Laser Spectroscopy and Plasma Lab (LSPL)

Professor Wang's Research Group

Department of Physics and Astronomy, Mississippi State University

 2022

    1. Yukai Ai, Chuji WangYong-Le PanGorden Videen,  Characterization of single fungal aerosol particles in a reactive atmospheric environment using time-resolved optical trapping-Raman spectroscopy (OT-RS)Environmental Science: Atmospheres2, 591-600 (2022). DOI: 1039/D2EA00030J(Front cover).

    2. Haifa Alali, Yukai Ai, Yong-le PanGorden VideenChuji WangA Collection of Molecular Fingerprints of Single Aerosol Particles in Air for Potential Identification and Detection Using Optical Trapping-Raman Spectroscopy, Molecules, 27(18), 5966 (2022). https://doi.org/10.3390/molecules27185966.

    3. Yong-Le PanKevin AptowiczJessica Arnold, Samuel, ChengAimable KalumeP PiedraChuji WangReview of elastic light scattering from single aerosol particles and application in bioaerosol detectionJournal of Quantitative Spectroscopy and Radiative Transfer279, 108067 (2022).

    4. Rongrong Wu, Pedro J. Castro, Cameron Gaito, Kyle Beiter, Theodore S. Dibble, Chuji WangCombined Experimental and Computational Kinetics Studies for the Atmospherically Important BrHg Radical Reacting with NO and O2Phys. Chem. A, 126, 24, 3914–3925 (2022) doi.org/10.1021/acs.jpca.2c02531.

    5. Yong-Le Pan, Aimable Kalume, Jessica Arnold, Leonid Beresnev, Chuji Wang, Danielle N. Rivera, Kevin K. Crown, and Joshua Santarpia, Measurement of circular intensity differential scattering (CIDS) from single airborne aerosol particles for bioaerosol detection and identificationOptics Express, 30,1442-1451(2022). https://doi.org/10.1364/OE.448288.


      2021

    6. Jessica A. Arnold, Aimable Kalume, Chuji Wang, Gorden Videen, and Yong-Le Pan, Active, controlled circular, and spin-rotational movement of optically trapped airborne micro-particles Opt. Lett. 46, 5332-5335 (2021)

    7. Viral Shah, Daniel J Jacob, Colin P Thackray, Xuan Wang, Elsie M Sunderland, Theodore S Dibble, Alfonso Saiz-Lopez, Ivan Černušák, Vladimir Kellö, Pedro J Castro, Rongrong Wu, and Chuji Wang, Improved mechanistic model of the atmospheric redox chemistry of mercury, Environmental Science & Technology, PMID : 34724789. DOI.10.1021/acs.est.1c03160. (2021)

    8. Chuji Wang, Yong-Le Pan, and Gorden Videen, Optical trapping and laser-spectroscopy measurements of single particles in air: A review, Measurement Science and Technology, 32(10), 102005 (2021).

    9. Aimable Kalume, Chuji Wang, and Yong-Le Pan, Optical-trapping laser techniques for characterizing airborne aerosol particles and its application in chemical aerosol study, Micromachines, 12(4), 466 (2021).

    10. Yukai Ai, Haifa Alali, Yongle Pan, Gorden Videen, and Chuji Wang, Single-particle optical-trapping raman spectroscopy for the detection and identification of aerosolized airborne biological particles, Measurement Science and Technology, 32(5), 055207 (2021).

    11. Yong-Le Pan, Aimable Kalume, Chuji Wang, and Joshua Santarpia, Atmospheric aging processes of bioaerosols under laboratory-controlled conditions: A review, Journal of Aerosol Science, 155, 105767 (2021).


      2020
    12. Rongrong Wu, Chuji Wang, and Theodore S. Dibble, First experimental kinetic study of the atmospherically important reaction of BrHg + NO2, Chemical Physics Letters, 759, 137928 (2020).

    13. Yukai Ai, Jing Li, Qingyuan Li, Meixiu Sun, Yingxin Li, and Chuji Wang, Cavity ringdown spectroscopy of nitric oxide in the ultraviolet region for human breath test, Journal of Breath Research, 14(3), 037101 (2020).

    14. Haifa Alali, Zhiyong Gong, Gorden Videen, Yong-Le Pan, Olga Muñoz, and Chuji Wang, Laser spectroscopic characterization of single extraterrestrial dust particles using optical trapping-cavity ringdown and raman spectroscopy, Journal of Quantitative Spectroscopy and Radiative Transfer, 255, 107249 (2020).

