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“The best way to predict the future is to invent it”  -- Alan Kay (1971) at a 1971 meeting of PARC

Research interests

My specific research interests have been focused on solving challenges on electronics including transistors with nanofabrication processes and materials for 7nm technology node and beyond. While my on-going research activities continue to evolve, my historical research programs can be divided into three focus areas, namely:

1. Electronic materials research on the latest challenges logic devices and memory devices including process and materials
2. Novel electronic device applications with nano-scale 2-D materials, nanowires, and QDs
3. GaN electronics

A summary of these researches follows.

Materials integration and nanofabrication for advanced device applications

I obtained a significant amount of my microfabrication and nanofabrication experience while at Applied Materials and Sun Microsystems. Since I gained that experience, I have been able to leverage both the new skills and my materials & device background to contribute to several advanced device applications. The figure shows challenges of the future nanowire-based devices that I am interested in investigating, which describes the challenges of the gate all around the structure with nanowires transistor array with a nanoscale device. This effort utilized deposition equipment (CVD, PVD, and ALD systems) that are capable of depositing thin films of metals, semiconductors, and insulating materials. These tools allow these thin film materials (metals, semiconductors, and insulators) to be deposited in a combinatorial or layered fashion.

Novel electronic device applications with nano-scale 2-D materials, nanowires, and QDs

Two-dimensional electronic materials (MoS2, etc): Two-dimensional materials are attractive for use in next-generation nanoelectronic devices as they are relatively easy to fabricate complex structures from compared to one-dimensional materials. Because monolayer MoS2 has a direct bandgap, it can be used to construct interband tunnel FETs. It will offer lower power consumption than classical transistors. Monolayer MoS2 could be used in applications that require thin transparent semiconductors, such as optoelectronics and energy harvesting, and energy-related materials and devices. Novel electronic applications with 2D materials and nanowires for biosensors: For example, Graphene is a covalent 2D electron system comprised of a single layer of carbon atoms arranged in a hexagonal honeycomb lattice. It has a unique electronic structure with linear dispersion, vanishing effective mass, extremely high carrier velocities, strong optical absorption over a wide wavelength range, and excellent thermal and mechanical properties. Because of these characteristics, there has been a strong interest in using it in electronics and optoelectronics. The limited gate-field induced tunability of the current through it and the excellent transport properties recommend it for fast analog and sensor applications. This will be a good platform for developing low-cost diagnostic devices for global health problems (HIV, or e.coli infection etc). Moreover, I aim to develop technologies to capture various cell types from blood using nanoparticles and microscale technologies.

GaN electronics

Integral to consumer electronics and many clean energy technologies, power electronics can be found in everything from electric vehicles and industrial motors, to laptop power adaptors and inverters that connect solar panels and wind turbines to the electric grid. For nearly 50 years, silicon chips have been the basis of power electronics. However, as clean energy technologies and the electronics industry has advanced, silicon chips are reaching their limits in power conversion — resulting in wasted heat and higher energy consumption. GaN is a revolutionary technology that will impact two major and distinct applications: high frequency and high power electronics. Through NRC’s GaN Electronics initiative in Canada, this will ensure that GaN technology will create wealth and a greener future for Canadians by establishing a strong industrial GaN manufacturing capability. NRC is the only Canadian foundry for GaN electronics and a global leader in the field. By collaborating with NRC at Ottawa, GaN-based technology will be gained a distinct competitive advantage with having access to the leading national research and technology development facilities, including the Ottawa-based Canadian Photonics Fabrication Centre (CPFC).

Deep learning and wearables for Parkinson’s disease

IoT sensor networks We will also introduce the use of technology to generate quantitative unbiased outcomes related with PD motor symptoms, such as tremor, gait, and falls, or to determine the level of engagement in physical activity in the context of an exercise program for PD. In order to do this, we have assembled a multidisciplinary group of academic researchers which include engineers with expertise in sensors, nanotechnology, mobile devices, computer science specialists, and specialists in understanding PD symptomatology (kinesiologists and PD specialists). These individuals will be supported by industry who will provide additional resources including hardware and software development, and opportunities for commercialization. 

