Jun Ma

Research Interests

Chemical Engineering Composite and Hybrid Materials Materials Engineering Mechanical Engineering Nanotechnology Polymers and Plastics

Prof Jun Ma

Professor of Materials Engineering

School of Chemical Engineering

College of Engineering and Information Technology

Eligible to supervise Masters and PhD - email supervisor to discuss availability.

Available For Media Comment.

I received my PhD degree in Materials Processing in 2002. I then conducted research as a visiting scholar and postdoc fellow at the Centre for Advanced Materials Technology, The University of Sydney. I joined the University of South Australia as a lecturer in 2007.
2012–2013: Academic Integrity Officer, School of Engineering, UniSA
2015–2019: Research Coordinator, School of Engineering, UniSA
2018–2020: Member, UniSA Academic Board

I am a member of the Australian Research Council's (ARC) College of Experts.
My research focuses on the development of applied functional (nano)composites through processing engineering materials with a range of cost-effective, safe nanomaterials, aiming to engage with industry in the design, development and manufacturing of advanced composite materials. For example, I researched with a plastic manufacturing plant in New South Wales, which resulted in commissioning of a plastic compounding system in June 2015. As another example, my team developed a novel stretchable strain sensor (‘Highly Sensitive, Wearable, Durable Strain Sensors and Stretchable Conductors Using Graphene/Silicon Rubber Composites’, Advanced Functional Materials, 2016, 42, 7614; an HiCi paper). Thanks to the financial support from ARC (LP160100717), my team was able to translate this strain sensor research into industry by manufacturing a prototype real-time idler condition monitoring system for industrial belt conveyors, which was delivered to a Perth-based industrial partner in 2018.
My research interests and past projects involve (i) the development of composites with specific functionalities through processing engineering materials with cost-effective, safe nanomaterials, and (ii) the investigation of the structure–property relations and fracture mechanisms of these composites. I pioneered the development of (i) polymer/nanosheet composites by molecular entanglements (‘A new strategy to exfoliate silicone rubber/clay nanocomposites’, Macromolecular Rapid Communications, 2005, 26, 830; ‘Interface-tuned epoxy/clay nanocomposites’, Polymer, 2011, 52, 497) and interface bonding (‘A novel method for preparation of disorderly exfoliated epoxy/clay nanocomposite’, Chemistry of Materials, 2004, 16, 757),  (ii) cost-effective few-layer graphene (also named graphene nanoplatelets; ‘A facile approach to chemically modified graphene and its polymer nanocomposites’, Advanced Functional Materials, 2012, 22, 2735) for composites processing (‘Graphene Platelets and Their Polymer Composites: Fabrication, Structure, Properties, and Applications’, Advanced Functional Materials, 2018, 28, 1706705), and (iii) facile processing for polymer/nanosheet composites (‘Epoxy/graphene platelets nanocomposites with two levels of interface strength’, Polymer, 2011, 52, 1603; an HiCi paper). My research on these topics has resulted in over 160 refereed journal papers, and a complete, most updated publication list is at Google Scholar.
To-date I as the lead Chief Investigator have attained a research income of $2,891,150; my total research income is over seven million dollars. Below is a list of my major projects.
15) ARC Linkage Project (LP240200755, 2025–2029, $300,420), titled ‘Mechanically Resilient Elastomer/Cellulose Nanofibre Composites’. Sole Chief Investigator: J. Ma. Partner Investigator: G. Schroeder.
14) ARC Linkage Project (LP230100229, 2024–2027, $395,773), titled ‘Flame-Retarding and Mechanically Resilient Elastomer Composites’. Sole Chief Investigator: J. Ma. Partner Investigator: H.C. Kuan.
13) ARC LIEF Project (LE240100129, 2024–2025, $530,721), titled ‘State-of-the-art atomic force microscopy facilities for South Australia’. Chief Investigators: A. Blencowe; M. Krasowska; C.X. Zhao; Y. Zheng; C. Gibson; C. Priest; D. Losic; S. Harmer; J. Ma; Y. Jiao; D. Beattie; C. Shearer; P. Sharma
12) ARC Discovery Project (DP230100688, 2023–2026, $501,504) titled ‘Creating pH-sensitive self-healing concrete using sludge waste for sewers’. Chief Investigators: Y. Zhuge; C.M. Wang; J. Ma; S.J. Chen.
11) ARC LIEF Project (LE230100018, 2023–2024, $2,206,421), titled ‘A customized surface chemistry study system in realistic working condition’. Chief Investigators: Z. Guo; S. Qiao; H. Ebendorff-Heidepriem; C. Sumby; S. Zhang; I. Gentle; W. Skinner; M. Krasowska; A. Blencowe; J. Ma; S. Li; R. Marceau; G. Andersson; D. Jones.
10) ARC Discovery Project (DP220103275, 2022–2025, $210,000) titled ‘Fundamentals of Electrically Conductive Elastomer Composites’. Sole Investigator: J. Ma.
9) ARC Linkage Project (LP200100617, 2021–2024, $215,000), titled ‘Elastomer/Graphene Composites for Reinforcement at Low Strain’. Sole Chief Investigator: J. Ma. Partner Investigators: S.A. Gouda; G. Schroeder.
8) ARC Discovery Project (DP200101737, 2020–2023, $350,000) titled ‘A Novel Approach to Polymer/Nanosheet Composites and Their Fundamentals’. Lead Chief Investigator: J. Ma. Other Chief Investigators: A. Mouritz; H.C. Kuan.
7) ARC Linkage Project (LP180100005, 2019–2022, $330,000) titled ‘High-Performance Polymer Composites for Electrical Discharging’. Lead Chief Investigator: J. Ma. Other Chief Investigators: Y.Y. Zhang; H.C. Kuan
6) ARC LIEF Project (LE180100129, 2017–2018, $425,200), titled ‘Atomic layer nanofabrication system for multi-functional applications’. Chief Investigators: G. Wang; A. McDonagh; B. Sun; R. Zheng; G. Smith; K.F. Aguey-Zinsou; J Ma; Y Chen; M. Cortie; H. Liu; W.K. Pang.
5) ARC Linkage Project (LP160100717, 2016–2020, $229,000), titled ‘Electrically Conductive Elastomeric Compo­sites by Nanomaterials’. Sole Chief Investigator: J. Ma. Partner Investigators: C. Stevenson; L.Q. Zhang.
4) ARC Industrial Transformation Research Hubs 2015 (IH150100003, 2016–2021, $2,611,346), titled ‘ARC Research Hub for Graphene Enabled Industry Transformation’. Chief Investigators: D. Losic; E. Skafidas; M. Majumder; C. Fumeaux; N. Choudhury; A. Nirmalathas; M. McLaughlin; J. Ma; R. Ghomashchi; Y. Zhong.
3) ARC Linkage Project (LP140100605, 2014–2018, $225,000), titled ‘Strong and Durable Flame-Retarding Composites by Multi-scale Encapsulation and Reinforcement’. Lead Chief Investigator: J. Ma. Other Chief Investigators: C.H. Wang; A.P. Mouritz; H.C. Kuan; J. Xu.
2) AutoCRC Project (2009–2012, $100,000), ‘The Development of Advanced Adhesives based upon Nano-additives’. Investigators: J. Ma; Q.S. Meng; R. Short; P. Murphy.
1) ARC Discovery Project (DP0666261, ARC-APD Fellowship, 2006–2010, $285,000), ‘The development of super-toughened epoxies using novel nanomaterials’. Chief Investigator: J. Ma.

  • ARC-APD Awards in 2006
  • ResearchSA Fellowship in 2009
  • Excellence in Research and Teaching awarded in 2011 by UniSA
  • ‘Certified Materials Professional’ by Materials Australia
  • Professional Member of Society of Plastics Engineers
  • Chair for the 2018 International Symposium of Advanced Composite Technology, South Australia
  • My team created four HiCi papers:

1) Zaman, J. Ma*, et al. Epoxy/graphene platelets nanocomposites with two levels of interface strength, Polymer 2011, 52, 1603–11. (Highly cited paper since the date of publication)

2) Z. Sun, J. Ma, S. Zhu*, et al. A high-performance Bi2WO6/graphene photocatalyst for visible light-induced H2 and O2 generation, Nanoscale 2014, 6, 2186–93.  (Highly cited paper since the date of publication)

3) S. Araby, J. Ma*, et al. Implication of multi-walled carbon nanotubes on polymer/graphene composite. Materials & Design 2015, 65, 690–9.  (Highly cited paper; 12/2015 – 06/2016)

4) G. Shi, J. Ma*, et al. Highly Sensitive, Wearable, Durable Strain Sensors and Stretchable Conductors Using Graphene/Silicon Rubber Composites. Advanced Functional Materials 2016, 26, 7614-25. (Highly cited paper since the date of publication)

My research has been in the field of engineering materials processing and composites, including nanosheet synthesis and modification, novel methods for the preparation of nanocomposites, polymer synthesis, materials processing and the structure–property identification of nanocomposites. My team have the following research directions.

