This work is licensed under the Creative Commons Attribution-NonCommercial-NoDerivatives 4.0 International License.
Bachmatiuk, A. (2008). Badania nad technologią otrzymywania i właściwościami nanorurek węglowych [Unpublished doctoral dissertation]. Politechnika Szczecińska, Wydział technologii i Inżynierii Chemicznej.BachmatiukA. (2008). Badania nad technologią otrzymywania i właściwościami nanorurek węglowych [Unpublished doctoral dissertation]. Politechnika Szczecińska, Wydział technologii i Inżynierii Chemicznej.Search in Google Scholar
Bakar Sulong, A., Muhamad, N., Sahari, J., Ramli, R., Md Deros, B., & Park, J. (2009). Electrical Conductivity Behaviour of Chemical Functionalized MWCNTs Epoxy Nanocomposites. European Journal of Scientific Research, 29(1), 13–21.Bakar SulongA.MuhamadN.SahariJ.RamliR.Md DerosB.ParkJ. (2009). Electrical Conductivity Behaviour of Chemical Functionalized MWCNTs Epoxy Nanocomposites. European Journal of Scientific Research, 29(1), 13–21.Search in Google Scholar
Barros, E. B., Jorio, A., Samsonidze, G. G., Capaz, R. B., Souza Filho, A. G., Mendes Filho, J., Dresselhaus, G., & Dresselhaus, M. S. (2006). Review on the symmetry-related properties of carbon nanotubes. Physics Reports, 431(6), 261–302.BarrosE. B.JorioA.SamsonidzeG. G.CapazR. B.Souza FilhoA. G.Mendes FilhoJ.DresselhausG.DresselhausM. S. (2006). Review on the symmetry-related properties of carbon nanotubes. Physics Reports, 431(6), 261–302.Search in Google Scholar
Baughman, R. H., Shacklette, J. M., Zakhidov, A. A., & Stafström, S. (1998). Negative Poisson’s ratios as a common feature of cubic metals. Nature, 392(6674), 362–365.BaughmanR. H.ShackletteJ. M.ZakhidovA. A.StafströmS. (1998). Negative Poisson’s ratios as a common feature of cubic metals. Nature, 392(6674), 362–365.Search in Google Scholar
Bielanski, A. (1980). Chemia Fizyczna. Państwowe Wydawnictwo Naukowe PWN.BielanskiA. (1980). Chemia Fizyczna. Państwowe Wydawnictwo Naukowe PWN.Search in Google Scholar
Borowiak-Palen, E., Pichler, T., Liu, X., Knupfer, M., Graff, A., Jost, O., Pompe, W., Kalenczuk, R. J., & Fink, J. (2002). Reduced diameter distribution of single-wall carbon nanotubes by selective oxidation. Chemical Physics Letters, 363(5-6), 567–572.Borowiak-PalenE.PichlerT.LiuX.KnupferM.GraffA.JostO.PompeW.KalenczukR. J.FinkJ. (2002). Reduced diameter distribution of single-wall carbon nanotubes by selective oxidation. Chemical Physics Letters, 363(5-6), 567–572.Search in Google Scholar
Cardona-Uribe, N., Betancur, M., & Martínez, J. D. (2021). Towards the chemical upgrading of the recovered carbon black derived from pyrolysis of end-of-life tires. Sustainable Materials and Technologies, 28, Article e00287.Cardona-UribeN.BetancurM.MartínezJ. D. (2021). Towards the chemical upgrading of the recovered carbon black derived from pyrolysis of end-of-life tires. Sustainable Materials and Technologies, 28, Article e00287.Search in Google Scholar
Ciecierska, E., Boczkowska, A., Chabera, P., Wisniewski, T., & Kubiś, M. (2015). Epoxy composites with carbon fillers. Structure and properties Kompozyty żywicy epoksydowej z napełniaczami węglowymi. Struktura i właściwości. Przemysł Chemiczny, 1(11), 159–163.CiecierskaE.BoczkowskaA.ChaberaP.WisniewskiT.KubiśM. (2015). Epoxy composites with carbon fillers. Structure and properties Kompozyty żywicy epoksydowej z napełniaczami węglowymi. Struktura i właściwości. Przemysł Chemiczny, 1(11), 159–163.Search in Google Scholar
Domun, N., Hadavinia, H., Zhang, T., Sainsbury, T., Liaghat, G. H., & Vahid, S. (2015). Improving the fracture toughness and the strength of epoxy using nanomaterials – a review of the current status. Nanoscale, 7(23), 10294–10329.DomunN.HadaviniaH.ZhangT.SainsburyT.LiaghatG. H.VahidS. (2015). Improving the fracture toughness and the strength of epoxy using nanomaterials – a review of the current status. Nanoscale, 7(23), 10294–10329.Search in Google Scholar
Dydek, K., Boczkowska, A., Kozera, R., Durałek, P., Sarniak, Ł., Wilk, M., & Login, W. (2021). Effect of SWCNT-Tuball Paper on the Lightning Strike Protection of CFRPs and Their Selected Mechanical Properties. Materials, 14(11), 3140.DydekK.BoczkowskaA.KozeraR.DurałekP.SarniakŁ.WilkM.LoginW. (2021). Effect of SWCNT-Tuball Paper on the Lightning Strike Protection of CFRPs and Their Selected Mechanical Properties. Materials, 14(11), 3140.Search in Google Scholar
Frigione, M., Naddeo, C., & Acierno, D. (2001). Cold-Curing Epoxy Resins: Aging and Environmental Effects. I - Thermal Properties. Journal of Polymer Engineering, 21(1).FrigioneM.NaddeoC.AciernoD. (2001). Cold-Curing Epoxy Resins: Aging and Environmental Effects. I - Thermal Properties. Journal of Polymer Engineering, 21(1).Search in Google Scholar
Ganesh, M., Lavenya, K., Kirubashini, K., Ajeesh, G., Bhowmik, S., Epaarachchi, J., & Yuan, X. (2017). Electrically conductive nano adhesive bonding: Futuristic approach for satellites and electromagnetic interference shielding. Advances in Aircraft and Spacecraft Science, 4(6), 729–744.GaneshM.LavenyaK.KirubashiniK.AjeeshG.BhowmikS.EpaarachchiJ.YuanX. (2017). Electrically conductive nano adhesive bonding: Futuristic approach for satellites and electromagnetic interference shielding. Advances in Aircraft and Spacecraft Science, 4(6), 729–744.Search in Google Scholar
Gardea, F., & Lagoudas, D. C. (2014). Characterization of electrical and thermal properties of carbon nanotube/epoxy composites. Composites Part B: Engineering, 56, 611–620.GardeaF.LagoudasD. C. (2014). Characterization of electrical and thermal properties of carbon nanotube/epoxy composites. Composites Part B: Engineering, 56, 611–620.Search in Google Scholar
Geipel, T., Meinert, M., Kraft, A., & Eitner, U. (2018). Optimization of Electrically Conductive Adhesive Bonds in Photovoltaic Modules. IEEE Journal of Photovoltaics, 8(4), 1074–1081.GeipelT.MeinertM.KraftA.EitnerU. (2018). Optimization of Electrically Conductive Adhesive Bonds in Photovoltaic Modules. IEEE Journal of Photovoltaics, 8(4), 1074–1081.Search in Google Scholar
Gogurla, N., Roy, B., Park, J.-Y., & Kim, S. (2019). Skin-contact actuated singleelectrode protein triboelectric nanogenerator and strain sensor for biomechanical energy harvesting and motion sensing. Nano Energy, 62, 674–681.GogurlaN.RoyB.ParkJ.-Y.KimS. (2019). Skin-contact actuated singleelectrode protein triboelectric nanogenerator and strain sensor for biomechanical energy harvesting and motion sensing. Nano Energy, 62, 674–681.Search in Google Scholar
Gojny, F. H., Wichmann, M. H. G., Köpke, U., Fiedler, B., & Schulte, K. (2004). Carbon nanotube-reinforced epoxy-composites: Enhanced stiffness and fracture toughness at low nanotube content. Composites Science and Technology, 64(15), 2363–2371.GojnyF. H.WichmannM. H. G.KöpkeU.FiedlerB.SchulteK. (2004). Carbon nanotube-reinforced epoxy-composites: Enhanced stiffness and fracture toughness at low nanotube content. Composites Science and Technology, 64(15), 2363–2371.Search in Google Scholar
Hagita, K., & Morita, H. (2019). Effects of polymer/filler interactions on glass transition temperatures of filler-filled polymer nanocomposites. Polymer, 178, 121615.HagitaK.MoritaH. (2019). Effects of polymer/filler interactions on glass transition temperatures of filler-filled polymer nanocomposites. Polymer, 178, 121615.Search in Google Scholar
Hall, L. J., Coluci, V. R., Galvao, D. S., Kozlov, M. E., Zhang, M., Dantas, S. O., & Baughman, R. H. (2008). Sign Change of Poisson’s Ratio for Carbon Nanotube Sheets. Science, 320(5875), 504–507.HallL. J.ColuciV. R.GalvaoD. S.KozlovM. E.ZhangM.DantasS. O.BaughmanR. H. (2008). Sign Change of Poisson’s Ratio for Carbon Nanotube Sheets. Science, 320(5875), 504–507.Search in Google Scholar
Huczko, A. (2004). Nanorurki Weglowe. Czarne diamenty XXI wieku. BEL STUDIO.HuczkoA. (2004). Nanorurki Weglowe. Czarne diamenty XXI wieku. BEL STUDIO.Search in Google Scholar
Iijima, S. (2002). Carbon nanotubes: past, present, and future. Physica B: Condensed Matter, 323(1-4), 1–5.IijimaS. (2002). Carbon nanotubes: past, present, and future. Physica B: Condensed Matter, 323(1-4), 1–5.Search in Google Scholar
Krainoi, A., Johns, J., Kalkornsurapranee, E., & Nakaramontri, Y. (2021). Carbon Nanotubes Reinforced Natural Rubber Composites. In P. Ghosh, K. Datta, & A. Rushi (Eds.), Carbon Nanotubes - Redefining the World of Electronics. IntechOpen.KrainoiA.JohnsJ.KalkornsurapraneeE.NakaramontriY. (2021). Carbon Nanotubes Reinforced Natural Rubber Composites. In GhoshP.DattaK.RushiA. (Eds.), Carbon Nanotubes - Redefining the World of Electronics. IntechOpen.Search in Google Scholar
Królikowski, W., & Rosłaniec, Z. (2004). Nanokompozyty polimerowe. Kompozyty, 4(9), 3–15.KrólikowskiW.RosłaniecZ. (2004). Nanokompozyty polimerowe. Kompozyty, 4(9), 3–15.Search in Google Scholar
Kumar, V., Alam, M. N., Manikkavel, A., Song, M., Lee, D.-J., & Park, S.-S. (2021). Silicone Rubber Composites Reinforced by Carbon Nanofillers and Their Hybrids for Various Applications: A Review. Polymers, 13(14), 2322.KumarV.AlamM. N.ManikkavelA.SongM.LeeD.-J.ParkS.-S. (2021). Silicone Rubber Composites Reinforced by Carbon Nanofillers and Their Hybrids for Various Applications: A Review. Polymers, 13(14), 2322.Search in Google Scholar
Kumar, V., Kumar, A., Han, S. S., & Park, S.-S. (2020). RTV silicone rubber composites reinforced with carbon nanotubes, titanium-di-oxide and their hybrid: Mechanical and piezoelectric actuation performance. Nano Materials Science.KumarV.KumarA.HanS. S.ParkS.-S. (2020). RTV silicone rubber composites reinforced with carbon nanotubes, titanium-di-oxide and their hybrid: Mechanical and piezoelectric actuation performance. Nano Materials Science.Search in Google Scholar
Kumar, V., Kumar, A., Song, M., Lee, D.-J., Han, S.-S., & Park, S.-S. (2021). Properties of Silicone Rubber-Based Composites Reinforced with Few-Layer Graphene and Iron Oxide or Titanium Dioxide. Polymers, 13(10), 1550.KumarV.KumarA.SongM.LeeD.-J.HanS.-S.ParkS.-S. (2021). Properties of Silicone Rubber-Based Composites Reinforced with Few-Layer Graphene and Iron Oxide or Titanium Dioxide. Polymers, 13(10), 1550.Search in Google Scholar
Kumar, V., & Lee, D.-J. (2016). Studies of nanocomposites based on carbon nanomaterials and RTV silicone rubber. Journal of Applied Polymer Science, 134(4).KumarV.LeeD.-J. (2016). Studies of nanocomposites based on carbon nanomaterials and RTV silicone rubber. Journal of Applied Polymer Science, 134(4).Search in Google Scholar