Signal process and electrode design for Deep Brain Stimulation 

The Deep Brain Stimulation (DBS) for Parkinson’s Disease Project has been researching a way to improve DBS through the development of a novel electrode that can both stimulate and record brain activity within the same device. Currently, recording and stimulation have to be done separately which lengthens the time of the procedure and can lead to discrepancies in the position of the electrode. Both issues increase the risk of complications.

Advancing ultrasound performance through data acquisition: Creating a comprehensive guideline for physicians-in-training

Inexperienced physicians today do not automatically know how to manipulate an ultrasound probe to their advantage. They need instructions and help from other physicians for a period of time before they learn how to properly use an ultrasound device. Therefore the goal would be to find a way to create a guideline/manual (written instructions) to assist physicians in performing an ultrasound.

Sensor development for sensitive detection and identification of airborne chemicals and biological agents

Portable explosive detectors, chemical identifiers and personal radiation detectors (PRD) are now commercially available and can routinely be used in the field for environmental, forensic and material sampling. These devices are based on well-known technologies such as mass spectrometry, patch-chemical reactions, electrochemical sensing, ion-mobility spectrometry, laser-induced fluorescence, acoustic-wave-chemical sensing, and fiber-based optical detection. Although constant progress is being made to improve these techniques, a disruptive sensing technology can improve safety and help counter terrorism by drastically enhancing detection performances in terms of sensitivity, selectivity, response time and repeatability. The main objective of this proposal is to develop and demonstrate a new sensing technology.

Selected publications

Journal Articles (submitted):

1. The Quantized Nature of Arc-Multiwalled Carbon Nanotubes, sp2-sp3-Hybridization of Helical Carbon Mediated by Atomic Hydrogen, Science Advance (submitted) (2022).
2. A neural subspace for encoding multiple associative memories in the primate lateral prefrontal cortex, Neuron (submitted) (2022).
3. Two-dimensional BAs/GeC van der Waals heterostructures: A widely tunable photocatalyst for water splitting and hydrogen production, Journal of Physics and Chemistry of Solids (submitted) (2022).
4. Radial-Tangential Mode of Single-Wall Carbon Nanotubes Manifested by Landau Regulation: Reinterpretation of Low- and Intermediate-Frequency Raman Signals, (Nature) Scientific Reports (under revision) (2022).
5. Growth mechanisms of two-dimensional hexagonal boron nitride (h-BN) on metal surfaces: Theoretical perspectives, Applied Materials Today (submitted) (2022).
6. Synthesis of Low-Band Gap Porous Zirconia Nanoparticles via Greener-Route: Mechanism, Theoretical Justification, Photocatalysis, and Antibacterial Activity, Nano Express (submitted) (2022).
7. Negative-capacitance Field-Effect Transistors: Behind the Origin and Challenges, Materials Today Physics (submitted) (2022).
8. Metallic CNT Tolerant Field Effect Transistor using Dielectrophoresis, IEEE Open Journal of Nanotechnology (Submitted) (2022).
9. CNFET SRAM Bit Cell for Processing In Memory, IEEE Transactions on Circuits and Systems (submitted) (2022).
10. E-Band CMOS Integrated Yagi Antenna with Hilbert Curve Shaped Artificial Magnetic Conductor, (submitted) (2020).
11. , Journal Annalen der Physik (Under revision) (2019).
12. Graphene-based Chemical and Biological Sensors, 2D Materials (Submitted) (2019).
13. Dallaire N., Zhang Y., Deng X., Andrzejewski L., Guay J.-M., Rautela R., Scarfe S., Park J., Ménard J.-M.,Luican-Mayer A., Under review, preprint.