1) Nanosheet synthesis and modification

2) Novel methods for the development of polymer/nanosheet composites

3) Investigation of the structure–property relations of nanocomposites

4) Elastomer nanocomposites for stretchable/flexible strain sensors and conductors

5) Cement nanocomposites

6)  Nanocomposites for energy applications

7) Flame-retarding polymer composites

 

Date Institution name Country Title
1999 Chinese Academy of Sciences China Doctor of Philosophy

Year Citation
2026 Meng, Q., Liu, S., Yu, Y., Gong, X., Wang, B., Ma, J., & Han, S. (2026). UV-Curable, Self-Healing and Rigid Polyurethane-Urea Acrylate Elastomers Reinforced with Zirconium Phosphate Nanosheets. ACS Applied Polymer Materials, 8(4), 2815-2830.
DOI
2026 Jia, Q., Zhuge, Y., Liu, Y., Su, X., & Ma, J. (2026). Mechanochemical synthesis and interfacial binding analysis of chitosan/alum sludge composite particles. Sustainable Materials and Technologies, 47, e01931.
DOI
2025 Jia, H., Zhang, J., Hou, Y., Pan, Y., Liu, C., Shen, C., . . . Liu, X. (2025). Bio-mass radiative cooling materials: progress and prospects. Advanced Sustainable Systems, 9(2, article no. 2400773), 1-16.
DOI Scopus5 WoS5
2025 Chen, F., Gao, F., Guo, X., Liao, L., Gao, X., Shen, L., & Ma, J. (2025). Enhancing polyacrylate covalent adaptable networks through dynamic protection and deprotection strategies for highly reactive functional monomers. Chemical Engineering Journal, 507, 1-11.
DOI Scopus3 WoS3
2025 Su, X., Lee, S. H., Hou, Y., Stanford, N., Meng, Q., Kuan, H. C., . . . Ma, J. (2025). Mechanochemically modified graphene nanoplatelets for high-performance polycarbonate composites. Smart Materials in Manufacturing, 3(100072), 1-9.
DOI Scopus3 WoS2
2025 Hu, W. Y., Cao, C. F., Chen, Z. Y., Hu, W. J., Yang, S., Yu, B., . . . Tang, L. C. (2025). Translucent MXene oxide-based bilayered nanocoating on woods for integrated active and passive fire safety. Small Structures, 6(7, article no. 2400630), 1-14.
DOI Scopus3 WoS2
2025 Zhao, Y., Zhang, H., Zhu, X., Wang, M., Shen, D., Fu, C., & Ma, J. (2025). Stable waterborne epoxy resins: impact of toughening agents on coating properties. Smart Materials in Manufacturing, 3(100079), 1-12.
DOI Scopus9 WoS9
2025 Tran, L. C., Su, X., Nguyen, H., La, L. B. T., Adu, P., Jia, Q., . . . Ma, J. (2025). Advancing polymer nanocomposites through mechanochemical approaches. Advanced Nanocomposites, 2, 86-107.
DOI
2025 Fan, M., Hou, Y., Jia, H., Pan, Y., Qu, M., Liu, C., . . . Liu, X. (2025). Sustainable radiative cooling of microstructure modulated flexible poly(lactic Acid) films. Langmuir, 41(31), 20768-20777.
DOI Scopus1 WoS1
2025 Hou, Y., Pan, Y., Liu, X., Ma, J., Liu, C., & Shen, C. (2025). Structural bioplastic metafilm for durable passive radiative cooling. Cell Reports Physical Science, 6(7, article no.102664), 1-12.
DOI Scopus6 WoS6
2025 Liu, X., Zhang, H., Pan, Y., Ma, J., Liu, C., & Shen, C. (2025). Transparent polymer-composite film for window energy conservation. Nano-Micro Letters, 17(1, article no. 151), 1-17.
DOI Scopus23 WoS23 Europe PMC5
2025 Nguyen, H. H., Tran, L. C., La, L. B. T., Su, X., Meng, Q., Kuan, H. C., & Ma, J. (2025). A novel water-based mechanochemical approach for surface modification of graphene platelets and their epoxy nanocomposites. Polymer Composites, 46(1), 735-748.
DOI Scopus3 WoS3
2025 Gao, Z., Wang, Y., Pan, Y., Ma, J., Liu, X., Liu, C., & Shen, C. (2025). Moisture-wicking fabric for radiation cooling. Nano Research, 18(10, article no. 94907537), 1-10.
DOI Scopus6 WoS5
2025 Qiao, Y. P., Chen, S. J., Wang, C. M., Zhuge, Y., & Ma, J. (2025). New classification, historical developments, technology readiness level and application conditions of self-healing concrete technologies. Journal of Building Engineering, 108(112869), 29 pages.
DOI Scopus2 WoS2
2025 Chi Tran, L., Hong Nguyen, H., Su, X., Dai, J., Lee, I., Losic, D., . . . Ma, J. (2025). An eco-friendly approach for graphene nanoplatelets by innovative wet thermal expansion and liquid-phase exfoliation. Applied Surface Science, 681(161497), 161497-1-161497-9.
DOI Scopus8 WoS7
2025 Yu, Y., Xu, L., Liu, S., Gu, G., Chen, Y., Yuan, H., . . . Ma, J. (2025). Eco-friendly, mechanically robust, weather-resistant and rapidly cured polyurea elastomer synthesized by vat photopolymerization 3D printing. Composites Part A: Applied Science and Manufacturing, 196(108985), 1-11.
DOI Scopus2 WoS3
2025 Feng, Q. H., Liu, J., Shen, Y. B., Cao, C. F., Hu, W. Y., Liu, T. T., . . . Tang, L. C. (2025). Semi-transparent, mechanically flexible, water-resistant, and flame-retardant sodium alginate/montmorillonite-based nanocomposite for fire alarm and protection. Composites Part A: Applied Science and Manufacturing, 190(108662), 1-11.
DOI Scopus21 WoS19
2024 Yu, Y., Xu, Z., Xu, L., Li, Y., Liu, T., Meng, Q., . . . Ma, J. (2024). Highly stretchable, sensitive and healable polyurethane-urea/graphene nanocomposite sensor for multifunctional applications. Thin-Walled Structures, 198(111660), 1-13.
DOI Scopus7 WoS6
2024 Sanaei Ataabadi, H., Liu, Y., Ma, J., Zeng, J. J., Huang, G., & Zhuge, Y. (2024). An innovative sludge-derived capsule for self-healing cementitious materials. Journal of Cleaner Production, 480(144120), 13 pages.
DOI Scopus4 WoS3
2024 Yap, P. L., Nguyen, H. H., Ma, J., Gunawardana, M., & Losic, D. (2024). Exploring kinetic and thermodynamic insights of graphene related two dimensional materials for carbon dioxide adsorption. Separation and Purification Technology, 348(127633), 127633-1-127633-12.
DOI Scopus32 WoS29
2024 Yap, P. L., Nguyen, H. H., Nine, M. J., Ma, J., Gunawardana, M., & Losic, D. (2024). Advancing carbon dioxide capture: Unravelling structure-property-performance dynamics in graphene related two-dimensional materials. Materials Today Sustainability, 27(100834), 100834-1-100834-17.
DOI Scopus8 WoS7
2024 Yang, Y., Ma, J., Yang, J., & Zhang, Y. (2024). Graphene/h-BN hybrid van der Waals structures with high strength and flexibility: a nanoindentation investigation. Thin-Walled Structures, 195(111341), 1-11.
DOI Scopus19 WoS19
2024 Yang, Y., Ma, J., Yang, J., Wei, N., & Zhang, Y. (2024). Tuning cross-plane thermal conductivity of multilayer graphene/h-BN vdW heterostructures via composition distribution. International Journal of Heat and Mass Transfer, 231(125808), 1-9.
DOI Scopus6 WoS6
2024 Zhang, Q., Cheng, H., Zhang, S., Li, Y., Li, Z., Ma, J., & Liu, X. (2024). Advancements and challenges in thermoregulating textiles: smart clothing for enhanced personal thermal management. Chemical Engineering Journal, 488(151040), 1-15.
DOI Scopus48 WoS44
2024 La, L. B. T., Nguyen, H., Tran, L. C., Su, X., Meng, Q., Kuan, H. C., & Ma, J. (2024). Exfoliation and dispersion of graphene nanoplatelets for epoxy nanocomposites. Advanced Nanocomposites, 1(1), 39-51.
DOI
2024 Su, X., Yang, Z., Cheng, R., Luvnish, A., Han, S., Meng, Q., . . . Ma, J. (2024). A comparative study of polycarbonate nanocomposites respectively containing graphene nanoplatelets, carbon nanotubes and carbon nanofibers. Advanced Nanocomposites, 1(1), 77-85.
DOI
2024 Lee, S. H., Luvnish, A., Su, X., Meng, Q., Liu, M., Kuan, H. C., . . . Ma, J. (2024). Advancements in polymer (Nano)composites for phase change material-based thermal storage: a focus on thermoplastic matrices and ceramic/carbon fillers. Smart Materials in Manufacturing, 2(100044), 1-11.
DOI Scopus25 WoS19
2024 Adu, P. C. O., Aakyiir, M., Su, X., Alam, J., Tran, L. C., Dai, J., . . . Ma, J. (2024). Challenges and advancements in Elastomer/CNT nanocomposites with mechanochemical treatment, reinforcement mechanisms and applications. Smart Materials in Manufacturing, 2(100053), 1-18.
DOI Scopus15 WoS13
2024 Jiang, Q., Cai, Y., Sang, X., Zhang, Q., Ma, J., & Chen, X. (2024). Nitrogen-doped carbon materials as supercapacitor electrodes: a mini review. Energy and Fuels, 38(12), 10542-10559.
DOI Scopus60 WoS59
2024 Zhao, Y., Guo, X., Gao, F., Fu, C., Shen, L., & Ma, J. (2024). Advancing next-generation polymers: through self-strengthening via mechanochemistry. European Polymer Journal, 218, 1-12.