Kumar, V., Lee, G., Monika, Choi, J., & Lee, D.-J. (2020). Studies on composites based on HTV and RTV silicone rubber and carbon nanotubes for sensors and actuators. Polymer, 190, 122221.KumarV.LeeG.MonikaChoiJ.LeeD.-J. (2020). Studies on composites based on HTV and RTV silicone rubber and carbon nanotubes for sensors and actuators. Polymer, 190, 122221.Search in Google Scholar
Lakes, R. (1987). Foam Structures with a Negative Poisson’s Ratio. Science, 235(4792), 1038–1040.LakesR. (1987). Foam Structures with a Negative Poisson’s Ratio. Science, 235(4792), 1038–1040.Search in Google Scholar
Latko-Durałek, P., Kozera, R., Macutkevič, J., Dydek, K., & Boczkowska, A. (2020). Relationship between Viscosity, Microstructure and Electrical Conductivity in Copolyamide Hot Melt Adhesives Containing Carbon Nanotubes. Materials, 13(20), 4469.Latko-DurałekP.KozeraR.MacutkevičJ.DydekK.BoczkowskaA. (2020). Relationship between Viscosity, Microstructure and Electrical Conductivity in Copolyamide Hot Melt Adhesives Containing Carbon Nanotubes. Materials, 13(20), 4469.Search in Google Scholar
Lee, J.-Y., Kumar, V., Tang, X.-W., & Lee, D.-J. (2017). Mechanical and electrical behavior of rubber nanocomposites under static and cyclic strain. Composites Science and Technology, 142, 1–9.LeeJ.-Y.KumarV.TangX.-W.LeeD.-J. (2017). Mechanical and electrical behavior of rubber nanocomposites under static and cyclic strain. Composites Science and Technology, 142, 1–9.Search in Google Scholar
Li, C., Chen, X., & Zhimin, D. (2004). A New Relationship of Rock Compressibility with Porosity. Paper presented at the SPE Asia Pacific Oil and Gas Conference and Exhibition, Perth, Australia, October 2004.LiC.ChenX.ZhiminD. (2004). A New Relationship of Rock Compressibility with Porosity. Paper presented at the SPE Asia Pacific Oil and Gas Conference and Exhibition, Perth, Australia, October 2004.Search in Google Scholar
Limpert, E., & Stahel, W. A. (2011). Problems with Using the Normal Distribution – and Ways to Improve Quality and Efficiency of Data Analysis. PLoS ONE, 6(7), Article e21403.LimpertE.StahelW. A. (2011). Problems with Using the Normal Distribution – and Ways to Improve Quality and Efficiency of Data Analysis. PLoS ONE, 6(7), Article e21403.Search in Google Scholar
Liu, Q., Lomov, S. V., & Gorbatikh, L. (2020). Enhancing Strength and Toughness of Hierarchical Composites through Optimization of Position and Orientation of Nanotubes: A Computational Study. Journal of Composites Science, 4(2), 34.LiuQ.LomovS. V.GorbatikhL. (2020). Enhancing Strength and Toughness of Hierarchical Composites through Optimization of Position and Orientation of Nanotubes: A Computational Study. Journal of Composites Science, 4(2), 34.Search in Google Scholar
Liu, Q., Shi, W., Chen, Z., Li, K., Liu, H., & Li, S. (2019). Rubber accelerated ageing life prediction by Peck model considering initial hardness influence. Polymer Testing, 80, 106132.LiuQ.ShiW.ChenZ.LiK.LiuH.LiS. (2019). Rubber accelerated ageing life prediction by Peck model considering initial hardness influence. Polymer Testing, 80, 106132.Search in Google Scholar
