Today there are several new and interesting Nano-particle materials on the market providing good electrical conductivity. Examples are carbon Nano-tubes and different versions of graphene derivatives, often provided as powder. In particular, the materials available were Multi-Walled Carbon Nanotubes in Epoxy matrix and Reduced Graphene Oxide (rGOH). An initial literature survey underlined the lack of measurements and information about the conductivity of these materials during heating up or curing. This work is part of a larger project aiming at producing ”sensing structural composite material”, i.e. a composite material with integrated Nanoparticles, as eg. Carbonnano-tubes or graphene, working as sensors reporting the status of the material during heating up, curing and/or tensioning. The principal results concerns the evaluation of the specific conductivity during heating for both materials (rGOH and MWCNT in Epoxy Matrix) with the realization of an experimental model for the gradient of the specific conductivity with temperature. The linearity underlines the possibility of using the properties of these materials to create sensors, not only for strain (with the advantage of high Gauge Factors), but also for temperature

D. Passato

G. Petrone

M. Akermo

P. Hallander

S. De Rosa

English

Archivio della ricerca - