[1] K. M. M. Kabir, M. Baker, W. A. Donald, Micro- and Nanoscale Sensing of Volatile Organic Compounds for Early-stage Cancer Diagnosis, Trends in Analytical Chemistry, 153 (2022), 116655

[2] K. M. M. Kabir, E. Ahmed, and W.A. Donald, An atmospheric pressure ion funnel with a slit entrance for enhancing signal and resolution in high resolution differential ion mobility mass spectrometry, Analyst, 147 (2022), 870-879

[3] J. Mastellone, K.M.M. Kabir, X. Huang, W.A. Donald, Separation of disaccharide epimers, anomers and connectivity isomers by high resolution differential ion mobility mass spectrometry, Analytica Chimica Acta, 1206(2022) 339783

[4] Q. Liu, E. Ahmed, K. M. M. Kabir, X. Huang, D. Xiao, J. Fletcher and W. A. Donald, Pulsed Nanoelectrospray Ionization Boosts Ion Signal in Whole Protein Mass Spectrometry, Applied Sciences, 11 (2021), 10883

[5] J. D. Zhang, M. J. Baker, Z. Liu, K. M. M. Kabir et al., Medical diagnosis at the point-of-care by portable high-field asymmetric waveform ion mobility spectrometry: A systematic review and meta-analysis, Journal of Breath Research, 15 (2021), 046002

[6] Y. M. Sabri, A. E. Kandjani, C. J. Harrison, S. R. Sarker, A. Chalkidis, V. E. Coyle, G. Matthews, S. Ippolito, K. M. M. Kabir and M. Srinivasan, Gold nanorods self-assembly on quartz crystal microbalance: An enhanced mercury vapor sensor, Environmental Science: Nano, 8 (2021), 3273-3281

[7] E. Ahmed, D. Xiao, K.M.M. Kabir, J. Fletcher, W.A. Donald, Ambient Pressure Ion Funnel: Concepts, Simulations, and Analytical Performance, Analytical Chemistry, 92(2020) 15811-7

[8] R. Abbasi, M. Mayyas, M. B. Ghasemian, F. Centurion, J. Yang, M. Saborio, F.-M. Allioux, J. Han, J. Tang, M. J. Christoe, K.M.M. Kabir, K. Kalantar-Zadeh and M. A. Rahim, Photolithography–enabled direct patterning of liquid metals, Journal of Materials Chemistry C, 8(2020) 7805-11

[9] J.D. Zhang, M.T. Donor, A.D. Rolland, M.G. Leeming, H. Wang, A.J. Trevitt, K.M.M. Kabir, J.S. Prell, W.A. Donald, Protonation isomers of highly charged protein ions can be separated in FAIMS-MS, International Journal of Mass Spectrometry, 457(2020) 116425

[10] K.M.M. Kabir, D. Jampaiah, A. E. Kandjani, M. Mullett, J. Tardio, Y. M. Sabri, S. K. Bhargava, Cold vapor integrated quartz crystal microbalance (CV-QCM) based detection of mercury ions with gold nanostructures. Sensors and Actuators B: Chemical 290 (2019), 453-458

[11] D. L. Winter, J. Mastellone, K. M. M. Kabir, M. R. Wilkins and W. A. Donald, Separation of Isobaric Mono- and Dimethylated RGG-Repeat Peptides by Differential Ion Mobility-Mass Spectrometry, Analytical Chemistry 91(2019), 11827-11833

[12] E.Ahmed, K.M.M. Kabir, H. Wang, D. Xiao, J. Fletcher, W. A. Donald, Rapid separation of isomeric perfluoroalkyl substances by high-resolution differential ion mobility mass spectrometry. Analytica chimica acta, 1058 (2019), 127-135

[13] J.D. Zhang, K.M.M. Kabir, W.A. Donald, Metal-ion free chiral analysis of amino acids as small as proline using high-definition differential ion mobility mass spectrometry, Analytica Chimica Acta, 1036, 172-8, 2018

[14] J. D. Zhang, K. M. M. Kabir, W. A. Donald, Chiral Recognition of Amino Acid Enantiomers Using High-Definition High Field Asymmetric Waveform Ion Mobility Mass Spectrometry, International Journal of Mass Spectrometry, vol. 428, 1-7, 2018

[15] B. Lay, A.E. Kandjani, K.M.M. Kabir, P. Hartley, Y.M. Sabri, S.K. Bhargava, Gas sensing performance enhancement: Determining the role of active sites through colloidal lithography, Sensors and Actuators B: Chemical, 273, 1376-84, 2018

[16] K.M.M. Kabir, W.A. Donald, Cancer breath testing: a patent review, Expert Opinion on Therapeutic Patents, vol. 28, 227-239, 2018

[17] K. E. Donald, K. M. M. Kabir, W. A. Donald, Tips for reading patents: A concise introduction for scientists, Expert Opinion on Therapeutic Patents, vol. 28, 4, 277–280, 2018

[18] K.M.M. Kabir, S.J. Ippolito, A.E. Kandjani, Y.M. Sabri, S.K. Bhargava, Nano-engineered surfaces for mercury vapor sensing: Current state and future possibilities, Trends in Analytical Chemistry, vol. 88, pp. 77-99, 2017

[19] K.M.M. Kabir, W.A. Donald, Microscale differential ion mobility spectrometry for field deployable chemical analysis, Trends in Analytical Chemistry, 97, 399-427, 2017

[20] Y.M. Sabri*, K.M.M. Kabir*, A.E. Kandjani, S.K. Bhargava, Studying the effect of dealloying Cu-Au nanostructures on their mercury sensing performance, Sensors and Actuators B: Chemical, 245 (2017) 273-281 (*YMS and KMMK are co-first authors)

[21] B. Lay, A.E. Kandjani, M.H. Amin, K.M.M. Kabir, S.J. Ippolito, Y.M. Sabri, S.K. Bhargava, Galvanic replacement of colloidal monolayer crystal on a QCM device for selective detection of mercury vapor, Sensors and Actuators B: Chemical, vol. 250, pp. 383-392

[22] K.M.M. Kabir, A.E. Kandjani, C.J. Harrison, S.J. Ippolito, Y.M. Sabri, S.K. Bhargava, A real-time comparison of mercury accumulation on noble metal thin films using gravimetric device, Superlattices and Microstructures, vol. 100, pp. 1151-1158, 2016

[23] K. M. M. Kabir, B. Lay, A. E. Kandjani, Y. M. Sabri, S. J. Ippolito, and S. K. Bhargava, A nanoengineered surface acoustic wave device for analysis of mercury in gas phase, Sensors and Actuators B: Chemical, vol. 234, pp. 562-572, 2016

[24] K. M. M. Kabir, Y. M. Sabri, L. Myers, I. Harrison, E. Boom, V. E. Coyle, et al., Investigating the cross-interference effects of alumina refinery process gas species on a SAW based mercury vapor sensor, Hydrometallurgy, 170, 51-7, 2016

[25] K. M. M. Kabir, Y. M. Sabri, B. Lay, S. J. Ippolito, and S. K. Bhargava, A silver electrode based surface acoustic wave (SAW) mercury vapor sensor: a physio-chemical and analytical investigation, RSC Advances, vol. 6, pp. 36362-36372, 2016

[26] K. M. M. Kabir, Y. M. Sabri, A. E. Kandjani, S. J. Ippolito, and S. K. Bhargava, Development and comparative investigation of Ag-sensitive layer based SAW and QCM sensors for mercury sensing applications, Analyst, vol. 141, pp. 2463-2473, 2016

[27] K. M. M. Kabir, G. I. Matthews, Y. M. Sabri, S. P. Russo, S. J. Ippolito, and S. K. Bhargava, Development and experimental verification of a Finite Element Method for accurate analysis of Surface Acoustic Wave device, Smart Materials & Structures, vol. 25, p. 035040, 2016

[28] Y. M. Sabri, K. M. M. Kabir, E. Boom, S. Rosenberg, S. J. Ippolito, and S. K. Bhargava, Mercury detection in real industrial flue gas using a nanostructured quartz crystal microbalance, Industrial & Engineering Chemistry Research, 55, 7661–7668, 2016

[29] S.K. Soni, K.M.M. Kabir, R. Babarao, V.E. Coyle, S. Sarkar, Y.M. Sabri, S.K. Bhargava, A QCM-based 'on-off' mechanistic study of gas adsorption by plasmid DNA and DNA-[Bmim][PF6] construct, RSC Advances, vol. 6, pp. 81318-81329, 2016

[30] K. M. M. Kabir, Y. M. Sabri, G. I. Matthews, L. A. Jones, S. J. Ippolito, and S. K. Bhargava, Selective detection of elemental mercury vapor using a surface acoustic wave (SAW) sensor, Analyst, vol. 140, pp. 5508-5517, 2015

[31] K. M. M. Kabir, S. J. Ippolito, G. I. Matthews, S. B. Abd Hamid, Y. M. Sabri, and S. K. Bhargava, Determining the Optimum Exposure and Recovery Periods for Efficient Operation of a QCM Based Elemental Mercury Vapor Sensor, Journal of Sensors, vol. 2015, p. 7, 2015

[32] K. M. M. Kabir, Y. M. Sabri, G. I. Matthews, S. J. Ippolito, and S. K. Bhargava, Cross sensitivity effects of volatile organic compounds on a SAW-based elemental mercury vapor sensor, Sensors and Actuators B: Chemical, vol. 212, pp. 235-241, 2015

[33] K. M. M. Kabir, Y. M. Sabri, A. E. Kandjani, G. I. Matthews, M. R. Field, A. Nafady, et al., Mercury sorption and desorption on gold: A comparative analysis of surface acoustic wave and quartz crystal microbalance-based sensors, Langmuir, vol. 31 (30), pp. 8519–8529, 2015

[34] M. J. Griffin, K. M. M. Kabir, V. E. Coyle, A. E. Kandjani, Y. M. Sabri, S. J. Ippolito, et al., A Nanoengineered Conductometric Device for Accurate Analysis of Elemental Mercury Vapor, Environmental Science & Technology, vol. 50, pp. 1384-1392, 2016. (MJI and KMMK are co-first authors)

[35] P. Larki, Y. M. Sabri, K. M. M. Kabir, A. Nafady, A. E. Kandjani, and S. K. Bhargava, Silver/Gold Core/shell nanowire monolayer on a QCM microsensor for enhanced mercury detection, RSC Advances, vol. 5, pp. 92303-92311, 2015

Publications – Book Chapter

[1] J.D. Zhang, K. M. M. Kabir, W.A. Donald, Ion-Mobility Mass Spectrometry for Chiral Analysis of Small Molecules, Comprehensive Analytical Chemistry, Elsevier, 2018

Publications – Conference Papers

[1] K. M. M. Kabir, S. J. Ippolito, Y. M. Sabri, L. Myers, I. Harrison, S. K. Bhargava, et al., "Study of Ammonia and Acetaldehyde interference on a SAW based mercury vapour sensor for alumina refinery processes," presented at the 10th Alumina Quality Workshop, Perth, Western Australia, 2015.

[2] C. J. Harrison, G. I. Matthews, S. J. Ippolito, K. M. M. Kabir, and Y. M. Sabri, "Simultaneous multi-mode analysis of surface acoustic wave device temperature stability utilizing time-frequency methods," in Ultrasonics Symposium (IUS), 2015 IEEE International, 2015, pp. 1-4.

[3] K. M. M. Kabir, S. J. Ippolito, Y. M. Sabri, C. J. Harrison, G. Matthews, and S. K. Bhargava, "A comparison of Surface Acoustic Wave (SAW) and Quartz Crystal Microbalance (QCM) based sensors for portable, online mercury vapour sensing," in Chemeca 2014, Australia, 2014.