency on chip circuit components,” European
Journal of Scientific Research, vol. 32, no. 2, pp. 141-150, 2009

45. Chaojiang Li, Hanqiao Zhang, and Pingshan Wang, “A Novel Six-Port Circuit
Based on Four Quadrature Hybrids,” International Journal of RF and Microwave
Computer-Aided Engineering, vol. 28, p. 128, 2009

46. Hanqiao Zhang, Ralu Divan, Axel Hoffmann, and Pingshan Wang, “DC current
effects on high-frequency properties of patterned permalloy thin films,” IEEE
Transactions on Magnetics, vol. 45, p. 5296, 2009

47. Chunrong Song, James Harris, and Pingshan Wang, “Compensating on-chip
transmission line losses for a high-sensitivity microwave sensor,” Sensors and
Actuators A, vol. 154, no. 1, pp. 7-11, 2009

48. P. Wang, and E. C. Kan, “High-speed Interconnects with underlayer orthogonal
metal grids,” IEEE Trans. Advanced Packaging, vol. 27, no. 3, pp. 497-507, 2004.

​

49. P. Wang, W. Ni, N. C. Tien, and E. C. Kan, “High-Frequency Permalloy
Permeability Extracted from Scattering-Parameters,” J. Appl. Physics, vol. 95, no.
11, pp. 7034-7036, 2004

50. P. Wang, G. Pei, and E. C. Kan, “Pulsed wave interconnects,” IEEE Trans. VLSI
Syst., vol. 12, no. 5, pp. 453-463, 2004

51. P. Wang, N. C. Tien, and E. C. Kan, “Permalloy loaded transmission lines for
high-speed interconnect applications,” IEEE Trans. Electron Devices, vol. 51, no.
1, pp. 74-82, 2004

52. P. Wang, Z. Xu, J. A. Nation, S. Banna, and L. Schachter, “ Symmetric and
asymmetric mode interaction in high-power traveling wave amplifiers:
Experiments and theory ,” IEEE Trans. Plasma Sci., vol. 28, no.6, pp. 2262-2271,
2000

53. S. Banna, L. Schachter, J. Nation, and P. Wang, “Coupling of symmetric and
asymmetric modes in a high-power, high-efficiency traveling-wave amplifier,”
Physical Review E, vol 61, no.4, pp. 4445-4449, 2000

54. S. Banna, L. Schachter, J. Nation, and P. Wang, “ The interaction of symmetric
and asymmetric modes in a high-power traveling-wave amplifier ,” IEEE
Transactions on Plasma Science, Special Issue on High Power Microwaves, vol
28, no.3, pp. 798-811, 2000

55. P. Wang, Z. Xu, J. D. Ivers, J. A. Nation, S. Naqvi, and L. Schachter, “Efficient
Operation of a high power X-band traveling wave tube amplifier,” Applied
Physics Letters, vol. 75, no.16, pp.2506-2508, 1999

56. P. Wang, F. Lei, H. Huang, Y. Gan, W. Wang, and B. Gu, “Generation of intense
microwaves from a two-cavity image charge focusing relativistic klystron
amplifier,” Phys. Rev. Lett., vol. 80, no. 20, pp. 4594-4597, 1998

57. Q. Wang Qingyuan, Z. Kui, C. Chen, K. Hu, Y. Chen, and P. Wang, “Multi-
electron beam Cerenkov oscillator operating at mm wavelength,” Nucl. Instru.
Method Phys. Res., vol. 349, 1994

58. P. Wang, J. Hu, K. Hu, “End effects and focusing ability of a double bifilar helix
linear wiggler,” Nucl. Instru. Method Phys. Res., A331, pp. 731-735, 1993

59. Q. Wang, S. Yu, S. Liu, K. Hu, Y. Chen, and P. Wang, “First operation of a
multi-electron-beam Cerenkov Free electron laser,” Appl. Phys. Lett., vol 59, no.
19, pp. 2378-2380, 1991

​

60. P. Wang, K. Hu, S. Huang, S. Hu, and Y. Cheng, “Virtual cathode experiment on
a high impedance, low current pulse-line accelerator,” International Journal of
Infrared and millimeter waves, vol.11, no.12. pp. 1395-1398, 1990