    15. Che A. Fuh and Chuji Wang, Measurement of OH(X) in the microwave plasma-assisted ignition of methane/air mixture by cavity ringdown spectroscopy, IEEE Transactions on Plasma Science, 48(7), 2646-2652 (2020).


      2019
    16. Nimisha Srivastava and Chuji Wang, Effect of N2 and O2 on OH radical production in an atmospheric helium microwave plasma jet, Plasma Science and Technology, 21, 115401 (2019).

    17. Zhiyong Gong, Yong-Le Pan, Gorden Videen, and Chuji Wang, Chemical reactions of single optically trapped bioaerosols in a controlled environment, Aerosol Science and Technology, 53, 853-859 (2019).

    18. Zhiyong Gong, Yong-Le Pan, Gorden Videen, and Chuji Wang, Online characterization of single airborne carbon nanotube particles using optical trapping raman spectroscopy, Applied Spectroscopy, 73, 910-916 (2019).

    19. Yong-Le Pan, Aimable Kalume, Isaac C. D. Lenton, Timo A. Nieminen, Alex B. Stilgoe, Halina Rubinsztein-Dunlop, Leonid A. Beresnev, Chuji Wang, and Joshua L. Santarpia, Optical-trapping of particles in air using parabolic reflectors and a hollow laser beam, Optics Express, 27, 33061-33069 (2019).


      2018
    20. Zhiyong Gong, Yong-Le Pan,  Gorden Videen, and Chuji Wang, Optical trapping and manipulation of single particles in air: Principles, technical details, and applications, Journal of Quantitative Spectroscopy and Radiative Transfer, 214, 94–119 (2018) (Invited).

    21. Zhiyong Gong, Yong-Le Pan, Gorden Videen, and Chuji Wang, Optical trapping-Raman spectroscopy (OT-RS) with embedded microscopy imaging for concurrent characterization and monitoring of physical and chemical properties of single particles, Analytica Chimica Acta, 1020, 86–94 (2018).

    22. Maheshwar Ghimire, Chuji Wang, Kenneth Dixon, Michael Serrato, In situ monitoring of prestressed concrete using embedded fiber loop ringdown strain sensor, Measurement, 124, 224-232 (2018).

    23. Chenyu Jiang, Meixiu Sun, Yingxin Li, Chuji Wang, Breath analysis using laser spectroscopy techniques: development and future, Chinese Journal of Lasers, 45(2): 0207015-19 (2018). (Invited)

    24. Qiangu Yan, Xuefeng Zhang, Jinghao Li, El Barbary Hassan, Chuji Wang, Jilei Zhang, Zhiyong Cai, Catalytic conversion of Kraft lignin to bio-multilayer graphene materials under different atmospheres, Journal of Materials Science, 53, 8020-29 (2018).

    25. Qiangu Yan, Jinghao Li, Xuefeng Zhang, El Barbary Hassan, Chuji Wang, Jilei Zhang, Zhiyong Cai, Catalytic graphitization of kraft lignin to graphene-based structures with four different transitional metals, Journal of Nanoparticle Research 20, 223-42 (2018).

    26. Che A. Fuh, Chuji Wang, A Novel Combustion Platform for Microwave Plasma-Assisted Combustion Studies, IEEE Transactions on Plasma Science, 46, 1800-1808, (2018)

    27. Yong-Le Pan, Aimable Kalume, Chuji Wang, Joshua L Santarpia, Opto-aerodynamic focusing of aerosol particles, Aerosol Science and Technology, 52, 13-18 (2018).

    28. Aimable Kalume, Chuji Wang, Joshua Santarpia, and Yong-Le Pan, Liquid–liquid phase separation and evaporation of a laser-trapped organic–organic airborne droplet using temporal spatial-resolved Raman spectroscopy, Physical Chemistry Chemical Physics, 20, 19151 (2018).

    29. Aimable Kalume, Chuji Wang, Joshua Santarpia, and Yong-Le Pan, Study of single airborne particle using laser-trapped submicron position-resolved temporal Raman spectroscopy, Chemical Physics Letters, 706, 255-260 (2018).


      2017


    30. Aimable Kalume, Eric Zhu, Chuji Wang, Joshua Santarpia, Yong-Le Pan, Position-resolved Raman spectra from a laser-trapped single airborne chemical droplet, Optics letters, 42(24), 5113-5116 (2017).

    31. Zhiyong Gong, Yong-Le Pan, Gorden Videen, and Chuji Wang, The temporal evolution process from fluorescence bleaching to clean Raman spectra of single solid particles optically trapped in air, Chemical Physics Letter, 689, 100-104 (Dec. 2017) (Front Cover).