Journal Articles (published):

1. , Siraj Ahmed, Majid Komeili and Jeongwon Park (Nature) Scientific Reports, 12, 21469 (2022) (Impact Factor: 4.996) .
2. n, Naim Ferdous, Md. Sherajul Islam, Jeshurun Biney, Catherine Stampfl & Jeongwon Park (Nature) Scientific Reports, 12, 20106 (2022) (Impact Factor: 4.996) .
3. , Abdullah Arafat, Md. Sherajul Islam, Naim Ferdous, A. S. M. Jannatul Islam, Md. Mosarof Hossain Sarkar, Catherine Stampfl & Jeongwon Park, (Nature) Scientific Reports, 12, 16085 (2022) (Impact Factor: 4.996).
4. , Nisha Kumari,   Shweta Sareen,   Meenakshi Verma,   Shelja Sharma,   Ajay Sharma,   Harvinder Singh Sohal,   S. K. Mehta,   Jeongwon Park  and  Vishal Mutreja,  Nanoscale Advances, 4, 4210-4236 (2022) (Impact Factor: 5.598).
5. , Rasidul Islam, Sherajul Islam, Rayid Hasan Mojumder, Zarif Khan, Hasan Molla, A.S.M. Jannatul  Islam, Jeongwon Park, Materials Today Communications, 104227 (2022) (Impact Factor: 3.383) .
6. , Md. Sherajul Islam, Ashraful Hossain Howlader, Rongkun Zheng, Catherine Stampfl, Jeongwon Park, and Akihiro Hashimoto, ACS Omega, 7, 30, 26591–26600 (2022) (Impact Factor: 4.132).
7. , Md. Yasir Zamil, Md. Sherajul Islam, Catherine Stampfl, and Jeongwon Park, ACS Applied Materials & Interfaces, 14, 18, 20856–20865  (2022) (Impact Factor: 8.33) .
8. , Vishal Mutreja, Ajay Kumar, Shweta Sareen, Khushboo Pathania, Harshit Sandhu, Dr. Ramesh Kataria, Sandip V. Pawar, Surinder K. Mehta, Jeongwon Park, ChemistrySelect, 7(21), e202200448 (2022), (Impact Factor: 2.109).
9. , Anahita Malvea, Farbod Babaei, Chadwick Boulay, Adam Sachs, Jeongwon Park, Biomedical Engineering Letters 12, 303–316, Springer Nature (2022) DOI: 10.1007/s13534-022-00226-y (Impact Factor:  5.25).
10. , A. S. M. Jannatul Islam, Md. Sherajul Islam, Md. Sayed Hasan, Md. Shahadat Akbar, and Jeongwon Park, ACS Omega, 7, 17, 14678–14689 (2022) (Impact Factor: 4.132).
11. , Muhammad Riaz, Uzma Sharafat, Nafeesa Zahid, Muhammad Ismail, Jeongwon Park,* Bashir Ahmad, Neelum Rashid, Muhammad Fahim, Muhammad Imran, and Aisha Tabassum, ACS Omega 7, 14723−14734 (2022)(Impact Factor: 4.132).
12. , Md. Mosarof Hossain Sarkar, Md. Sherajul Islam, Abdullah Arafat, A. S. M. Jannatul Islam, Naim Ferdous, Md. Tawabur Rahman, Minhaz Uddin Sohag, Md. Al Imran Fahim, Catherine Stampfl, and Jeongwon Park, J. Phys. Chem. C 2022, 126, 14, 6373–6384 (2022)(Impact Factor: 2.781).
13. , Abdullah Al Mamun Mazumder, Kamal Hosen, Md. Sherajul Islam, Jeongwon Park, IEEE Access, 10, 30323 (2022) DOI: 10.1109/ACCESS.2022.3159809 (Impact Factor:  3.361).