DOI Scopus4 WoS4
2024 Meng, F., Meng, Q., Guo, F., Alam, J., & Ma, J. (2024). Bismuthene nanosheets prepared by an environmentally friendly method and their thermoelectric epoxy nanocomposites. Advanced Industrial and Engineering Polymer Research, 7(2), 226-233.
DOI Scopus7 WoS6
2024 Hou, Y., Su, X., & Ma, J. (2024). Advanced transparent composite membranes for efficient ultraviolet protection and thermal regulation. Science Bulletin, 69(18), 2799-2801.
DOI Scopus2 WoS3
2023 Yuan, W., Su, X., Dai, J., Han, S., Chelliah, S. S., Adu, P., . . . Ma, J. (2023). Removing hazardous additives from elastomer manufacturing. Smart Materials in Manufacturing, 1, 100021-1-100021-11.
DOI Scopus2 WoS3
2023 Alam, J., Xu, X., Adu, P. C. O., Meng, Q., Zuber, K., Afshar, S., . . . Ma, J. (2023). Enhancing thermoelectric performance of PEDOT: PSS: a review of treatment and nanocomposite strategies. Advanced Nanocomposites, 1(1), 16-38.
DOI
2023 Zhang, M., Su, M., Qin, Y., Liu, C., Shen, C., Ma, J., & Liu, X. (2023). Photothermal ultra-high molecular weight polyethylene/MXene aerogel for crude oil adsorption and water evaporation. 2D Materials, 10(2), 1-8.
DOI Scopus33 WoS30
2023 Han, S., Yang, F., Li, Q., Sui, G., Su, X., Dai, J., & Ma, J. (2023). Tackling smoke toxicity and fire hazards of thermoplastic polyurethane by mechanochemical combination of Cu2O nanoparticles and zirconium phosphate nanosheets. Polymer Degradation and Stability, 212(article no. 110350), 1-11.
DOI Scopus31 WoS32
2023 Han, S., Yang, F., Meng, Q., Li, J., Sui, G., Su, X., . . . Ma, J. (2023). Using renewable phosphate to decorate graphene nanoplatelets for flame-retarding, mechanically resilient epoxy nanocomposites. Progress in Organic Coatings, 182(107658), 1-12.
DOI Scopus30 WoS29
2023 Houshi, M. N., Aakyiir, M., Stephen, S., Wang, R., Kuan, H. C., Meng, Q., & Ma, J. (2023). A green and solvent-free method for simultaneously producing graphene nanoplatelets, nanoscrolls, and nanodots and functionalizing their surface for epoxy nanocomposites. Smart Materials in Manufacturing, 1(100018), 1-8.
DOI Scopus9 WoS8
2023 Yang, Y., Ma, J., Pei, Q. X., Yang, J., & Zhang, Y. (2023). Cross-plane thermal transport in multiplayer graphene/h-BN van der Waals heterostructures: the role of interface morphology. International Journal of Heat and Mass Transfer, 216(124558), 1-11.
DOI Scopus28 WoS28
2023 Meng, Q., Wang, P., Yu, Y., Liu, J., Su, X., Kuan, H. C., . . . Ma, J. (2023). Polyaspartic polyurea/graphene nanocomposites for multifunctionality: Self-healing, mechanical resilience, electrical and thermal conductivities, and resistance to corrosion and impact. Thin-Walled Structures, 189(110853), 1-13.
DOI Scopus39 WoS37
2023 Luo, X., He, X., Zhao, H., Ma, J., Tao, J., Zhao, S., . . . Zhu, S. (2023). Research progress of Polymer Biomaterials as scaffolds for corneal endothelium tissue engineering. Nanomaterials, 13(13, article no. 1976), 1-18.
DOI Scopus14 WoS15 Europe PMC10
2022 Zhang, H., Ma, J., Zhang, Y., & Yang, J. (2022). Failure mechanism of graphene kirigami under nanoindentation. Nanotechnology, 33(37, article no. 375703), 1-8.
DOI Scopus8 WoS7 Europe PMC1
2022 Yang, Y., Ma, J., Yang, J., & Zhang, Y. (2022). Molecular dynamics simulation on in-plane thermal conductivity of graphene/hexagonal boron nitride van der Waals heterostructures. ACS Applied Materials and Interfaces, 14(40), 45742-45751.
DOI Scopus49 WoS48 Europe PMC6
2022 Oh, J. A., Aakyiir, M., Liu, Y., Qiu, A., Meola, T. R., Forson, P., . . . Ma, J. (2022). Durable cement/cellulose nanofiber composites prepared by a facile approach. Cement and Concrete Composites, 125(104321), 1-13.
DOI Scopus40 WoS38
2022 Yu, H., Whittle, J. D., Losic, D., & Ma, J. (2022). Ultra-stable zinc-ion batteries by suppressing vanadium dissolution via multiple ion-bonded vanadate cathodes. Applied Physics Reviews, 9(1), 1-10.
DOI Scopus16 WoS17
2022 Aakyiir, M., Tanner, B., Yap, P. L., Rastin, H., Tung, T. T., Losic, D., . . . Ma, J. (2022). 3D printing interface-modified PDMS/MXene nanocomposites for stretchable conductors. Journal of Materials Science and Technology, 117, 174-182.
DOI Scopus31 WoS27
2022 Alosaimi, F. K., Tung, T. T., Dao, V. D., Huyen, N. K., Nine, M. J., Hassan, K., . . . Losic, D. (2022). Graphene-based multifunctional surface and structure gradients engineered by atmospheric plasma. Applied Materials Today, 27, 101486-1-101486-12.
DOI Scopus52 WoS52
2022 Yu, L., Yap, P. L., Santos, A., Tran, D., Hassan, K., Ma, J., & Losic, D. (2022). Graphene and Hexagonal Boron Nitride in Molybdenum Disulfide/Epoxy Composites for Significant X-ray Shielding Enhancement. ACS Applied Nano Materials, 5(9), 12196-12208.
DOI Scopus13 WoS13
2022 Han, S., Wang, P., Zhou, Y., Meng, Q., Aakyiir, M., & Ma, J. (2022). Flexible, mechanically robust, multifunctional and sustainable cellulose/graphene nanocomposite films for wearable human-motion monitoring. Composites Science and Technology, 230(109451), 1-8.
DOI Scopus38 WoS39
2022 Wang, S., Cao, M., Wang, G., Cong, F., Meng, Q., Uddin, M., & Ma, J. (2022). Effect of graphene nanoplatelets on water absorption and impact resistance of fibre-metal laminates under varying environmental conditions. Composite Structures, 281(114977), 1-11.
DOI Scopus20 WoS18
2022 Su, X., Wang, R., Li, X., Araby, S., Kuan, H. C., Naeem, M., & Ma, J. (2022). A comparative study of polymer nanocomposites containing multi-walled carbon nanotubes and graphene nanoplatelets. Nano Materials Science, 4(3), 185-204.
DOI Scopus109 WoS93
2021 Aakyiir, M., Kingu, M. A. S., Araby, S., Meng, Q., Shao, J., Amer, Y., & Ma, J. (2021). Stretchable, mechanically resilient, and high electromagnetic shielding polymer/MXene nanocomposites. Journal of Applied Polymer Science, 138(22, article no. e50509), 1-10.
DOI Scopus43 WoS40
2021 Cui, X., Tian, J., Zhang, C., Cai, R., Ma, J., Yang, Z., & Meng, Q. (2021). Comparative study of nanocarbon-based flexible multifunctional composite electrodes. ACS Omega, 6(4), 2526-2541.
DOI Scopus20 WoS15 Europe PMC4
2021 Araby, S., Philips, B., Meng, Q., Ma, J., Laoui, T., & Wang, C. H. (2021). Recent advances in carbon-based nanomaterials for flame retardant polymers and composites. Composites Part B: Engineering, 212(108675), 1-29.
DOI Scopus216 WoS176
2021 Meng, Q., Meng, F., Yu, Y., Alam, J., Han, S., Chen, S., & Ma, J. (2021). Preparation of antimonene nanosheets and their thermoelectric nanocomposites. Composites Communications, 28(100968), 1-9.
DOI Scopus8 WoS9
2021 Aakyiir, M., Oh, J. A., Araby, S., Zheng, Q., Naeem, M., Ma, J., . . . Mai, Y. W. (2021). Combining hydrophilic MXene nanosheets and hydrophobic carbon nanotubes for mechanically resilient and electrically conductive elastomer nanocomposites. Composites Science and Technology, 214(108997), 1-9.
DOI Scopus57 WoS54
2021 Zhang, Y., Ma, J., Wei, N., Yang, J., & Pei, Q. X. (2021). Recent progress in the development of thermal interface materials: a review. Physical Chemistry Chemical Physics, 23(2), 753-776.
DOI Scopus86 WoS82 Europe PMC12
2021 Naeem, M., Kuan, H. C., Michelmore, A., Yu, S., Mouritz, A. P., Chelliah, S. S., & Ma, J. (2021). Epoxy/graphene nanocomposites prepared by in-situ microwaving. Carbon, 177, 271-281.
DOI Scopus45 WoS39
2021 Han, S., Zhang, X., Wang, P., Dai, J., Guo, G., Meng, Q., & Ma, J. (2021). Mechanically robust, highly sensitive and superior cycling performance nanocomposite strain sensors using 3-nm thick graphene platelets. Polymer Testing, 98, 1-9.
DOI Scopus57 WoS53
2021 Meng, Q., Araby, S., Oh, J. A., Chand, A., Zhang, X., Kenelak, V., . . . Ma, J. (2021). Accurate self-damage detection by electrically conductive epoxy/graphene nanocomposite film. Journal of Applied Polymer Science, 138(20, article no. 50452), 1-12.
DOI Scopus15 WoS14
2021 Oh, J. A., Zhuge, Y., Araby, S., Wang, R., Yu, H., Fan, W., . . . Ma, J. (2021). Cement nanocomposites containing montmorillonite nanosheets modified with surfactants of various chain lengths. Cement and Concrete Composites, 116(103894), 1-9.
DOI Scopus21 WoS20
2021 Qiu, A., Jia, Q., Yu, H., Oh, J. A., Li, D., Hsu, H. Y., . . . Ma, J. (2021). Highly sensitive and flexible capacitive elastomeric sensors for compressive strain measurements. Materials Today Communications, 26(102023), 1-11.
DOI Scopus37 WoS35
2021 Yu, H., Aakyiir, M., Xu, S., Whittle, J. D., Losic, D., & Ma, J. (2021). Maximized crystal water content and charge-shielding effect in layered vanadate render superior aqueous zinc-ion battery. Materials Today Energy, 21(100757), 100757-1-100757-8.
DOI Scopus41 WoS42
2021 Liu, Y., Zhuge, Y., Chow, C. W. K., Keegan, A., Ma, J., Hall, C., . . . Wang, L. (2021). Cementitious composites containing alum sludge ash: an investigation of microstructural features by an advanced nanoindentation technology. Construction and Building Materials, 299(124286), 1-9.
DOI Scopus50 WoS46
2020 Aakyiir, M., Araby, S., Michelmore, A., Meng, Q., Amer, Y., Yao, Y., . . . Ma, J. (2020). Elastomer nanocomposites containing MXene for mechanical robustness and electrical and thermal conductivity. Nanotechnology, 31(315715), 1-14.
DOI Scopus54 WoS50 Europe PMC13
2020 Yap, P. L., Auyoong, Y. L., Hassan, K., Farivar, F., Tran, D. N. H., Ma, J., & Losic, D. (2020). Multithiol functionalized graphene bio-sponge via photoinitiated thiol-ene click chemistry for efficient heavy metal ions adsorption. Chemical Engineering Journal, 395(124965), 1-13.
DOI Scopus114 WoS104
2020 Naeem, M., Kuan, H. C., Michelmore, A., Meng, Q., Qiu, A., Aakyiir, M., . . . Ma, J. (2020). A new method for preparation of functionalized graphene and its epoxy nanocomposites. Composites Part B: Engineering, 196(article no. 108096), 108096-1-108096-10.
DOI Scopus53 WoS50
2020 Aakyiir, M., Yu, H., Araby, S., Ruoyu, W., Michelmore, A., Meng, Q., . . . Ma, J. (2020). Electrically and thermally conductive elastomer by using MXene nanosheets with interface modification. Chemical Engineering Journal, 397(97, article no. 125439), 125439-1-125439-10.
DOI Scopus101 WoS94
2020 Meng, Q., Yu, Y., Tian, J., Yang, Z., Guo, S., Cai, R., . . . Ma, J. (2020). Multifunctional, durable and highly conductive graphene/sponge nanocomposites. Nanotechnology, 31(46, article no. 465502), 1-15.
DOI Scopus27 WoS26 Europe PMC6
2020 Qiu, A., Aakyiir, M., Wang, R., Yang, Z., Umer, A., Lee, I., . . . Ma, J. (2020). Stretchable and calibratable graphene sensors for accurate strain measurement. Materials Advances, 1(2), 235-243.
DOI Scopus31 WoS29
2020 Meng, Q., Han, S., Liu, T., Ma, J., Ji, S., Dai, J., . . . Ma, J. (2020). Noncovalent modification of boron nitrite nanosheets for thermally conductive, mechanically resilient epoxy nanocomposites. Industrial & Engineering Chemistry Research, 59(47), 20701-20710.
DOI Scopus29 WoS27
2020 Meng, X., Zhang, J., Ma, J., Li, Y., Chen, Z., Liu, S., . . . Zhu, S. (2020). Using cellulose nanocrystals for graphene/hexagonal boron nitride nanosheet films towards efficient thermal management with tunable electrical conductivity. Composites Part A: Applied Science and Manufacturing, 138(106089), 1-13.
DOI Scopus17 WoS16
2020 Liu, S., Pan, J., Li, X., Meng, X., Yuan, H., Li, Y., . . . Kong, L. (2020). In situ modification of BiVO4 nanosheets on graphene for boosting photocatalytic water oxidation. Nanoscale, 12(27), 14853-14862.
DOI Scopus27 WoS25 Europe PMC8
2020 Han, S., Meng, Q., Xing, K., Araby, S., Yu, Y., Mouritz, A., & Ma, J. (2020). Epoxy/graphene film for lifecycle self-sensing and multifunctional applications. Composites Science and Technology, 198(108312), 1-10.
DOI Scopus63 WoS62
2020 Wang, R., Aakyiir, M., Qiu, A., Oh, J. A., Adu, P., Meng, Q., & Ma, J. (2020). Surface-tunable, electrically conductive and inexpensive graphene platelets and their hydrophilic polymer nanocomposites. Polymer, 205(122851), 1-8.
DOI Scopus20 WoS20
2020 Yu, H., Rouelle, N., Qiu, A., Oh, J. A., Kempaiah, D. M., Whittle, J. D., . . . Ma, J. (2020). Hydrogen bonding-reinforced hydrogel electrolyte for flexible, robust, and all-in-one supercapacitor with excellent low-temperature tolerance. ACS Applied Materials and Interfaces, 12(34), 37977-37985.
DOI Scopus137 WoS131 Europe PMC31
2020 Houshi, M. N., Aakyiir, M., & Ma, J. (2020). Low-temperature, rapid preparation of functionalized graphene platelets. Composites Communications, 22(100500), 1-6.
DOI Scopus8 WoS8
2020 Wang, R., Kuan, H. C., Qiu, A., Su, X., & Ma, J. (2020). A facile approach to the scalable preparation of thermoplastic/carbon nanotube composites. Nanotechnology, 31(19, article no. 195706), 1-10.
DOI Scopus11 WoS10 Europe PMC4
2019 Araby, S., Su, X., Meng, Q., Kuan, H. C., Wang, C. H., Mouritz, A., . . . Ma, J. (2019). Graphene platelets versus phosphorus compounds for elastomeric composites: flame retardancy, mechanical performance and mechanisms. Nanotechnology, 30(38, article no. 385703), 1-35.
DOI Scopus39 WoS37 Europe PMC10
2019 Yang, Z., Ma, J., Araby, S., Shi, D., Dong, W., Tang, T., & Chen, M. (2019). High-mass loading electrodes with exceptional areal capacitance and cycling performance through a hierarchical network of MnO₂ nanoflakes and conducting polymer gel. Journal of power sources, 412, 655-663.
DOI Scopus30 WoS30
2019 Yuan, H., Pan, H., Meng, S., Zhu, C., Liu, S., Chen, Z., . . . Zhu, S. (2019). Assembly of MnO/CNC/rGO fibers from colloidal liquid crystal for flexible supercapacitors via continuous one-process method. Nanotechnology, 30(46, article no. 465702), 1-30.
DOI Scopus30 WoS27 Europe PMC4
2019 Li, Y., Xia, M., An, F., Ma, N., Jiang, X., Zhu, S., . . . Ma, J. (2019). Superior removal of Hg (II) ions from wastewater using hierarchically porous, functionalized carbon. Journal of hazardous materials, 371, 33-41.
DOI Scopus62 WoS55 Europe PMC17
2019 Luan, R., Xu, D., Pan, H., Zhu, C., Wang, D., Meng, X., . . . Ma, J. (2019). High electrochemical cycling performance through accurately inheriting hierarchical porous structure from bagasse. Journal of energy storage, 22, 60-67.
DOI Scopus19 WoS18
2019 Qiu, A., Li, P., Yang, Z., Yao, Y., Lee, I., & Ma, J. (2019). A path beyond metal and silicon: polymer/nanomaterial composites for stretchable strain sensors. Advanced functional materials, 29(17, article no. 1806306), 1-21.
DOI Scopus218 WoS212
2019 Yang, Z., Ma, J., Bai, B., Qiu, A., Losic, D., Shi, D., & Chen, M. (2019). Free-standing PEDOT/polyaniline conductive polymer hydrogel for flexible solid-state supercapacitors. Electrochimica Acta, 322(134769), 134769-1-134769-9.
DOI Scopus162 WoS156
2018 Wu, H., Araby, S., Xu, J., Kuan, H. C., Wang, C. H., Mouritz, A., . . . Ma, J. (2018). Filling natural microtubules with triphenyl phosphate for flame-retarding polymer composites. Composites part A, 115, 247-254.
DOI Scopus27 WoS26
2018 Jones, M., Bhat, T., Kandare, E., Thomas, A., Joseph, P., Dekiwadia, C., . . . Wang, C. H. (2018). Thermal degradation and fire properties of fungal mycelium and mycelium - biomass composite materials. Scientific reports, 8(1, article no. 17583), 1-10.
DOI Scopus167 WoS131 Europe PMC48
2018 Pan, H., Wang, D., Peng, Q., Ma, J., Meng, X., Zhang, Y., . . . Zhang, D. (2018). High-performance microsupercapacitors based on bioinspired graphene microfibers. ACS applied materials and interfaces, 10(12), 10157-10164.
DOI Scopus43 WoS39 Europe PMC9
2018 Shi, G., Araby, S., Gibson, C. T., Meng, Q., Zhu, S., & Ma, J. (2018). Graphene platelets and their polymer composites: fabrication, structure, properties, and applications. Advanced functional materials, 28(19, article no. 1706705), 1-44.
DOI Scopus250 WoS239
2018 Moussa, M., El-Kady, M. F., Abdel-Azeim, S., Kaner, R. B., Majewski, P., & Ma, J. (2018). Compact, flexible conducting polymer/graphene nanocomposites for supercapacitors of high volumetric energy density. Composites Science and Technology, 160, 50-59.
DOI Scopus68 WoS54
2018 Lu, S., Shao, J., Ma, K., Chen, D., Wang, X., Zhang, L., . . . Ma, J. (2018). Flexible, mechanically resilient carbon nanotube composite films for high-efficiency electromagnetic interference shielding. Carbon, 136, 387-394.
DOI Scopus95 WoS92
2018 Yang, Z., Qiu, A., Ma, J., & Chen, M. (2018). Conducting α-Fe₂O₃ nanorod/polyaniline/CNT gel framework for high performance anodes towards supercapacitors. Composites science and technology, 156, 231-237.
DOI Scopus53 WoS51
2018 Araby, S., Wang, C. H., Wu, H., Meng, Q., Kuan, H. C., Kim, N. K., . . . Ma, J. (2018). Development of flame-retarding elastomeric composites with high mechanical performance. Composites Part A: applied science and manufacturing, 109, 257-266.
DOI Scopus31 WoS29
2018 Alam, A., Zhang, Y., Kuan, H. C., Lee, S. H., & Ma, J. (2018). Polymer composite hydrogels containing carbon nanomaterials: morphology and mechanical and functional performance. Progress in polymer science, 77, 1-18.
DOI Scopus135 WoS128
2017 Alam, A., Kuan, H. C., Zhao, Z., Xu, J., & Ma, J. (2017). Novel polyacrylamide hydrogels by highly conductive, water-processable graphene. Composites part A: applied science and manufacturing, 93, 1-9.
DOI Scopus39 WoS38
2017 Meng, Q., Wu, H., Zhao, Z., Araby, S., Lu, S., & Ma, J. (2017). Free-standing, flexible, electrically conductive epoxy/graphene composite films. Composites part A: Applied science and manufacturing, 92, 42-50.
DOI Scopus82 WoS77
2017 Araby, S., Li, J., Shi, G., Ma, Z., & Ma, J. (2017). Graphene for flame-retarding elastomeric composite foams having strong interface. Composites part A: applied science and manufacturing, 101, 254-264.
DOI Scopus37 WoS32
2017 Pan, H., Ma, J., Tao, J., & Zhu, S. (2017). Hierarchical architecture for flexible energy storage. Nanoscale, 9(20), 6686-6694.
DOI Scopus15 WoS15 Europe PMC6
2017 Moussa, M., Shi, G., Wu, H., Zhao, Z., Voelcker, N., Losic, D., & Ma, J. (2017). Development of flexible supercapacitors using an inexpensive graphene/PEDOT/MnO₂ sponge composite. Materials and Design, 125, 1-10.
DOI Scopus62 WoS48
2017 Lu, T., Pan, H., Ma, J., Li, Y., Bokhari, S. W., Jiang, X., . . . Zhang, D. (2017). Cellulose nanocrystals/polyacrylamide composites of high sensitivity and cycling performance to gauge humidity. ACS applied materials and interfaces, 9(21), 18231-18237.
DOI Scopus101 WoS95 Europe PMC39
2017 Fei, X., Lu, T., Ma, J., Zhu, S., & Zhang, D. (2017). A bioinspired poly(N-isopropylacrylamide)/silver nanocomposite as a photonic crystal with both optical and thermal responses. Nanoscale, 9(35), 12969-12975.
DOI Scopus30 WoS30 Europe PMC11
2017 Lu, T., Pan, H., Ma, J., Li, Y., Zhu, S., & Zhang, D. (2017). Near-infrared trigged stimulus-responsive photonic crystals with hierarchical structures. ACS applied materials and interfaces, 9(39), 34279-34285.
DOI Scopus20 WoS20 Europe PMC5
2017 Pan, H., Zhu, C., Lu, T., Lin, J., Ma, J., Zhang, D., & Zhu, S. (2017). A chiral smectic structure assembled from nanosheets and nanorods. Chemical communications, 53(11), 1868-1871.
DOI Scopus31 WoS33 Europe PMC16
2016 Fei, X., Lu, T., Ma, J., Wang, W., Zhu, S., & Zhang, D. (2016). Bioinspired polymeric photonic crystals for high cycling pH-sensing performance. ACS applied materials and interfaces, 8(40), 27091-27098.
DOI Scopus44 WoS42 Europe PMC8
2016 Odedairo, T., Ma, J., Chen, J., Wang, S., & Zhu, Z. (2016). Influences of doping Cr/Fe/Ta on the performance of Ni/CeO₂ catalyst under microwave irradiation in dry reforming of CH₄. Journal of Solid State Chemistry, 233, 166-177.
DOI Scopus39 WoS34
2016 Zhao, Z., Moussa, M., Shi, G., Meng, Q., Wang, R., & Ma, J. (2016). Compressible, electrically conductive, fibre-like, three-dimensional PEDOT-based composite aerogels towards energy storage applications. Composites Science and Technology, 127, 36-46.
DOI Scopus24 WoS24
2016 Moussa, M., El-Kady, M. F., Zhao, Z., Majewski, P., & Ma, J. (2016). Recent progress and performance evaluation for polyaniline/graphene nanocomposites as supercapacitor electrodes. Nanotechnology, 27(44), 1-22.
DOI Scopus118 WoS99 Europe PMC16
2016 Shi, G., Zhao, Z., Pai, J. H., Lee, I., Zhang, L., Stevenson, C., . . . Ma, J. (2016). Highly Sensitive, Wearable, Durable Strain Sensors and Stretchable Conductors Using Graphene/Silicon Rubber Composites. Advanced Functional Materials, 26(42), 7614-7625.
DOI Scopus377 WoS365
2016 Lu, Y., Liu, J., Hou, G., Ma, J., Wang, W., Wei, F., & Zhang, L. (2016). From nano to giant? Designing carbon nanotubes for rubber reinforcement and their applications for high performance tires. Composites science and technology, 137, 94-101.
DOI Scopus73 WoS65
2016 Alam, A., Meng, Q., Shi, G., Arabi, S., Ma, J., Zhao, N., & Kuan, H. C. (2016). Electrically conductive, mechanically robust, pH-sensitive graphene/polymer composite hydrogels. Composites science and technology, 127, 119-126.
DOI Scopus117 WoS113
2016 Lou, X., Zhu, C., Pan, H., Ma, J., Zhu, S., Zhang, D., & Jiang, X. (2016). Cost-effective three-dimensional graphene/Ag aerogel composite for high-performance sensing. Electrochimica Acta, 205, 70-76.
DOI Scopus43 WoS38
2016 Araby, S., Qiu, A., Wang, R., Zhao, Z., Wang, C. H., & Ma, J. (2016). Aerogels based on carbon nanomaterials. Journal of materials science, 51(20), 9157-9189.
DOI Scopus104 WoS79
2016 Odedairo, T., Ma, J., Chen, J., & Zhu, Z. (2016). Cr-doped La-Ni-O catalysts derived from perovskite precursors for CH4-CO2 reforming under microwave irradiation. Chemical engineering & technology, 39(8), 1551-1560.
DOI Scopus9 WoS9
2016 Zhao, Z., Richardson, G. F., Meng, Q., Zhu, S., Kuan, H. C., & Ma, J. (2016). PEDOT-based composites as electrode materials for supercapacitors. Nanotechnology, 27(4, article no. 042001), 1-19.
DOI Scopus149 WoS127 Europe PMC20
2016 Wang, Y. X., Xu, Y., Meng, Q., Chou, S. L., Ma, J., Kang, Y. M., & Liu, H. K. (2016). Chemically bonded Sn nanoparticles using the crosslinked epoxy binder for high energy-density Li ion battery. Advanced materials interfaces, 3(23, article no. 1600662), 1-7.
DOI Scopus19 WoS18
2015 Wu, S., Ladani, R. B., Zhang, J., Kinloch, A. J., Zhao, Z., Ma, J., . . . Wang, C. H. (2015). Epoxy nanocomposites containing magnetite-carbon nanofibers aligned using a weak magnetic field. Polymer, 68, 25-34.
DOI Scopus109 WoS98
2015 Araby, S., Meng, Q., Zhang, L., Zaman, I., Majewski, P., & Ma, J. (2015). Elastomeric composites based on carbon nanomaterials. Nanotechnology, 25(11), 1-24.
DOI Scopus134 WoS121 Europe PMC25
2015 Shi, G., Meng, Q., Zhao, Z., Kuan, H. C., Michelmore, A., & Ma, J. (2015). Facile fabrication of graphene membranes with readily tunable structures. ACS applied materials and interfaces, 7(25), 13745-13757.
DOI Scopus43 WoS38
2015 Yao, B., Li, C., Ma, J., & Shi, G. (2015). Porphyrin-based graphene oxide frameworks with ultra-large d-spacings for the electrocatalyzation of oxygen reduction reaction. Physical chemistry chemical physics, 17(29), 19538-19545.
DOI Scopus42 WoS40
2015 Moussa, M., Zhao, Z., El Kady, M. F., Liu, H., Michelmore, A., Kawashima, N., . . . Ma, J. (2015). Free-standing composite hydrogel films for superior volumetric capacitance. Journal of materials chemistry A, 3(30), 15668-15674.
DOI Scopus73 WoS72
2015 Moussa, M., El Kady, M. F., Wang, H., Michimore, A., Zhou, Q., Xu, J., . . . Ma, J. (2015). High-performance supercapacitors using graphene/polyaniline composites deposited on kitchen sponge. Nanotechnology, 26(7, article no. 075702), 1-11.
DOI Scopus44 WoS36 Europe PMC9
2015 Araby, S., Saber, N., Ma, X., Kawashima, N., Kang, H., Shen, H., . . . Ma, J. (2015). Implication of multi-walled carbon nanotubes on polymer/graphene composites. Materials and Design, 65, 690-699.
DOI Scopus118 WoS108
2015 Kandare, E., Afaghi Khatibi, A., Soo, S., Wang, R., Ma, J., Olivier, P. A., . . . Wang, C. H. (2015). Improving the through-thickness thermal and electrical conductivity of carbon fibre/epoxy laminates by exploiting synergy between graphene and silver nano-inclusions. Composites part A: applied science and manufacturing, 69, 72-82.
DOI Scopus227 WoS196
2015 Lu, T., Zhu, S., Ma, J., Lin, J., Wang, W., Pan, H., . . . Zhang, D. (2015). Bioinspired thermoresponsive photonic polymers with hierarchical structures and their unique properties. Macromolecular Rapid Communications, 36(19), 1722-1728.
DOI Scopus23 WoS20 Europe PMC4
2015 Li, Y., Meng, Q., Ma, J., Zhu, C., Cui, J., Chen, Z., . . . Zhang, D. (2015). Bioinspired carbon/SnO₂ composite anodes prepared from a photonic hierarchical structure for lithium batteries. ACS Applied Materials and Interfaces, 7(21), 11146-11154.
DOI Scopus52 WoS49 Europe PMC10
2015 Odedairo, T., Yan, X., Ma, J., Jiao, Y., Yao, X., Du, A., & Zhu, Z. (2015). Nanosheets Co3O4 interleaved with graphene for highly efficient oxygen reduction. ACS applied materials and interfaces, 7(38), 21373-21380.
DOI Scopus105 WoS99 Europe PMC20
2015 Yu, Y., Andrade, L. D., Fang, L., Ma, J., Zhang, W., & Tang, Y. (2015). Graphene oxide and hyperbranched polymer-toughened hydrogels with improved absorption properties and durability. Journal of materials science, 50(9), 3457-3466.
DOI Scopus38 WoS38
2014 Odedairo, T., Ma, J., Gu, Y., Zhou, W., Jin, J., Zhao, X. S., & Zhu, Z. (2014). A new approach to nanoporous graphene sheets via rapid microwave-induced plasma for energy applications. Nanotechnology, 25(49), 1-10.
DOI Scopus25 WoS22
2014 Meng, Q., Wang, C. H., Saber, N., Kuan, H. C., Dai, J., Friedrich, K., & Ma, J. (2014). Nanosilica-toughened polymer adhesives. Materials and design, 61, 75-86.
DOI Scopus54 WoS45
2014 Ma, J., Meng, Q., Zaman, I., Zhu, S., Michelmore, A., Kawashima, N., . . . Kuan, H. C. (2014). Development of polymer composites using modified, high-structural integrity graphene platelets. Composites Science and Technology, 91, 82-90.
DOI Scopus156 WoS138
2014 Zhu, S., Yao, L., Yin, C., Li, Y., Peng, W., Ma, J., & Zhang, D. (2014). Fe2O3/TiO2 photocatalyst of hierarchical structure for H2 production from water under visible light irradiation. Microporous and mesoporous materials, 190, 10-16.
DOI Scopus61 WoS59
2014 Sun, Z., Guo, J., Zhu, S., Ma, J., Liao, Y., & Zhang, D. (2014). High photocatalytic performance by engineering Bi2WO6 nanoneedles onto graphene sheets. RSC advances, 4(53), 27963-27970.
DOI Scopus24 WoS24
2014 Li, Y., Zhu, S., Yu, Z., Meng, Q., Liu, Q., Gu, J., . . . Zhang, D. (2014). A facile fabrication of Fe3O4/graphene nanosheets for lithium-ion battery. Science of advanced materials, 6(2), 283-289.
DOI Scopus15 WoS15
2014 Shi, G., Michelmore, A., Jin, J., Li, L., Chen, Y., Wang, L., . . . Ma, J. (2014). Advancement in liquid exfoliation of graphite through simultaneously oxidizing and ultrasonicating. Journal of Materials Chemistry A, 2(47), 20382-20392.
DOI Scopus26 WoS26
2014 Mao, L., Zhu, S., Ma, J., Shi, D., Chen, Z., Yin, C., . . . Zhang, D. (2014). Superior H2 production by hydrophilic ultrafine Ta 2O5 engineered covalently on graphene. Nanotechnology, 25(21), 1-9.
DOI Scopus13 WoS15 Europe PMC4
2014 Sun, Z., Guo, J., Zhu, S., Mao, L., Ma, J., & Zhang, D. (2014). A high-performance Bi₂WO₆-graphene photocatalyst for visible light-induced H₂ and O₂ generation. Nanoscale, 6(4), 2186-2193.
DOI Scopus192 WoS184 Europe PMC41
2014 Meng, Q., Jin, J., Wang, R., Kuan, H. C., Ma, J., Kawashima, N., . . . Wang, C. H. (2014). Processable 3-nm thick graphene platelets of high electrical conductivity and their epoxy composites. Nanotechnology, 25(12, article no. 125707), 1-13.
DOI Scopus126 WoS105 Europe PMC18
2014 Saber, N., Araby, S., Meng, Q., Hsu, H. Y., Yan, C., Azari, S., . . . Yu, S. (2014). Superior piezoelectric composite films: taking advantage of carbon nanomaterials. Nanotechnology, 25(4), 1-11.
DOI Scopus15 WoS11
2014 Liao, Y., Zhu, S., Ma, J., Sun, Z., Yin, C., Zhu, C., . . . Zhang, D. (2014). Tailoring the morphology of g-C₃N₄ by self-assembly towards high photocatalytic performance. ChemCatChem, 6(12), 3419-3425.
DOI Scopus160 WoS155
2014 Meng, Q., Araby, S., Saber, N., & Ma, J. (2014). From graphene and graphene oxide, to graphene platelets. Australian resources and investment, 8(2), 134.
2014 Saber, N., Meng, Q., Hsu, H. Y., Lee, S. H., Kuan, H. C., Marney, D., . . . Ma, J. (2014). Smart thin-film piezoelectric composite sensors based on high lead zirconate titanate content. Structural health monitoring, 14(3), 214-227.
DOI Scopus16 WoS16
2014 Araby, S., Meng, Q., Zhang, L., Kang, H., Majewski, P., Tang, Y., & Ma, J. (2014). Electrically and thermally conductive elastomer/graphene nanocomposites by solution mixing. Polymer, 55(1), 201-210.
DOI Scopus276 WoS236
2014 Meng, Q., Kuan, H. C., Araby, S., Kawashima, N., Saber, N., Wang, C. H., & Ma, J. (2014). Effect of interface modification on PMMA/graphene nanocomposites. Journal of materials science, 49(17), 5838-5849.
DOI Scopus34 WoS33
2014 Meng, Q., Araby, S., Saber, N., Kuan, H. C., Dai, J., Luong, L., . . . Wang, C. H. (2014). Toughening polymer adhesives using nanosized elastomeric particles. Journal of materials research, 29(5), 665-674.
DOI Scopus29 WoS27
2014 Odedairo, T., Ma, J., Gu, Y., Chen, J., Zhao, X. S., & Zhu, Z. (2014). One-pot synthesis of carbon nanotube-graphene hybrids via syngas production. Journal of materials chemistry A, 2(5), 1418-1428.
DOI Scopus66 WoS61
2013 Kuan, H. C., Desari, A., Yu, Z. Z., Ma, J., Mai, Y. W., & Ma, C. C. M. (2013). Molecular mobility and mechanical properties of novel clay/waterborne polyurethane nanocomposites. Advanced science letters, 19(2), 524-528.
DOI
2013 Araby, S., Zhang, L., Kuan, H. C., Dai, J. B., Majewski, P., & Ma, J. (2013). A novel approach to electrically and thermally conductive elastomers using graphene. Polymer, 54(14), 3663-3670.
DOI Scopus145 WoS134
2013 Ma, J., Meng, Q., Michelmore, A., Kawashima, N., Zaman, I., Bengtsson, C., & Kuan, H. C. (2013). Covalently bonded interfaces for polymer/graphene composites. Journal of materials chemistry A, 1(13), 4255-4264.
DOI Scopus183 WoS161
2013 Li, F., Lu, Y., Liu, L., Zhang, L., Dai, J., & Ma, J. (2013). Relations between carbon nanotubes' length and their composites' mechanical and functional performance. Polymer, 54(8), 2158-2165.
DOI Scopus53 WoS51
2013 Araby, S., Zaman, I., Meng, Q., Kawashima, N., Michelmore, A., Kuan, H. C., . . . Zhang, L. (2013). Melt compounding with graphene to develop functional, high-performance elastomers. Nanotechnology, 24(16, article no. 165601), 1-14.
DOI Scopus142 WoS122 Europe PMC18
2013 Yang, Q., Zhu, S., Peng, W., Yin, C., Wang, W., Gu, J., . . . Zhang, D. (2013). Bioinspired fabrication of hierarchically structured, pH-tunable photonic crystals with unique transition. ACS nano, 7(6), 4911-4918.
DOI Scopus107 WoS99 Europe PMC49
2013 Zhu, S., Guo, J., Dong, J., Cui, Z., Lu, T., Zhu, C., . . . Ma, J. (2013). Sonochemical fabrication of Fe3O4 nanoparticles on reduced graphene oxide for biosensors. Ultrasonics sonochemistry, 20(3), 872-880.
DOI Scopus170 WoS146 Europe PMC30
2013 Zhu, S., Zhu, C., Ma, J., Meng, Q., Guo, Z., Yu, Z., . . . Lau, W. M. (2013). Controlled fabrication of Si nanoparticles on graphene sheets for Li-ion batteries. RSC advances, 3(17), 6141-6146.
DOI Scopus70 WoS69
2013 Li, Y., Zhu, S., Liu, Q., Chen, Z., Gu, J., Zhu, C., . . . Ma, J. (2013). N-doped porous carbon with magnetic particles formed in situ for enhanced Cr(VI) removal. Water Research, 47(12), 4188-4197.
DOI Scopus208 WoS201 Europe PMC68
2013 Li, Y., Zhu, C., Lu, T., Guo, Z., Zhang, D., Ma, J., & Zhu, S. (2013). Simple fabrication of a Fe2O3/carbon composite for use in a high-performance lithium ion battery. Carbon, 52, 565-573.
DOI Scopus139 WoS136
2013 Kang, H., Qiao, B., Wang, R., Wang, Z., Zhang, L., Ma, J., & Coates, P. (2013). Employing a novel bioelastomer to toughen polylactide. Polymer, 54(9), 2450-2458.
DOI Scopus99 WoS92
2012 Zaman, I., Kuan, H. C., Dai, J., Kawashima, N., Michelmore, A., Sovi, A., . . . Ma, J. (2012). From carbon nanotubes and silicate layers to graphene platelets for polymer nanocomposites. Nanoscale, 4(15), 4578-4586.
DOI Scopus213 WoS198 Europe PMC23
2012 Wang, R., Ma, J., Zhou, X., Wang, Z., Kang, H., Zhang, L., . . . Kulig, J. (2012). Design and preparation of a novel cross-linkable, high molecular weight, and bio-based elastomer by emulsion polymerization. Macromolecules, 45(17), 6830-6839.
DOI Scopus101 WoS94
2012 Zaman, I., Kuan, H. C., Meng, Q., Michelmore, A., Kawashima, N., Pitt, T., . . . Ma, J. (2012). A facile approach to chemically modified graphene and its polymer nanocomposites. Advanced functional materials, 22(13), 2735-2743.
DOI Scopus282 WoS257
2012 Wang, Z., Zhang, X., Wang, R., Kang, H., Qiao, B., Ma, J., . . . Wang, H. (2012). Synthesis and characterization of novel soybean-oil-based elastomers with favorable processability and tunable properties. Macromolecules, 45(22), 9010-9019.
DOI Scopus137 WoS124
2012 Zaman, I., Meng, Q., & Ma, J. (2012). Role of interface of epoxy/clay nanocomposites and its effect on structure-property relationship. Advanced materials research, 476-478, 859-862.
DOI Scopus1 WoS1
2011 Zaman, I., Le, Q. H., Kuan, H. C., Kawashima, N., Luong, L., Gerson, A., & Ma, J. (2011). Interface-tuned epoxy/clay nanocomposites. Polymer, 52(2), 497-504.
DOI Scopus85 WoS70
2011 Ma, J., La, L. T. B., Zaman, I., Meng, Q., Luong, L., Ogilvie, D., & Kuan, H. C. (2011). Fabrication, structure and properties of epoxy/metal nanocomposites. Macromolecular materials & engineering, 296(5), 465-474.
DOI Scopus66 WoS58
2011 Zaman, I., Thanh Tam, P., Kuan, H. C., Meng, Q., La, L. T. B., Luong, L., . . . Ma, J. (2011). Epoxy/graphene platelets nanocomposites with two levels of interface strength. Polymer, 52(7), 1603-1611.
DOI Scopus533 WoS482
2011 Meng, Q., Zaman, I., Hannam, J. R., Kapota, S., Luong, L. H. S., Youssf, O., & Ma, J. (2011). Improvement of adhesive toughness measurement. POLYMER TESTING, 30(2), 243-250.
DOI Scopus35 WoS28
2011 Le, Q. H., Kuan, H. C., Dai, J. B., Zaman, I., Luong, L., & Ma, J. (2011). Erratum: Structure-property relations of 55 nm particle-toughened epoxy (Polymer (2010) 51 (4867-4879)). Polymer, 52(3), 894.
DOI WoS1
2010 Le, Q. H., Kuan, H. C., Dai, J. B., Zaman, I., Luong, L., & Ma, J. (2010). Structure-property relations of 55nm particle-toughened epoxy. Polymer, 51(21), 4867-4879.
DOI Scopus116 WoS101
2010 Kuan, H. C., Dai, J. B., & Ma, J. (2010). A reactive polymer for toughening epoxy resin. Journal of applied polymer science, 115(6), 3265-3272.
DOI Scopus57 WoS53
2009 Dai, J. B., Kuan, H. C., Du, X. S., Dai, S. C., & Ma, J. (2009). Development of a novel toughener for epoxy resins. Polymer international, 58(7), 838-845.
DOI Scopus65 WoS58
2009 Mo, M. S., Wang, D., Du, X., Ma, J., Qian, X., Chen, D., & Qian, Y. (2009). Engineering of nanotips in ZnO submicrorods and patterned arrays. Crystal growth and design, 9(2), 797-802.
DOI Scopus17 WoS17
2009 Hu, H., Yu, S., Wang, M., Ma, J., & Liu, K. (2009). Tribological properties of epoxy/polyurea composite. Polymers for Advanced Technologies, 20(9), 748-752.
DOI Scopus19 WoS15
2008 Ma, J., Mo, M. S., du, X. S., Dai, S. R., & Luck, I. (2008). Study of epoxy toughened by in situ formed rubber nanoparticles. Journal of applied polymer science, 110(1), 304-312.
DOI Scopus82 WoS72
2008 Li, S., Wang, F., Wang, Y., Wang, J., Ma, J., & Xiao, J. (2008). Effect of acid and TETA modifications on mechanical properties of MWCNTs/epoxy composites. Journal of materials science, 43(8), 2653-2658.
DOI Scopus63 WoS60
2008 Ma, J., Mo, M. S., Du, X. S., Rosso, P., Friedrich, K., & Kuan, H. C. (2008). Effect of inorganic nanoparticles on mechanical property, fracture toughness and toughening mechanism of two epoxy systems. Polymer, 49(16), 3510-3523.
DOI Scopus262 WoS240
2008 Du, X. S., Wang, G., Ma, J., Mo, M. S., & Mai, Y. W. (2008). Silver nanoparticles, cages and flowers growing on carbon nanosheets. Advanced Materials Research, 32(2008), 5-8.
DOI
2008 Du, X. S., Yu, Z. Z., Dasari, A., Ma, J., Mo, M. S., Meng, Y. Z., & Mai, Y. W. (2008). New method to prepare graphite nanocomposites. Chemistry of materials, 20(6), 2066-2068.
DOI Scopus129 WoS123
2008 Yu, S., Hu, H., Ma, J., & Yin, J. (2008). Tribological properties of epoxy/rubber nanocomposites. Tribology international, 41(12), 1205-1211.
DOI Scopus59 WoS47
2008 Wang, Y., Wang, Y., Tian, M., Zhang, L., & Ma, J. (2008). Influence of prolonging vulcanization on the structure and properties of hard rubber. Journal of applied polymer science, 107(1), 444-454.
DOI Scopus8 WoS7
2007 Ma, J., Qi, Q., Bayley, J., Du, X. S., Mo, S. M., & Zhang, L. (2007). Development of SENB toughness mearsurement for thermoset resins. Polymer Testing, 26(4), 445-450.
DOI Scopus59 WoS56
2007 Hu, H. X., Yu, S. R., Ma, J., & Wang, Y. H. (2007). Study on surface chemical effects of epoxy under dry friction. Mocaxue Xuebao Tribology, 27(3), 241-245.
Scopus5
2006 Liu, H., Xu, J., Li, Y., LI, B. Y., Ma, J., & Zhang, Q. X. (2006). Fabrication and characterization of an organic-inorganic gradient surface made by polymethylsilsesquioxane (PMSQ). Macromolecular Rapid Communications, 27(18), 1603-1607.
DOI Scopus41 WoS40
2006 Tang, H. G., Qi, Q., Wu, Y. P., Liang, G., Zhang, L. Q., & Ma, J. (2006). Reinforcement of elastomer by starch. Macromolecular Materials & Engineering, 291(6), 629-637.
DOI Scopus53 WoS48
2006 LI, B. Y., Ma, J., Liu, H. Y., Guo, X. L., Xu, J., & Zhang, X. L. (2006). Study on polymethylsilsesquixane/clay nanocomposite and its laminate. Journal of Applied Polymer Science, 100(5), 3974-3980.
DOI Scopus12 WoS10
2006 Qi, Q., Wu, Y. P., Tian, M., Zhang, L. Q., & Ma, J. (2006). Modification of starch for high performance elastomer. Polymer, 47(11), 3896-3903.
DOI Scopus68 WoS68
2006 Du, X. S., Yu, Z. Z., Dasary, A., Ma, J., Meng, Y. Z., & Mai, Y. (2006). Facile synthesis and assembly of Cu2S nanodisks to corncoblike nanostructures. Chemistry of Materials, 18(22), 5156-5158.
DOI Scopus75 WoS73
2005 Ma, J., Yu, Z. Z., Kuan, H. C., & Mai, Y. (2005). A new strategy to exfoliated silicone rubber/clay nanocomposites. Macromolecular Rapid Communications, 26(10), 830-833.
DOI Scopus75 WoS64
2005 Liang, Y., Ma, J., Lu, Y. L., Wu, Y. P., Zhang, L. Q., & Mai, Y. (2005). Effects of heat and pressure on intercalation structures of isobutylene-isoprene rubber/clay nanocomposites. I. prepared by melt blending. Journal of Polymer Science: Part B Polymer Physics, 43(19), 2653-2664.
DOI Scopus47 WoS33
2004 Ma, J., Xiang, P., Mai, Y., & Zhang, L. Q. (2004). A novel approach to high performance elastomer by using clay. Macromolecular Rapid Communications, 25(19), 1692-1696.
DOI Scopus110 WoS96
2004 Ma, J., LI, B. Y., Liu, H. Y., Zheng, Z. M., & Xu, J. (2004). Study on a hydrophobic-hydrophilic gradient rod. Chinese Journal of Polymer Science, 22(2), 131-135.
Scopus6
2004 Ma, J., Yu, Z. Z., Zhang, Q. X., Xie, X. L., Mai, Y., & Luck, I. (2004). A novel method for preparing disorderly exfoliated epoxy/clay nanocomposite. Chemistry of Materials, 16(5), 757-759.
DOI Scopus94 WoS83
2003 Ma, J., Su, W., Zhang, Y., Hu, T. J., Liu, H., Li, B. Y., . . . Mai, Y. W. (2003). Polysilsesquiozane nanosheets synthsized in confined environment. Macromolecular Rapid Communications, 24(11), 676-680.
DOI Scopus1
2003 Zhang, Q. X., Yu, Z. Z., Yang, M. S., Ma, J., & Mai, Y. (2003). Multiple Melting and Crystallization of Nylon 66/Montmorillonite Nanocomposites. Journal of Polymer Science : Part B Polymer Physics, 41(22), 2861-2869.
DOI Scopus75 WoS67
2003 Ma, J., Xu, J., Ren, J. H., Yu, Z. Z., & Mai, Y. W. (2003). A new approach to polymer/montmorillonite nanocomposites. Polymer, 44(16), 4619-4624.
DOI Scopus225 WoS201
2002 Jun, M., Shi, L., Shi, Y., Luo, S., & Xu, J. (2002). Pyrolysis of polymethylsilsesquioxane. Journal of Applied Polymer Science, 85(5), 1077-1086.
DOI Scopus53 WoS51
2002 Ma, J., Shi, L., & Xu, J. (2002). Preliminary Study on Pyrolysis of Polymethylsilsesquioxane by FT-IR and XPS. Chinese Chemical Letters, 13(1), 75-78.
Scopus12
2002 Ma, J., Shi, L., & Xu, J. (2002). Study on Pyrolysis of Polymethylsissesquioxane. Journal of Applied Polymer Science, 20(6), 573-577.
Scopus10
2002 Ma, J., Shi, L., & Xu, J. (2002). Study on Pyrolysis of Polyphenylsilsesquioxane. Journal of Polymer Science: Part B Polymer Physics.
2002 Ma, J., Shi, L., & Xu, J. (2002). Preparation of PMSQ/clay nanocomposite via in situ intercalative polymerisation. Journal of Applied Polymer Science, 86(14), 3708-3711.
DOI Scopus19 WoS17
2001 Ma, J., Feng, Y. X., Xu, J., Xiong, M. L., Zhu, Y. J., & Zhang, L. Q. (2001). Effects of compatibilizing agent and in situ fibril on the morphology, interface and mechanical properties of EPDM/nylon copolymer blends. Polymer, 43(3), 937-945.
DOI Scopus42 WoS50

  • Elastomer/Graphene Composites for Reinforcement at Low Strain, ARC - Linkage Project, 01/07/2021 - 30/06/2024

  • High-Performance Polymer Composites for Electrical Discharging, ARC - Linkage Project, 13/01/2020 - 12/01/2024

  • A Novel Approach to Polymer/Nanosheet Composites and Their Fundamentals, ARC - Discovery Projects, 01/06/2020 - 01/12/2023

  • High-Performance Polymer Composites for Electrical Discharging, Hanyu Materials Technology Co. Ltd, 01/01/2019 - 12/01/2023

  • ARC Research Hub for Graphene Enabled Industry Transformation, ARC - Industrial Transformation Research Hubs, 28/06/2017 - 28/06/2022

  • Electrically conductive elastomeric composites by nanomaterials, ARC - Linkage Project, 11/11/2016 - 08/07/2020

  • Electrically conductive elastomeric composites by nanomaterials (Industry Partner), Graphlex Technology Pty Ltd, 01/07/2016 - 08/06/2020

  • APR Internship - Aidong Qiu, AMSI-APR Intern, 15/10/2018 - 31/05/2019

  • Strong and durable flame-retarding composites by multi-scale encapsulation and reinforcement, ARC - Linkage Project, 22/05/2015 - 22/05/2018

  • Novel Sensors to Monitor Conveyor Belt Rolls, Graphlex Technology Pty Ltd, 01/10/2016 - 31/12/2017

Courses I teach

  • RENG 1005 Engineering Materials (2025)
  • RENG 1005 Engineering Materials (2024)

Date Role Research Topic Program Degree Type Student Load Student Name
2025 Principal Supervisor Clean manufacture of high-performance flame-retardant elastomer nanocomposites Doctor of Philosophy Doctorate Full Time Mr Yangzhe Hou
2025 Principal Supervisor Sustainable Cellulose-Based Composites for Passive Radiative Cooling Paints Doctor of Philosophy Doctorate Full Time Miss Linh Tran
2025 Principal Supervisor Environmentally friendly polymer composite coatings containing safe, cost-effective nanomaterials for flame retardancy - Master Full Time Yongshan Zhao
2025 Principal Supervisor Architecture and Mechanisms Investigation of Ion Conductive Polymers over Wide-temperature Ranges Doctor of Philosophy Doctorate Full Time Mr Wangwu Li
2024 Principal Supervisor Development of high performance thermally conductive thermoplastic composites. - Master Full Time Miss Tongyan Cui
2023 Principal Supervisor 111826- Electrically conductive polymer composites for thermoelectric and sensing applications Doctor of Philosophy Doctorate Full Time Mr Md Joherul Alam
2023 Co-Supervisor New cement composites with high durability and thermoelectric performance Doctor of Philosophy Doctorate Full Time Miss Qiong Jia
2022 Principal Supervisor h4>Thermally conductive, mechanically resilient thermoplastic nanocomposites for heat exchangers Doctor of Philosophy Doctorate Full Time Mr Xiao Su
2022 Principal Supervisor h4>Mechanically strong elastomer composites with multifunctionalities by Using cost­-effective, safe nanomaterials - Master Full Time Mr Sanjay Stephen Chelliah

Date Role Editorial Board Name Institution Country
2025 - ongoing Editor Advanced Composites and Hybrid Materials Springer Nature (United Kingdom) United Kingdom

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