    32. Che A. Fuh, Wei Wu, and Chuji Wang, A parametric study of the microwave plasma-assisted combustion of premixed ethylene/air mixtures. The European Physical Journal D, 71 (11), 302 (2017) doi: 10.1140/epjd/e2017-80259-6.

    33. Maheshwar Ghimire, Hong Guo, Junpeng Guo, and Chuji Wang, Surface plasmon-based fiber loop ringdown sensor, Sensor Letters, 15 (7), 565-569 (2017).

    34. Zhennan Wang, Meixiu Sun, Xiaomeng Zhao, Chenyu Jiang, Yingxin Li, and Chuji Wang, Study of breath acetone in a rad mode of 126 rats with type I diabetes, Journal of Analytical and bioanalytical techniques, DOI: 10.4172/2155-9872.1000344, 2017.

    35. Maheshwar Ghimire and Chuji Wang, Highly sensitive fiber loop ringdwon strain sensor with low temperature sensitivity, Measurement Science and Technology 28 (10), 105101 (2017).

    36. Yong-Le Pan, Aimable Kalume, Chuji Wang, and Joshua L. Santarpia, Opto-aerodynamic focusing of aerosol particles, Aerosol Science and Technology 1, 1-6 (2017).

    37. Gangbing Song, Chuji Wang, and Bo Wang, Structural Health Monitoring (SHM) of Civil Structures, Applied Sciences (editorial) 7(8), 789 (2017).

    38. Zhiyong Gong, Yong-Le Pan, and Chuji Wang, Characterization of single airborne particle extinction using the tunable optical trap-cavity ringdown spectroscopy (OT-CRDS) in the UV, Optics Express 25(6), 6732-6745 (2017).

    39. Yong-Le Pan, Chuji Wang, Leonid A. Beresnev, Alex J. Yuffa, Gorden Videen, David Ligon, and Joshua L. Santarpia, Measurement of back-scattering patterns from single laser trapped aerosol particles in air, Applied Optics 56(3), B1-B4 (2017).

    40. Richard Fu, Chuji Wang, Olga Muñoz, Gorden Videen, Joshua L. Santarpia, Yong-Le Pan, Elastic back-scattering patterns via particle surface roughness and orientation from single trapped airborne aerosol particles, Journal of Quantitative Spectroscopy and Radiative Transfer, 187, 224-231 (2017) http://dx.doi.org/10.1016/j.jqsrt.2016.09.018.


      2016


    41. Che A. Fuh, Shane M. Clark, Wei Wu, and Chuji Wang, Electronic ground state OH(X) radical in a low-temperature atmospheric pressure plasma jet. Journal of Applied Physics 120, 163303 (2016).

    42. Haifa Alali, and Chuji Wang, Fiber loop ringdown humidity Sensor. Applied Optics 55(31), 8938-8945 (2016).

    43. Zhiyong Gong, Yong-Le Pan, and Chuji Wang, Optical configurations for photophoretic trap of single particles in air. Review of Scientific Instruments 87(10), 103104(2016).

    44. Chuji Wang, Zhiyong Gong, Yong-Le Pan, and Gorden Videen. Laser pushing or pulling of absorbing airborne particles. Applied Physics Letters 109(1), 011905(2016).

    45. Che A Fuh, Wei Wu, and Chuji Wang, Microwave plasma-assisted ignition and flameholding in premixed ethylene/air mixtures. J. of Physics D: Applied Physics, 49, 285202(2016).

    46. Zhennan Wang, Meixiu Sun, and Chuji Wang, Detection of melanoma cancer biomarker Dimethyl Disulfide using cavity ringdown spectroscopy at 266 nm, Applied Spectroscopy 70(6), 1080-1085 (2016).

    47. Yong-Le Pan, Chuji Wang, Leonid A. Beresnev, Alex J. Yuffa, Gorden Videen, David Ligon, and Joshua L. Santarpia, Measurement of back-scattering patterns from single laser trapped aerosol particles in air. Applied Optics, 56(3), pp. B1-B4 (2017), doi.org/10.1364/AO.56.0000B1.

    48. Chenyu Jiang, Meixiu Sun, Zhennan Wang, Zhuying Chen, Xiaomeng Zhao, Yuan Yuan, Yingxin Li, and Chuji Wang, A portable real-time ringdown breath acetone analyzer: toward potential diabetic screening and management. Sensors (Basel), 16, 1199 (2016).