61. F. Meng, Z. Yang, H. Ma, B. Ju, W. Wu, and P. Wang, “Experimental studies on
a 100 MW repetitive pulse ultra wide band radiation source,” High Power Laser
and Particle Beams (in Chinese), vol. 10, no.2, 1998

62. D. Zhu, P. Wang and S. Liu, “The longitudinal self-bunch of intensely relativistic
electron beam,” Journal of Electronics (in Chinese), vol. 27, no.8, p. 114-116,
1998

63. Wang Pingshan, H. Huang, Y. Gan, Z. Tao, “Confinement of electron beams by
mesh arrays in a relativistic klystron amplifier,” Acta Physica Sinica (in Chinese),
vol. 47, no.3, 1998

64. H. Huang, P. Wang, Y. Chen, “Influences of large coupling holes on the cavity
parameters for klystron amplifiers,” Journal of University of Electronic Science
and Technology of China (in Chinese), vol.27, no.2, p.166, 1998

65. H. Huang, P. Wang, F. Lei, H. Cheng, Y. Gan, and W. Wang, “A Study on a L-
band relativistic klystron amplifier,” High Power Laser and Particle Beams (in
Chinese), vol.10, no.1, p. 135, 1998

66. H. Huang, P. Wang, F. Lei, and Y. Gan, “Research on input cavity of L-band
relativistic klystron amplifiers,” High Power Laser and Particle Beams (in
Chinese), vol.9, no.4, p. 573, 1997

67. L. Xia, P. Wang, H. Huang, Y. Cheng, “The experiment result of relativistic
klystron at X-band with an annular intense beam,” High Power Laser and
Particle Beams (in Chinese), vol.8, no.1, pp.1-6, 1996

68. P. Wang, H. Huang, Y. Lei, Z. Tao, Confinement of mesh arrays to relativistic
annular beams and initial experimental results of the influences of the mesh array
on beam bunching, Acta Physica Sinica (in Chinese), vol. 45, no.6, 1996

69. P. Wang, K. Hu, and Y. Su, “Theoretical analysis of Raman free electron laser
experiment,” Acta Physica Sinica (in Chinese), vol. 40, no. 5, 1991

70. K. Hu, S. Huang, Y. Chen, S. Fu, P. Wang, and Z. Deng, “A Raman free electron
laser experiment without axial magnetic field,” High Power Laser and Particle
Beams (in Chinese), vol.2, no.2, 1990

71. P. Wang, K. Hu, Y. SU, and S. Huang, “A novel virtual cathode oscillator
experiment,” High Power Laser and Particle Beams (in Chinese), vol.2, no.4,
1990

​

72. P. Wang, K. Hu, J. Hu, Y. Yan, “Theoretical analysis of a free electron laser with
linear electro-static wiggler,” High Power Laser and Particle Beams (in Chinese),
vol.2, no.2, 1990

73. P. Wang, Y. Su, and K. Hu, “A double bifilar helix linear wiggler,” High Power
Laser and Particle Beams (in Chinese), vol.1, no.2, 1989

74. Pingshan Wang and Kesong Hu, “Electron trajectories of intense relativistic
electron beams,” Journal of University of Electronic Science and Technology of
China (in Chinese), Vol.18, no. 4, p. 321-331, 1989

 

Invited Talk
 

1. Pingshan Wang, “RF Sensors: Label-Free Detection and Analysis of Single Cells
in Liquid,” Department of Bioengineering and Mechanical Engineering,
University of South Carolina, Columbia, SC, November 2, 2012

2. Pingshan Wang, “Recent progress on microwave lab-on-chip,” Institute of
Applied Electronics, China Academy of Engineering Physics, Mianyang, China,
December, 2013

3. Pingshan Wang, “High-frequency magnetization dynamics in patterned permalloy
thin films,” Center for Nanoscale Materials, Argonne National Lab, May 9, 2012