14. , Jeongwon Park, Peter Zalden, Edwin Ng, Scott Johnston, Scott W. Fong, Chieh Chang, Christopher J. Tassone, Douglas Van Campen, Walter Mok, Hideo Mabuchi, H.-S. Philip Wong, Zhi-Xun Shen, Aaron M. Lindenberg, and Anne Sakdinawat, Opt. Mater. Express 12, 1408-1416 (2022) (Impact Factor: 3.442).
15. , Md. Sherajul Islam, Imon Mia, A. S. M. Jannatul Islam, Catherine Stampfl, and  Jeongwon Park (Nature) Scientific Reports, 12, 761 (2022) (Impact Factor: 4.996).
16. , A. S. M. Jannatul Islam, Md. Sherajul Islam, Nura Zannat Mim, Md. Shahadat Akbar, Md. Sayed Hasan, Md. Rasidul Islam, Catherine Stampfl, and Jeongwon Park, ACS Omega 7, 5, 4525–4537 (2022) (Impact Factor: 4.132) .
17. , Hardeep Kaur, Shweta Sareen, Meenakshi Verma, Aseem Vashisht, Ajay Sharma, Ramesh Kataria, S. K. Mehta, Jeongwon Park & Vishal Mutreja, Critical Reviews in Analytical Chemistry (2021) DOI: 10.1080/10408347.2021.1977608 (Impact Factor: 4.568).
18. , Md. Sherajul Islam, Md. Yasir Zamil, Md. Rayid Hasan Mojumder, Catherine Stampfl & Jeongwon Park, (Nature) Scientific Reports, 11:18669 (2021) (Impact Factor: 4.996).
19. , Sohag, Minhaz Uddin, Md Sherajul Islam, Kamal Hosen, Md Al Imran Fahim, Md Mosarof Hossain Sarkar, and Jeongwon Park, Results in Physics, 104796, (2021)  (Impact Factor: 4.476).
20. , Islam, Md, Abu Farzan Mitul, Md Mojumder, Rayid Hasan, A. S. M. Islam, Catherine Stampfl, and Jeongwon Park, Nature) Scientific Reports,1, 1-14 (2021) (Impact Factor: 4.996).
21. , A.S.M. Jannatul Islam, Md. Sayed Hasan, Md. Sherajul Islam, Jeongwon Park, Computational Materials Science, 200, 110824 (2021)  (Impact Factor: 3.3).
22. , Kamal Hosen; Md. Sherajul Islam; Catherine Stampfl; Jeongwon Park, IEEE Access, 9, 116254 - 116264 (2021) DOI: 1109/ACCESS.2021.3105341 (Impact Factor:  3.367).
23. , A. S. M. Jannatul Islam, Md. Shahadat Akbar, Md. Sherajul Islam, Jeongwon Park, ACS Omega, 2021, 6, 34, 21861–21871 (2021) (Impact Factor: 4.132).
24. , Islam, A. J., Islam, M. S., Islam, M. R., Stampfl, C., & Park, J, Nanotechnology, 32,435703 (2021) (Impact Factor:  3.974).
25. , Md. Sakib ; Islam, Md. Sherajul; Park, Jeongwon, Nanotechnology, 32 305707 (2021)(Impact Factor:  3.974).
26. , Biswajit Dey, Md. Sherajul Islam, and Jeongwon Park, Results in Physics, 23, 104021 (2021)(Impact Factor:  4.476).
27. , Riaz, Muhammad, Vishal Mutreja, Shweta Sareen, Bashir Ahmad, Muhammad Faheem, Nafeesa Zahid, Ghassan Jabbour, and Jeongwon Park, (Nature) Scientific Reports, 11, 2866 (2021)(Impact Factor:  4.379).