      2015


    49. Chuji Wang, Zhiyong Gong, Yong-Le Pan and Gorden Videen, Optical trap-cavity ringdown spectroscopy as a single-aerosol-particle-scope. Applied Physics Letters, 107, 241903 (2015). Featured Article

    50. Peeyush Sahay, and Chuji Wang, Absolute measurements of electron impact excitation cross-sections of atoms using cavity ringdown spectroscopy. Radiation Physics and Chemistry, 106,  165–169 (2015).

    51. Meixiu Sun, Chenyu Jiang, Zhiyong Gong, Xiaomeng Zhao, Zhuying Chen, Zhennan Wang, Meiling Kang, Yingxin Li, and Chuji Wang, A fully integrated stand alone portable cavity ringdown breath acetone analyzer. Review of Scientific Instruments, 86, no. 9 095003 (2015).

    52. Meixiu Sun, Xiaomeng Zhao, Huijuan Yin, Zhennan Wang, Chenyu Jiang, Weichao Liu, Zhuying Chen, Yuan Yuan, Yingxin Li, and Chuji Wang, Study of breath acetone and its correlations with blood glucose and blood beta-hydroxybutyrate using an animal model with lab-developed type 1 diabetic rats. RSC Adv. 5, 87, 71002–71010 (2015).

    53. Chuji Wang, Yong-Le Pan, Steven C. Hill, and Brandon Redding. “Photophoretic Trapping-Raman Spectroscopy for Single Pollens and Fungal Spores Trapped in Air.” Journal of Quantitative Spectroscopy and Radiative Transfer, 153,  4–12 (2015).

    54. Wei Wu, Che A Fuh, and Chuji Wang, Plasma-enhanced ignition and flame stabilization in microwave plasma-assisted combustion of premixed methane/oxygen/argon mixtures. IEEE Transactions on Plasma Science, 9 (2015).

    55. Brandon Redding, Steven C. Hill, Dimitri Alexson, Chuji Wang, and Yong-Le Pan, Photophoretic trapping of airborne particles using ultraviolet illumination, Optics Express, 23, 3630-3639 (2015). Selected by the Editors, Andrew Dunn and Anthony Durkin, for publication in the Virtual Journal for Biomedical Optics (VJBO) 2015.

    56. Wei Wu, Che A. Fuh, and Chuji Wang, Comparative study on microwave plasma-assisted combustion of premixed and nonpremixed methane/air mixtures, Combustion Science and Technology, 187, 999-1020 (2015).

    57. Meixiu Sun, Zhuying Chen, Zhiyong Gong, Xiaomeng Zhao, Chenyu Jiang, Yuan Yuan, Zhennang Wang, Yingxin Li, and Chuji Wang, Determination of breath acetone in 149 Type 2 diabetic patients using a ringdown breath-acetone analyzer, Analytical and Bioanalytical Chemistry, 407, 1641-50 (2015).


      2014


    58. Haifa Alali, and Chuji Wang, Fiber loop ringdown gas flow sensors, Measurement Science and Technology, 25(11), 115102 (2014).

    59. ZY Gong, MX Sun, CY Jiang, ZN Wang, ML Kang, YX Li, and Chuji Wang, A ringdown breath acetone analyzer: Performance and validation using gas chromatography-mass spectrometry, Journal of Analytical & Bioanalytical Techniques, S7-13 (2014).

    60. Yongle Pan, Chuji Wang, Steven C. Hill, Mark Coleman, Leonid A. Beresnev, and Joshua L. Santarpia, Trapping of individual airborne absorbing particles using a counterflow nozzle and photophoretic trap for continuous sampling and analysis, Applied Physics Letters, 104(11), 113507(2014).

    61. Brandon Redding, Yong-Le Pan, Chuji Wang, and Hui Cao, Polarization-resolved near-backscattering of airborne aggregates composed of different primary particles, Optics Letters, 39(14), 4076-4079 (2014).

    62. Peeyush Sahay, and Chuji Wang, Absolute measurements of electron impact excitation cross-sections of atoms using cavity ringdown spectroscopy, Radiation Physics and Chemistry, 106, 165-169, Online 2014, doi:10.1016/j.radphyschem.2014.07.005

    63. Chuji Wang, Yong-Le Pan, and Mark Coleman, Experimental observation of particle cones formed by optical trapping, Optics Letters, 39(9), 2767-2770 (2014).