4. Pingshan Wang, “Microwave lab-on-chip,” Institute of Applied Electronics,
China Academy of Engineering Physics, Mianyang, China, June, 2011

5. Pingshan Wang, “More Than Moore, You Are Invited,” Department of Physics,
Clemson University, 2009

​

​

Workshop Talk (invited)
 

1. Pingshan Wang and Yan Cui, “Measuring the microwave permittivity of giant
unilamellar vesicle membranes,” WMF-8, International Microwave Symposium,
Philadelphia, PA, June 10-15, 2018

2. Pingshan Wang, “Tunable interferometers for high sensitivity measurements of
cells and molecules in microfluidic channels,” ARFTG, Atlanta, GA, December
1-4, 2015

3. Pingshan Wang, Yan Cui, Chunrong Song, Zhe Chen, Yongzhi Shao, “Tunable
Radio Frequency Interferometers for the Detection and Analysis of Molecules in
Solutions,” IMS2015, Phoenix, AZ, 2015

4. Pingshan Wang, “Microwave interferometers for the measurement of single yeast
cells and particles in DI water,” IMS 2013, Seattle, WA, June 2-7

 

Conference Proceedings (Reviewed)
 

1. Neelima Dahal, Jeffrey Osterberg, Thomas Caldwell, Ralu Divan, Sarah
Harcum, Pingshan Wang, “Measuring yeast cell heterogeneity with a
microwave flow cytometer,” International Microwave Symposium, Denver,
CO, 2022

2. John S. Wang, David Moline, MD Saiful Islam and Pingshan Wang, “Single
particle transport in microfluidic channel constrictions and bifurcations at
low-Reynolds-numbers,” March 2020

3. Duye Ye, Weizheng Wang, David Moline, Feng Chen, Pingshan Wang, "A
Microwave Flow Detector for Gradient Elution Liquid Chromatography,"
HPLC 2017, Prague, Czech Republic, June 17-22, 2017

4. Z. Wang, Y. Raval, T. R. Tzeng, B. Booth, B. Flaherty, D. Peterson, J. Moore,
D. Rosenmann, R. Divan, G. Yu, and P. Wang, “Time Domain Detection and
Differentiation of Single Particles and Cells with a Radio Frequency
Interferometer,” 2016 IEEE Topical Conference on Biomedical Wireless
Technologies, Networks, and Sensing Systems (BioWireleSS), Austin Texas,
2016, pp. 77-80

5. Jiwei Sun, Hanqiao Zhang, and Pingshan Wang, “Reducing Power-Supply
and Ground Noise Induced Timing Jitter in Short Pulse Generation Circuits,”
2015 IEEE International Symposium on Electromagnetic Compatibility

6. Zhe Chen and Pingshan Wang, “Enhancing RF Interferometer Sensitivity with
a Resonator,” IEEE SENSORS, Valencia, Spain, November 2-5, 2014

7. Jiwei Sun and Pingshan Wang, “A CMOS Short Pulse Generator with a High-
Voltage Stacked MOSFET Switch,” IEEE 57th Int'l Midwest Symposium on
Circuits & Systems, College Station, Texas, August 3-6, 2014

8. Jiwei Sun and Pingshan Wang, “High Voltage Charge Pump with Triple Well
Diodes in a 0.13 µm Bulk CMOS Process,” IEEE 57th Int'l Midwest
Symposium on Circuits & Systems, College Station, Texas, August 3-6, 2014
 

9. Yan Cui, Jing Li, Weiguo Cao, and Pingshan Wang, “Highly Sensitive RF
Detection and Analysis of DNA Solutions,” student paper finalist, IMS2014,
Tampa, FL, 2014
 

10. Xiaodi Hu, Guofen Yu, Jiwei Sun, David Moline, and Pingshan Wang,
“Radio frequency detection and analysis of synthetic particles,” 2014 IEEE
Radio & Wireless Week, Newport Beach, California, January 20-23, 2014

11. Chunrong Song and Pingshan Wang, “Sub-10 nm Radio-Frequency Planar
Nanofluidic Channels,” IEEE IMS 2013, Seattle, WA, 2013