28. , Mojumder, Md Rayid Hasan, Md Sherajul Islam, and Jeongwon Park, AIP Advances, 1,  015126 (2021): 10.1063/5.0023448 (Impact Factor:  1.548).
29. , Md. Sherajul Islam, Imon Mia, Shihab Ahammed, Catherine Stampfl and Jeongwon Park, (Nature) Scientific Reports, 10, 22050 (2020) (Impact Factor: 4.996).
30. , Muhammad Riaz, Muhammad Ismail, Bashir Ahmad, Nafeesa Zahid, Ghassan Jabbour, Muhammad Shafiq Khan, Vishal Mutreja, Shweta Sareen, Aftab Rafiq, Muhammad Faheem, Muhammad Musaddiq Shah, M. I. Khan, Syed Ali Imran Bukhari and Jeongwon Park, Green Processing and Synthesis, 27;9(1):693-705. (2020)  (Impact Factor:  2.83).
31. , Md Sherajul Islam, Md. Rayid Hasan Mojumder; Naim Ferdous; Jeongwon Park, Materials Today Communications, 101718 (2020) (Impact Factor: 2.678).
32. , Yu Zheng, Dongmeng Li, Zubair Ahmed, Jeongwon Park, Changjian Zhou, and Cary Y. Yang, Journal of Electronic Materials, 49, 6806–6816 (2020),  (Impact Factor: 1.676).
33. , Shihab Ahammed, Md. Sherajul Islam, Imon Mia, Jeongwon Park, Nanotechnology, 31, 505702 (2020) (Impact Factor 3.399).
34. , Md. Sherajul Islam, Ashraful Hossain Howlader, Khalid N. Anindya, Rongkun Zhen, Jeongwon Park, Akihiro Hashimoto, Journal of Applied Physics, 128, 045108 (2020); (Impact Factor: 2.328) .
35. , Ranjana Rautela, Samantha Scarfe, Jean-Michel Guay, Petr Lazar, Martin Pykal, Saied Azimi, Cedric Grenapin, Justin Boddison-Chouinard, Alexei Halpin, Weixiang Wang, Lukasz Andrzejewski, Ryan Plumadore, Jeongwon Park, Jean-Michel Menard, Michal Otyepka, and Adina Luican-Mayer, ACS Appl. Mater. Interfaces, 12, 39764−39771 (2020), (Impact Factor: 8.33).
36. , Khalid N.Anindya, Md Sherajul Islam, Akihiro Hashimoto, and Jeongwon Park, Carbon, 168, 22-31 (2020), (Impact Factor 9.59), 
37. , Mohamad Al Sabbagh, Mustapha C. E. Yagoub, Jeongwon Park, International Journal of RF and Microwave Computer-Aided Engineering, 30, e22291 (2020), (Impact Factor: 1.528).
38. , Md. Sherajul Islam, Biswajit Dey, Md. Masud Rana, A.S.M. Jannatul Islam, Jeongwon Park and Takayuki Makino, AIP Advances, 10, 065331 (2020), DOI: 10.1063/5.0007087 (Impact Factor: 1.579).
39. , A. S. M. Jannatul Islam, Sherajul Islam,   Naim Ferdous,   Jeongwon Park  and  Akihiro Hashimoto, Physical Chemistry Chemical Physics, 22, 13592-13602 (2020), (Impact factor: 3.567).
40. , Sherajul Islam , Shahrukh Sadman, A. S. M. Jannatul Islam, and Jeongwon Park, AIP Advances 10, 035202 (2020) (Impact Factor: 1.579).
41. , Khalid N.Anindy, Md Sherajul Islam, Jeongwon Park, Ashraful G.Bhuiyan, Akihiro Hashimoto, Current Applied Physics, 20 (4), 572-581 (2020), (Impact Factor: 2.010).
42. , Sherajul Islam, A. S. M. Jannatul Islam, Orin Mahamud, Arnab Saha, Naim Ferdous, Jeongwon Park, and Akihiro Hashimoto, AIP Advances 10, 01511 (2020), (Impact Factor. 1.579).
43. , ASM Jannatul Islam, Md. Sherajul Islam, Naim Ferdous, J Park, A G Bhuiyan, Akihiro Hashimoto, Res. Express 6 125073 (2019), (Impact Factor 1.449).
44. , A S M Jannatul Islam, Md Sherajul Islam, Naim Ferdous, Jeongwon Park, A G Bhuiyan and Akihiro Hashimoto, Nanotechnology, 30, 445707 (2019), (Impact Factor 3.399).
45. , Asmaul Smitha Rashid, Md. Sherajul Islam, Naim Ferdous Khalid N. Anindya, Jeongwon Park, Akihiro Hashimoto, Journal of Computational Electronics, 18(3), 836-845 (2019), (Impact Factor 1.637).
46. , Trevor M. Grant, Brendan Mirka, Nicholas T. Boileau, Jeongwon Park, and Benoît Lessard, Advanced Electronic Materials, 1900087 (2019), (Impact Factor 6.593).
47. ,  Scott Johnston, Edwin Ng, Scott W. Fong, Walter Y. Mok, Jeongwon Park, Peter Zalden, Anne Sakdinawat, H.-S. Philip Wong, Hideo Mabuchi, and Zhi-Xun Shen, Appl. Phys. Lett.114, 093106 (2019), (Impact factor‎: ‎3.521).
48. , Naim Ferdous, Md. Sherajul Islam, Jeongwon Park, Hashimoto, AIP Advances 9, 025120 (2019), (Impact Factor. 1.579).
49. , D.-J. Kim and J. Park, Plasma Res. Express 1, 015015 (2019).
50. , Y. Yoonand J. Park, Nanotechnology 29, 165705 (2018), (Impact Factor 3.399).
51. , Duk-jae Kim, Park, Jeon-gun Han, Japan. J. of Appl. Phys., 55, 085102 (2016), (Impact Factor: 1.471).
52. , D.-J. Kim, Y.-K. Shim, Park, H.-J. Kim, J.-G. Han, Japan. J. of Appl. Phys., 55(4), 040302 (2016), (Impact Factor. 1.471).
53. , Patrick Wilhite, Anshul A. Vyas, Jason Tan, Jasper Tan, Toshishige Yamada, Phillip Wang, Jeongwon Park, and Cary Y. Yang, Sci. and Tech. 29, 054006, 1- 16 (2014): Selected by the journal’s Editorial Board as a Highlight of 2014.
54. , E. Royer, J. Park, C. Colesniuc, J. S. Lee, T. Gredig, S. Jin, I. K. Schuller, W. C. Trogler, A. C. Kummel, J. Vac. Sci. Technol. B 28, C5F22 (2010).
55. , Park, J. E. Royer, C. Colesniuc, F. I. Bohrer, A. Sharoni, S. Jin, I. K.Schuller, W. C. Trogler, A. C. Kummel, J. Appl. Phys. 106, 034505 (2009).
56. , Nickel, Copper, Zinc, and Metal-Free Phthalocyanine Chemiresistors, F. I. Bohrer, C. N. Colesniuc, Park, M. E. Ruidiaz, I. K. Schuller, A. C. Kummel, W. C. Trogler, J. Am. Chem. Soc., 131(2), 478-85 (2009).