    64. Chuji Wang, Yong-Le Pan, Steven C. Hill, and Brandon Redding, Photophoretic trapping-Raman spectroscopy for single pollens and fungal spores trapped in air, Journal of Quantitative Spectroscopy and Radiative Transfer, online 15 November 2014(2014),153,4-12(2015),doi:10.1016/j.jqsrt.2014.11.004

    65. Chuji Wang, Yong-Le Pan, Deryck James, Alan E. Wetmore, and Brandon Redding, Direct on-strip analysis of size- and time-resolved aerosol impactor samples using laser induced fluorescence spectra excited at 263 and 351 nm, Analytica Chimica Acta, 820, 119-132 (2014).

    66. Chuji Wang, and Wei Wu, Roles of the state-resolved OH(A) and OH(X) radicals in microwave plasma assisted combustion of premixed methane/air: An exploratory study, Combustion and Flame, 161(8), 2073-2084 (2014).

    67. Zhennan Wang, Chuji Wang, and Patty Lathan, Breath acetone analysis of diabetic dogs using a cavity ringdown breath analyzer, Sensors Journal IEEE, 14(4), 1117-1123 (2014).

    68. Chuji Wang, Fiber Loop Ringdown Sensors and Sensing, Cavity-Enhanced Spectroscopy and Sensing, 2014 – Springer.


      2013


    69. Chuji Wang and Wei Wu, Simultaneous measurements of OH(A) and OH(X) radicals in microwave plasma jet assisted combustion of methane/air mixtures around the lean-burn limit using optical emission spectroscopy and cavity ringdown spectroscopy, Journal Physics D: Applied Physics. 46, 464008 (2013).

    70. Chuji Wang, Malik Kaya, Peeyush Sahay, Haifa Alali, and Robert Reese, Fiber optic sensors and sensor networks using a time-domain sensing scheme, Optics and Photonics Journal, 3, 236-239 (2013)

    71. Peeyush Sahay, Susan T. Scherrer andChuji Wang, Measurements of the Weak UV Absorptions of Isoprene and Acetone at 261–275 nm Using Cavity Ringdown Spectroscopy for Evaluation of a Potential Portable Ringdown Breath Analyzer, Sensors 13, 8170-8187 (2013).

    72. Zennan Wang and Chuji Wang, Is breath acetone a biomarker of diabetes—a historical review on breath acetone measurements, Journal of Breath Research, 7, 037109 (2013)

    73. Zhennan Wang, Chuji Wang, and Patty Lathan, Breath Acetone Analysis of Diabetic Dogs Using a Cavity Ringdown Breath Analyzer, IEEE Sensors Journal, 99, 1-5 (2013)

    74. Peeyush Sahay, Malik Kaya, and Chuji Wang, Fiber loop ringdown sensor for potential real-time monitoring of cracks in concrete structures: An exploratory study, Sensors, 13, 39-57 (2013)

    75. Chuji Wang, Fiber loop ringdown sensors and sensor network, an invited book chapter for Cavity Enhanced Spectroscopy and Sensing, Springer. Springer Series in Optical Sciences Volume 179, 2014, pp 411-461. ISBN: 978-3-642-40002-5 (online 2013, print 2014)

    76. Chuji Wang, Cavity ringdown spectroscopy of plasma species, an invited book chapter for Low Temperature Plasma Technology: Methods and Applications, Publisher: CRC Press; 1 edition. ISBN-10: 1466509902. (July 12, 2013)


      2012


    77. Malik Kaya, Peeyush Sahay, and Chuji Wang, Reproducibly reversible fiber loop ringdown water sensor embedded in concrete and grout for water monitoring, Sensors and Actuators B, 176, 803-10 (2012).

    78. Peeyush Sahay, Susan T. Scherrer, and Chuji Wang, A portable OES-CRDS dual-mode plasma spectrometer for measurements of environmentally important trace heavy metals: initial test of elemental Hg, Review Scientific Instrument, 83, 095109-095122 (2012).

    79. Chuji Wang, Malik Kaya, and Charlotte Wang, Evanescent field fiber loop ringdown glucose sensor, Journal of Biomedical Optics. 17(3), 037004-13 (2012).

    80. Chuji Wang, Susan T. Scherrer, and Peeyush Sahay, Electron impact excitation-cavity ringdown absorption spectrometry of elemental mercury at 405 nm, Journal of Analytical Atomic Spectrometry, 27, 284-292 (2012).


      2011


    81. Nimisha Srivastava and Chuji Wang, Effects of addition of trace water on OH radical generation and plasma properties in an atmospheric argon microwave plasma jet, Journal of Applied Physics, 110, 053304-13 (2011).

    82. Chuji Wang, Peeyush Sahay, and Susan T. Scherrer, A New optical method of measuring electron impact excitation cross section of atoms: cross section of the metastable 6s6p 3P0 level of Hg, Physics Letters A, 375, 2366-70 (2011).