12. Yuxi He, Shenghan Wang, Ralu Divan, Daniel Rosenmann, and Pingshan
Wang, “Coplanar Waveguides with Sub-10 nm Gold Films,” IEEE IMS
2013, Seattle, WA, 2013

13. Y. Yang, Y. He, H. Zhang, K. Huang, G. Yu, and P. Wang, “Measuring the
microwave permittivity of single particles,” 2013 IEEE Radio & Wireless
Week, Austin, Texas, January 20-23, 2013

14. Jiwei Sun, Yuxi He, David Moline and Pingshan Wang, “A Highly Sensitive
and Tunable RF Sensor for Electron Paramagnetic Resonance Spectroscopy
Applications,” 55th Annual Rocky Mountain Conference on Magnetic
Resonance, Denver, CO, 2013

​

15. Huan Zou, Haiyang Wang, and Pingshan Wang, “On-chip tapered
transmission line transformer based on coplanar waveguide,” 2012
International Workshop on Microwave and Millimeter Wave Circuits and
System Technology (MMWCST), Chengdu, 2012

16. Chaojiang Li and Pingshan Wang, “Analysis of the Oscillation frequency and
Waveform Amplitude for a High- Frequency Differential Ring Oscillator,”
accepted by The 2nd International Conference on Electronics,
Communications and Control (ICECC2012)

17. Chunrong Song and Pingshan Wang, “A microfluidic device for high
frequency characterization of fluids under high DC electric fields,”
Solid-State Sensors, Actuators and Microsystems Conference
(TRANSDUCERS), 2011 16th International, pp. 2283-2286, 2011doi:
10.1109/TRANSDUCERS.2011.5969237

18. Chaojiang Li, Fei Gong, and Pingshan Wang, “A Wideband LNA Matched
with Quasi T-Coil Networks in 0.13 um CMOS,” IEEE 53rd MWSCAS, 2010
(In press)

19. Chunrong Song and Pingshan Wang, “A Simple Technique for Sub-10 nm
Planar Nanofluidic Channel Fabrication,” Mater. Res. Soc. Symp. Proc. Vol.
1222, 1222-DD05-08, 2010 (doi: 10.1557/PROC-1222-DD05-08)

20. Chunrong Song and Pingshan Wang, “DC electrical breakdown of water in a
sub-micron planar gap,” Proceedings of Pulsed Power Conference, 2009. PPC
'09. IEEE , pp. 561-564, 2009, doi: 10.1109/PPC.2009.5386340

21. Yang Yang, Rahul Mitchell Jairaj, Gaoyan Wang, Jeremy Tzeng, Xiangchun
Xuan, Kama Huang, and Pingshan Wang, “Broadband dielectric property
characterization of biological cells,” accepted for publication in Proceedings
of MNHMT2009, ASME 2009 2nd Micro/Nanoscale Heat & Mass Transfer
International Conference, December 18-22, 2009, Shanghai, China

22. Chaojiang Li, and Pingshan Wang, “A high frequency tunable differential
active inductor and its application to power dividers,”
IEEE 51 st Midwest Symposium on Circuits and Systems, 2008, pp. 285 - 288

23. Chunrong Song, and Pingshan Wang, “On-chip cancellation of parasitic
effects for dielectric permittivity measurement,” Digest IEEE MTT-S, 2008,
pp. 131 - 134

24. Hanqiao Zhang, Chunrong Song, Ralu, Divan, Axel Hoffmann, Pingshan
Wang, “High-Frequency Properties of Permalloy Nanowire Arrays for RF
Devices,” IEEE NANO, 2008, pp. 621 – 624

25. Chunrong Song, Zuqin Liu, Gyula Eres, David B. Geohegan, Pingshan Wang,
“A New Method for Microwave Characterization of Metallic Single-Walled
Carbon Nanotubes,” IEEE NANO, 2008, pp. 228 – 229

26. S. Azeemuddin, A. Hoffmann, R. divan, M. Donahue, S. H. Chung, P. Wang,
“High-frequency, Domain-wall Motion and Magnetization Rotation of
Patterned Permalloy Films under External Magnetic Field Excitation,” IEEE
NANO 2006, (July 20, 2006), pp. 853-856