57. , D. Yang, J. Park, C. N. Colesniuc, I. K. Schuller, J. E. Royer, W. C. Trogler, and A. C. Kummel, J. Chem. Phys. 130 164703 (2009).
58. , J. Park, L.-H. Chen, D. Hong, C. Choi, M. Loya, K. Brammer, P. Bandaru and S. Jin, Nanotechnology 20, 015303 (2009).
59. , Loya, J. Park, L. H. Chen, K. S. Brammer, P. R. Bandaru and S. Jin, Nano. 3, 449–454(2008).
60. , J. Park, R. D. Yang, C. N. Colesniuc, A. Sharoni, S. Jin, I. K. Schuller, W. C. Trogler and A. C. Kummel, Appl. Phys. Lett. 92, 193311 (2008).
61. , F. I. Bohrer, C.N. Colesniuc, J.  Park, I. K. Schuller, A. C. Kummel, and W. C. Trogler, J. Am. Chem. Soc., 130 (12), 3712 -3713, (2008).
62. , R. Yang, J. Park, C. N. Colesniuc, I. K. Schuller, W. C. Trogler and A. C. Kummel, J. Appl. Phys. 102, 034515 (2007).
63. , R. D. Yang, T. Gredig, C. N. Colesniuc, J.  Park, I. K. Schuller, W. C. Trogler, and A. C. Kummel, Appl. Phys. Lett. 90, 263506 (2007), also accepted to the Virtual Journal of Nanoscale Science & Technology, (2007).
64. , F. I. Bohrer, Sharoni, C. Colesniuc, J. Park, I. K. Schuller, A. C. Kummel, and W. C. Trogler, J. Am. Chem. Soc., 129 (17), 5640 -5646 (2007).
65. , C. Soci, A. Zhang, B. Xiang, S. A. Dayeh, D. P. R. Aplin, J. Park, X. Y. Bao, Y. H. Lo, and D. Wang, Nano Lett., 7 (4), 1003 -1009 (2007).
66. , P.R. Bandaru, J. Park, J.S. Lee, Y.J. Tang, L. H. Chen, S. Jin, S.A. Song, and J. O'Brien, Appl. Phys. Lett. 89, 112502 (2006).
67. , J.  Park, C. Daraio, S. Jin, P.R. Bandaru, J. Gaillard and A. M. Rao, Appl. Phys. Lett. 88, 243113 (2006).
68. , D. Yang, B. Fruhberger, J. Park, A. C. Kummel, Appl. Phys. Lett. 88, 074104 (2006).
69. , A. Miller, R. D. Yang, M. J. Hale, J. Park, B. Fruhberger, I. K. Schuller, A. C. Kummel, William C. Trogler, J. Phys. Chem. B; 110(1) 361 - 366 (2006).
70. , J. Park, D.-J. Kim, Y.-K. Kim, K.-H. Lee, K.-H. Lee, H. Lee, and S. Ahn, Thin Solid Films, 435, 102-107 (2003).
71. , S.-H. Yang, S. Lee, J. Park, J.-Y. Kim and J.-W. Park, J. Korean Phys. Soc., 35, S361-364 (1999).
72. , S.-H. Yang, J.  Park, J.-Y. Kim, Y.-K. Lee, B.-R. Cho, D.-K. Park, W.-H. Lee and J.-W. Park, Microchemical Journal, 63 (1), 161-167 (1999).
73. , J. Park, S.-H. Yang and J.-W. Park, Korean J. Material Research, 9 (12), 1211- 1215 (1999)
74. , J. Park, S.-H. Yang, S. Lee, S. Sohn, K. Oh and J.-W. Park, J. Korea Vacuum Society, 7 (4), 368-373 (1998).
75. , S. Lee, D. J. Kim, S.-H. Yang, J. Park, S. Shon, K. Oh, Y.-T. Kim, J-Y. Kim, G.-Y. Yeom and J.-W. Park, J. Appl. Phys, 85, 473-477 (1998).