    83. C. Herath, Chuji Wang, M. Kaya, and D. Chevalier, Fiber loop ringdown DNA and bacteria sensors, Journal of Biomedical Optics Letters, 16, 050501-3 (2011).

    84. Nimisha Srivastava and Chuji Wang, Determination of OH radicals in an atmospheric pressure helium microwave plasma jet, IEEE Transaction on Plasma Science, 39, 918-24 (2011).

    85. Yicheng Du, Chuji Wang, Hossein Toghiani, Zhiyong Cai, Xiaojian Liu, Jilei Zhang, and Qiangu Yan, Synthesis of carbon-encapsulated metal nanoparticles from wood char, Forest Prod. J. 60(6):527–533 (2011).


      2010


    86. Du, Y., J. Zhang, Chuji Wang, T. E. Lacy, Y. Xue, H. Toghiani, M. F. Horstemeyer, and C. U. Pittman. Kenaf bast fiber bundle-reinforced unsaturated polyester composites IV: water resistance and composite mechanical properties improvement, Forest Products Journal, 60(4), 366–372 (2010).

    87. Chuji Wang and Nimisha Srivastava, Cavity ringdown spectroscopic measurements of OH number densities in atmospheric microwave plasma jets operating with different plasma gases (Ar, Ar/N2, and Ar/O2), European Physical Journal D: Atomic, Molecular, Optical and Plasma Physics, 60, 465-477 ( 2010).

    88. Chuji Wang and Chamini Herath, Fabrication and characterization of fiber loop ringdown evanescent field sensors, Measurement Science and Technology, 21, 08205-15 (2010).

    89. Chuji Wang and Chamini Herath, High-sensitivity fiber-loop ringdown evanescent field index sensors using single-mode fiber, Optics Letters, 35, 1629-1631 (2010).

    90. Chuji Wang, Armstrong Mbi, and Mark Shepherd, A study on breath acetone in diabetic patients using a cavity ringdown breath analyzer: Exploring correlations of breath acetone with blood glucose and glycohemoglobin A1C, IEEE Sensors Journal, 10, 54 – 63, (2010). (2011 Best Paper Award).


      Before 2010


    91. Chuji Wang, Fiber loop ringdown--a time-domain sensing technique for multi-function fiber optic sensor platforms: current status and design perspectives, Sensors, 9(10), 7595-7621 (2009) (Invited contribution to a special issue (Physical Sensors) by Guest Editor, Dr. Markus W. Sigrist, ETH Zürich, Institute for Quantum Electronics, Basel, Switzerland).

    92. Chuji Wang and Peeyush Sahay, Breath analysis using high-sensitivity laser spectroscopic techniques: breath biomarkers, spectral finger prints, and detection limits, Sensors, 9, 8230-8262 (2009) (Invited contribution to a special issue (Chemical Sensors) by Guest Editor, Dr. JinJun Shi, Massachusetts Institute of Technology).

    93. Chuji Wang, Nimisha Srivastava, and Theodore S. Dibble, Observation and quantification of OH radicals in the far downstream part of an atmospheric microwave plasma using cavity ringdown spectroscopy, Applied Physics Letters, 95, 051501-3 (2009).

    94. Nimisha Srivastava, Chuji Wang, and Theodore S. Dibble, A study of OH radicals in an atmospheric AC discharge plasma using near infrared diode laser cavity ringdown spectroscopy combined with optical emission spectroscopy, European Physical Journal D: Atomic, Molecular, Optical and Plasma Physics, 54, 77-86 (2009).

    95. Chuji Wang, Nimisha Srivastava, Susan Scherrer, Ping-Rey Jang, Theodore S. Dibble, and Yixiang Duan, Optical diagnostics of a low power - low gas flow rates atmospheric-pressure argon plasma created by a microwave plasma torch, Plasma Sources Science and Technology, 18, 025030-41 (2009) (11 pages).


    96. Chuji Wang, George P. Miller, Christopher B. Winstead, Book Chapter: Cavity Ringdown Laser Absorption Spectroscopy. Encyclopedia of Analytical Chemistry, R. A. Meyers (Ed.), John Wiley & Sons, 2008 (20 pages). PDF Book Chapter (Invited)
    97. Chuji Wang and Anand B Surampudi, An acetone breath analyzer using cavity ringdown spectroscopy: an initial test with human subjects under various situations, Measurement Science and Technology, 19, 105604-14 (2008). (selected as Highlighted Article of the journal in 2008).