​

27. C. Song, S. Azimuudin, B. Lee, F. Harackiewicz, M. Yen, D. Ralu, A.
Hoffman, P. Wang, “Microwave dielectric properties of on-chip liquid films,”
IEEE/NLM Life Science Systems & Applications Workshop, 2006, pp.102-
103

28. P. Wang and E. C. Kan, “Dispersion and resonance of on-chip interconnect
lines with underlayer orthogonal metal grids,” the 12 th Topical Meeting on
Electrical Performance of Electrical Packaging, Oct. 2003, pp.111-114

29. P. Wang, V. S. Kaper, S. J. Richard, and E. C. Kan, “Transient analysis of
nonlinear microwave circuits using small-signal scattering parameters,” 2003
IEEE RFIC Symp. Dig., Philadelphia, PA, pp. 361-364

30. P. Wang, N. C. Tien, and E. C. Kan, “Permalloy loaded transmission line for
high-speed interconnects,” Proc. 2003 IEEE International Interconnect
Conference, San Francisco, CA, pp. 159-161

31. Hanqiao Zhang, Ralu Divan, Pingshan Wang, “Ferromagnetic resonance and
damping in an individual magnetic nanowire measured with a differential
signaling radio-frequency device,” 55 th Annual Conference on Magnetism &
Magnetic Materials, 2010

32. Hanqiao Zhang, Chaojiang Li, Pingshan Wang, “Direct current effects on 1/f
and phase noise in Permalloy microwires,” 55 th Annual Conference on
Magnetism & Magnetic Materials, 2010

33. Pingshan Wang, Yongtao Geng, Huan Zou, Haibo Wang, Chaojiang Li, “An
on-chip power modulator,” IEEE International Power Modulator and High
Voltage Conference, Atlanta, GA, May 23-27, 2010

34. Huan Zou, Yongtao Geng, Chaojiang Li, Pingshan Wang, “A comparison
study of transmission line based on-chip short pulse generation circuits,”
IEEE International Power Modulator and High Voltage Conference, Atlanta,
GA, May 23-27, 2010

35. Hanqiao Zhang, Axel Hoffmann, Ralu Divan, and Pingshan Wang,
“Measuring broadband mag-noise of patterned Permalloy thin-films with a Y-
factor method,” 11 th MMM-Intermag Conference, Washington, DC, Jan. 18-
22, 2010

36. Chunrong Song and Pingshan Wang, “A technique for 1-10 nm planar
nanofluidic channel fabrication,” Materials Research Society 2009 Fall
Meeting, Boston, Nov. 30 th – Dec. 4 th , 2009

37. C.S. Song and P. Wang, “DC Electrical Breakdown of Water in a Sub-Micron
Planar Gap,” 17th IEEE International Pulsed Power Conference, Washington
DC, June 29 thru July 2, 2009

38. Hanqiao Zhang, Chunrong Song and Pingshan Wang, “A new method for
high-frequency characterization of patterned ferromagnetic thin films,” 53 rd
Annual Conference on Magnetism and Magnetic Materials, Austin, Texas,
Nov 10 th – Nov. 14 th , 2008

39. P. Wang, W. Ni, N. C. Tien and E. C. Kan, “High-Frequency Permalloy
Permeability Extracted from Scattering-Parameters,” the 9 th MMM-Intermag
conference, Anaheim, CA, 5-9 Jan. 2004

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40. E. C. Kan, Z. Liu, P. Wang, M. Kim, Y. N. Shen, "Design and technology of
submillimeter autonomous microsystems: a real power viewpoint for
functional module integration,” 2003 Nanotechnology Conference and Trade
Show, February 23-27, 2003, San Francisco, CA

41. E. C. Kan, Z. Liu, P. Wang, M. Kim, Y. N. Shen, and G. Pei, "Si fleas:
technology demonstration of functional modules in submillimeter autonomous
microsystems ", Invited talk, Ninth Foresight Conference on Molecular
Nanotechnology, Santa Clara, CA, Nov. 9-11, 2001

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