Lopes, P., Moura, D., Freitas, D., Proença, M., Figueiredo, R., Alves, H., & Paiva, M. (2019). Advanced electrically conductive adhesives for high complexity PCB assembly. AIP Conf. Proc. 22 January 2019, 2055(1), 090009.LopesP.MouraD.FreitasD.ProençaM.FigueiredoR.AlvesH.PaivaM. (2019). Advanced electrically conductive adhesives for high complexity PCB assembly. AIP Conf. Proc. 22 January 2019, 2055(1), 090009.Search in Google Scholar
Ma, P.-C., Mo, S.-Y., Tang, B.-Z., & Kim, J.-K. (2010). Dispersion, interfacial interaction and re-agglomeration of functionalized carbon nanotubes in epoxy composites. Carbon, 48(6), 1824–1834.MaP.-C.MoS.-Y.TangB.-Z.KimJ.-K. (2010). Dispersion, interfacial interaction and re-agglomeration of functionalized carbon nanotubes in epoxy composites. Carbon, 48(6), 1824–1834.Search in Google Scholar
Mucha, M., Krzyzak, A., Kosicka, E., Coy, E., Kościński, M., Sterzyński, T., & Sałaciński, M. (2020). Effect of MWCNTs on Wear Behavior of Epoxy Resin for Aircraft Applications. Materials, 13(12), 2696.MuchaM.KrzyzakA.KosickaE.CoyE.KościńskiM.SterzyńskiT.SałacińskiM. (2020). Effect of MWCNTs on Wear Behavior of Epoxy Resin for Aircraft Applications. Materials, 13(12), 2696.Search in Google Scholar
Nicolau-Kuklińska, A., Latko-Durałek, P., Nakonieczna, P., Dydek, K., Boczkowska, A., & Grygorczuk, J. (2017). A new electroactive polymer based on carbon nanotubes and carbon grease as compliant electrodes for electroactive actuators. Journal of Intelligent Material Systems and Structures, 29(7), 1520–1530.Nicolau-KuklińskaA.Latko-DurałekP.NakoniecznaP.DydekK.BoczkowskaA.GrygorczukJ. (2017). A new electroactive polymer based on carbon nanotubes and carbon grease as compliant electrodes for electroactive actuators. Journal of Intelligent Material Systems and Structures, 29(7), 1520–1530.Search in Google Scholar
Nobile, M. R. (2011). Rheology of polymer–carbon nanotube composites melts. In T. McNally & P. Pötschke (Eds.), Polymer–Carbon Nanotube Composites (pp. 428–481). Woodhead Publishing.NobileM. R. (2011). Rheology of polymer–carbon nanotube composites melts. In McNallyT.PötschkeP. (Eds.), Polymer–Carbon Nanotube Composites (pp. 428–481). Woodhead Publishing.Search in Google Scholar
Plagge, J., & Lang, A. (2021). Filler-polymer interaction investigated using graphitized carbon blacks: Another attempt to explain reinforcement. Polymer, 218, 123513.PlaggeJ.LangA. (2021). Filler-polymer interaction investigated using graphitized carbon blacks: Another attempt to explain reinforcement. Polymer, 218, 123513.Search in Google Scholar
Przygocki, W., & Włochowicz, A. (2001). Fulereny i nanorurki – Właściwosci i zastosowanie. Wydawnictwo Naukowo – Techniczne.PrzygockiW.WłochowiczA. (2001). Fulereny i nanorurki – Właściwosci i zastosowanie. Wydawnictwo Naukowo – Techniczne.Search in Google Scholar
Rodríguez-Prieto, A., Primera, E., Frigione, M., & Camacho, A. M. (2021). Reliability Prediction of Acrylonitrile O-Ring for Nuclear Power Applications Based on Shore Hardness Measurements. Polymers, 13(6), 943.Rodríguez-PrietoA.PrimeraE.FrigioneM.CamachoA. M. (2021). Reliability Prediction of Acrylonitrile O-Ring for Nuclear Power Applications Based on Shore Hardness Measurements. Polymers, 13(6), 943.Search in Google Scholar
Rosca, I. D., & Hoa, S. V. (2009). Highly conductive multiwall carbon nanotube and epoxy composites produced by three-roll milling. Carbon, 47(8), 1958–1968.RoscaI. D.HoaS. V. (2009). Highly conductive multiwall carbon nanotube and epoxy composites produced by three-roll milling. Carbon, 47(8), 1958–1968.Search in Google Scholar
Sajith, S. (2019). Investigation on effect of chemical composition of bio-fillers on filler/matrix interaction and properties of particle reinforced composites using FTIR. Composites Part B: Engineering, 166, 21–30.SajithS. (2019). Investigation on effect of chemical composition of bio-fillers on filler/matrix interaction and properties of particle reinforced composites using FTIR. Composites Part B: Engineering, 166, 21–30.Search in Google Scholar
Sivaselvi, K., Varma, V. S., Harikumar, A., Jayaprakash, A., Sankar, S., Krishna, C. Y., & Gopal, K. (2021). Improving the mechanical properties of natural rubber composite with carbon black (N220) as filler. Materials Today: Proceedings, 42, 921–925.SivaselviK.VarmaV. S.HarikumarA.JayaprakashA.SankarS.KrishnaC. Y.GopalK. (2021). Improving the mechanical properties of natural rubber composite with carbon black (N220) as filler. Materials Today: Proceedings, 42, 921–925.Search in Google Scholar
Smoleń, P., Czujko, T., Komorek, Z., Grochala, D., Rutkowska, A., & Osiewicz-Powęzka, M. (2021). Mechanical and Electrical Properties of Epoxy Composites Modified by Functionalized Multiwalled Carbon Nanotubes. Materials, 14(12), 3325.SmoleńP.CzujkoT.KomorekZ.GrochalaD.RutkowskaA.Osiewicz-PowęzkaM. (2021). Mechanical and Electrical Properties of Epoxy Composites Modified by Functionalized Multiwalled Carbon Nanotubes. Materials, 14(12), 3325.Search in Google Scholar
Terranova, M. L., Sessa, V., & Rossi, M. (2006). The World of Carbon Nanotubes: An Overview of CVD Growth Methodologies. Chemical Vapor Deposition, 12(6), 315–325.TerranovaM. L.SessaV.RossiM. (2006). The World of Carbon Nanotubes: An Overview of CVD Growth Methodologies. Chemical Vapor Deposition, 12(6), 315–325.Search in Google Scholar
Yadav, S. G., Guntur, N. P. R., N., R., & Gopalan, S. (2021). Effect of titanium carbide powder as a filler on the mechanical properties of silicone rubber. Materials Today: Proceedings, 46, 665–671.YadavS. G.GunturN. P. R.N., R.GopalanS. (2021). Effect of titanium carbide powder as a filler on the mechanical properties of silicone rubber. Materials Today: Proceedings, 46, 665–671.Search in Google Scholar
Yang, H., Yao, X., Zheng, Z., Gong, L., Yuan, L., Yuan, Y., & Liu, Y. (2018). Highly sensitive and stretchable graphene-silicone rubber composites for strain sensing. Composites Science and Technology, 167, 371–378.YangH.YaoX.ZhengZ.GongL.YuanL.YuanY.LiuY. (2018). Highly sensitive and stretchable graphene-silicone rubber composites for strain sensing. Composites Science and Technology, 167, 371–378.Search in Google Scholar
Yeganeh-Haeri, A., Weidner, D. J., & Parise, J. B. (1992). Elasticity of agr-Cristobalite: A Silicon Dioxide with a Negative Poisson’s Ratio. Science, 257(5070), 650–652.Yeganeh-HaeriA.WeidnerD. J.PariseJ. B. (1992). Elasticity of agr-Cristobalite: A Silicon Dioxide with a Negative Poisson’s Ratio. Science, 257(5070), 650–652.Search in Google Scholar
Zhang, X., Cai, L., He, A., Ma, H., Li, Y., Hu, Y., Zhang, X., & Liu, L. (2021). Facile strategies for green tire tread with enhanced filler-matrix interfacial interactions and dynamic mechanical properties. Composites Science and Technology, 203, 108601.ZhangX.CaiL.HeA.MaH.LiY.HuY.ZhangX.LiuL. (2021). Facile strategies for green tire tread with enhanced filler-matrix interfacial interactions and dynamic mechanical properties. Composites Science and Technology, 203, 108601.Search in Google Scholar
, 