    98. Chuji Wang, N. Srivastava, B.A. Jones, R.B. Reese, A novel multiple species ringdown spectrometer for in situ measurements of methane, carbon dioxide, and carbon isotope, Applied Physics B, 92, 259-70 (2008). PDF

    99. Chuji Wang and A Mbi, A new acetone detection device using cavity ringdown spectroscopy at 266 nm: evaluation of the instrument performance using acetone sample solutions. Measurement Science and Technology, 18, 2731-2741(2007).

    100. Chuji Wang, Plasma-cavity ringdown spectroscopy (P-CRDS) for elemental and isotopic measurements. Journal of Analytical Atomic Spectrometry, 22, 1347-63 (2007) (Invited, featured on the front cover of the journal, issue 11th). PDF

    101. P. Cias, Chuji Wang, and T. S. Dibble, Absorption cross-sections of the C-H overtone of volatile organic compounds: 2 methyl-1,3-butadiene (Isoprene), 1,3-butadiene, and 2,3-dimethyl-1,3-butadiene. Applied Spectroscopy, 61, 230-236 (2007).

    102. F-X Han, Jeff S. Lindner, and Chuji Wang, Making carbon sequestration a paying proposition. Naturwissenschaften, 94, 170-182 (2007).

    103. Armstrong Mbi and Chuji Wang, Optical superposition in double fiber loop ringdown. Proc. of SPIE 6377, 6377021-8 (2006) (8 pages). (Invited).

    104. Chuji Wang and Armstrong Mbi, An alternative method to develop fibre grating temperature sensors using the fibre loop ringdown scheme. Measurement Science and Technology, 17(7), 1741-1751 (2006).

    105. Chuji Wang, Susan T. Scherrer, Yixiang Duan, and Christopher B. Winstead, Cavity ringdown measurements of mercury and its hyperfine structures at 254 nm in an atmospheric microwave plasma: spectral interference and analytical performance. Journal of Analytical Atomic Spectrometry 20(7), 638-644 (2005). (Hot Article).

    106. Yixiang Duan, Chuji Wang, Susan T. Scherrer, and Christopher B. Winstead, Development of alternative plasma sources for cavity ring-down measurements of mercury. Analytical Chemistry, 77(15), 4883-4889 (2005).

    107. Yixiang Duan, Susan T. Scherrer, Sudip P. Koirala, Chuji Wang, and Christopher B. Winstead, Uranium emission spectra with a low power microwave plasma source. Analytica Chimica Acta, 532(1), 47-54 (2005).

    108. Chuji Wang, Fiber ringdown temperature sensors. Optical Engineering Letters, 44(3), 030503-5 (2005).

    109. Chuji Wang, Sudip P. Koirala, Susan T. Scherrer, Yixiang Duan, and Christopher B. Winstead, Diode laser microwave induced plasma cavity ringdown spectrometer: Performance and perspective. Review of Scientific Instruments, 75(5), 1305-13 (2004).

    110. Chuji Wang and Susan T. Scherrer, Fiber loop ringdown for physical sensor development: pressure sensor. Applied Optics, 43(35), 6458-64 (2004).

    111. Chuji Wang and Susan T. Scherrer, Fiber ringdown pressure sensors. Optics Letters, 29(4), 352-4 (2004). PDF

    112. Chuji Wang, Susan T. Scherrer, and D. Hossain, Measurements of cavity ringdown spectroscopy of acetone in the ultraviolet and near-infrared spectral regions: Potential for development of a breath analyzer. Applied Spectroscopy, 58(7), 784-791 (2004).

    113. Chuji Wang, Fabio J. Mazzotti, Sudip P. Koirala, Christopher B. Winstead, and George P. Miller, Measurements of OH radicals in a low-power atmospheric inductively coupled plasma by cavity ringdown spectroscopy. Applied Spectroscopy, 58(6), 734-740 (2004).

    114. Chuji Wang, Christopher B. Winstead, Yixiang Duan, Susan T. Scherrer, Sudip P. Koirala, Ping-Rey Jang, George P. Miller, and Fabio J. Mazzotti, Plasma cavity ringdown spectrometer for elemental and isotopic measurements: Past, present and future. Environmental Chemistry, 44(1), 518-522 (2004).

    115. Yixiang Duan, Chuji Wang, and Christopher B. Winstead, Exploration of microwave plasma source cavity ring-down spectroscopy for elemental measurements. Analytical Chemistry, 75(9), 2105-2111 (2003).