Patents / Technology disclosures:

1. J. Griffith, J. Park, P. Narwankar, N. Nguyen, H. Nguyen, T. Chan, J. Xu, Methods and apparatus for cleaning substrate surfaces with atomic hydrogen, CN104025264A, US20130160794, WO2013096748 A1, US20150311061 (2015).
2. J. Park, J. Griffith, P. Narwankar, M. Narasimhan, B. Zheng, Methods and apparatus for cleaning substrate structures with atomic hydrogen, WO 2014100047 A1 (2014).
3. J. Park, J. Cruz, P. Narwankar, Methods for removing photoresist from substrates with atomic hydrogen, WO 2014164493 A1 (2014).
4. J. Park, J. Cruz, P. Narwankar, Methods and apparatus for processing germanium containing material, a III-V compound containing material, or a II-VI compound containing material disposed on a substrate using a hot wire source, US 20140179110 (2014).
5. S. Chatterjee, J. Park, Methods for cleaning a surface of a substrate using a hot wire chemical vapor deposition (HWCVD) chamber, US 20120312326 A1 (2011).
6. A. Kummel, J. Park, Multi-rate resist method to form organic TFT contact and contacts formed by same, US20110108815 (2009).

Conference proceedings:

1. High-Efficiency Multi Quantum Well Blue LED Using 2D-SiC as an Active Material, 2021 5th International Conference on Electrical Engineering and Information & Communication Technology (ICEEICT) Military Institute of Science and Technology (MIST), Dhaka-1216, Bangladesh.
2. Single Ended Computational SRAM Bit-Cell, International Symposium on Signals, Circuits and Systems (ISSCS 2019), July 11, 2019 to July 12, 2019, Iasi, Romania.
3. (Invited) Contacts with Nanocarbon Structures in Flexible Electronics, Jeongwon Park, Changjian Zhou, Cary Y. Yang, 2018 International Flexible Electronics Technology Conference (IFETC), August 7th to 9th, 2018 in Ottawa.
4. (Invited) Carbon-based Nanostructures for Flexible Electronics, Jeongwon Park, Changjian Zhou, Cary Y. Yang, IEEE International Conferences on Electron Devices and Solid-State Circuits 2018, 6 June to 8 June 2018, Shenzhen, China.
5. "(Invited) A Novel Approach to Clean Surface for High Mobility Channel Materials With in-Situ Atomic Hydrogen Clean", Park, Joe Griffith, Bo Zheng, Jerry Gelatos, Murali Narasimhan, Pravin K Narwankar, ECS Transactions, 58 (6) 275-280 (2013).
6. Electrical and Structural Analysis of CNT-Metal Contacts in Via Interconnects, P. Wilhite, A. Vyas, J. Tan, and C. Y. Yang, P. Wang, Park, H. Ai, and M. Narasimhan, ICQNM 2013: The Seventh International Conference on Quantum, Nano and Micro Technologies (2013).
7. Effects of Growth and Surface Cleaning Conditions on Strain Relaxation on SiGe Films beyond a Critical Thickness on Si (001) Substrate, Park, M. Ishii, R. Balasubramanian, Y. Kim and S. Kurpprao. ECS Transactions, 33 (6) 523-528 (2010).
8. Electrical Transport in Carbon Nanotube Y-junctions- a Paradigm for Novel Functionality at the Nanoscale, Park, C. Daraio, A. Rao, P. Bandaru, Mater. Res. Soc. Symp. Proc. Vol. 922, 0922- U11-08, Materials Research Society (2006).

Book Chapters:

1. , ISBN: 9781003043089, Chapter 6. Nanocarbons for Flexible Sensing Applications, edited by Changjian Zhou , Min Zhang and Cary Y. Yang Jenny Stanford Publishing (2020).

Courses taught

Fall 2016- Winter 2019

 Undergraduate engineering classes

• ELG 2138 Circuit Theory I (Fall 2016, Fall 2017, Fall 2018)
• ELG 2137 Circuit Theory II (Winter 2017, Winter 2018)
• ELG 3137 Fundamentals of Semiconductor Devices (Winter 2019)

Graduate engineering classes

• ELG 7132 Nanoelectronics (Winter 2018, Winter 2019)

Spring 2009- Spring 2016

Undergraduate engineering classes

• Electric Circuits I (Winter 2016)
• Introduction to Nanotechnology (Guest lecturer) for Spring 2009
• Nanoscale Science and Technology (Guest lecturer) for Fall 2009

Graduate engineering classes

• Nanoelectronics (Fall 2011, Spring 2014)
• Nanomaterials (Winter 2011, Winter 2012, Winter 2014, Spring 2016)
• Fundamentals of Semiconductor Physics (Summer 2009, Fall 2009 and Winter 2010)