    116. Chuji Wang, Fabio J. Mazzotti, George P. Miller, and Christopher B. Winstead, Isotopic measurements of uranium using inductively coupled plasma cavity ringdown spectroscopy. Applied Spectroscopy, 57(9), 1167-1172 (2003).

    117. Chuji Wang, Fabio J. Mazzotti, George P. Miller, and Christopher B. Winstead, Cavity ringdown spectroscopy for diagnostic and analytical measurements in an inductively coupled plasma. Applied Spectroscopy, 56(3), 386-397 (2002).

    118. Chuji Wang, Wei Deng, Liat G. Shemesh, Michael D. Lilien, David R. Katz, and Theodore S. Dibble, Observation of Fluorescence Excitation Spectra of tert-Pentoxy and 3-Pentoxy Radicals. Journal of Physical Chemistry A, 104(45), 10368-10373 (2000).

    119. Deng W, Chuji Wang, David. R. Katz, G. R. Gawinski, A. J. Davis, and Theodore S. Dibble, Direct kinetic studies of the reactions of 2-butoxy radicals with NO and O2. Chemical Physical Letters, 330, 541-5 (2000).

    120. Chuji Wang, Liat G. Shemesh, Wei Deng, Michael D. Lilien, and Theodore S. Dibble, Laser-Induced Fluorescence Excitation Spectra of tert-Butoxy and 2-Butoxy Radicals. Journal of Physical Chemistry A, 103(41), 8207-8212 (1999).

    121. Chuji Wang, Yingsheng Xiao, Qin Ran, Congxiang Chen, Shuqin Yu, and Xingxiao Ma, Laser-induced fluorescence excitation spectra of supersonic jet-cooled CF2. Chinese Journal of Chemical Physics, 11(1), 31-36 (1998).

    122. Chuji Wang, Yingsheng Xiao, Congxiang Chen, Shuqin Yu, and Xingxiao Ma, Laser-induced fluorescence excitation spectra of supersonic jet-cooled SO2 1A21A1. Chinese Journal of Chemical Physics, 11(6), 542-547 (1998).

    123. Chuji Wang, Congxiang Chen, Jinghua Dai, and Xingxiao Ma, Laser-induced fluorescence studies of jet-cooled CF2: determination of A-state stretching frequencies. Chemical Physics Letters, 288 (2,3,4), 473-480 (1998).

    124. Limin Zhang, Jun Chen, Jinghua Dai, Chuji Wang, Tao Zhang, Congxiang Chen, and Xingxiao Ma, Multiphoton dissociation and ionization of CS2 in the range 242-260 nm. Chinese Journal of Physical Chemistry, 14(11), 1007-1012 (1998).

    125. Chuji Wang, Jun Chen, Tao Zhang, Limin Zhang, Jinghua Dai, Congxiang Chen, and Xingxiao Ma, Rotational analyses of laser-induced fluorescence excitation spectra of the supersonic jet-cooled SO2(~A 1A2-~X 1A1) system. Wuli Xuebao, 47(8), 1258-1264 (1998).

    126. Chuji Wang, Jian Wang, and Xingxiao Ma, Theoretical treatment of radiation trapping of atomic fluorescence in V-E energy transfer. Wuli Xuebao, 47(2), 198-207 (1998).

    127. Chuji Wang, Yingsheng Xiao, Qin Ran, Yiwei Chu, Congxing Chen, Shuqin Yu, and Xingxiao Ma, Determination of A-state stretching frequencies of CF2 radical. Chinese Journal of Physical Chemistry, 13(4), 297-300 (1997).

    128. Jian Wang, Chuji Wang, Re Lai, and Xingxiao Ma, Validity of detail balance in hyperfine structure with radiation trapping. Chinese Journal of Quantum Electronics, 14(1)1, 18-22 (1997).

    129. Chuji Wang, Yingshen Xiao, Qin Ran, Yiwei Chu, Congxiang Chen, Shuqin Yu, and Xingxiao Ma, Measurement of A-state stretching frequencies of CF2 radical. Chinese Acta Physico-chimica Sinica, 13, 297-302 (1997).

    130. Yang Chen, Jinian Shu, Chuji Wang, Congxiang Chen, Shuqin Yu, and Xingxiao Ma, Laser-induced fluorescence excitation spectrum of C3 cooled in a supersonic free jet. Chinese Journal of Chemical Physics, 9(4), 287-292 (1996).

    131. Jian Wang, Chuji Wang, Re Lai, and XingXiao Ma, Detailed balance in hyperfine structure with radiation trapping. Zeitschrift fuer Physik D: Atoms, Molecules and Clusters, 38(2), 113-117 (1996).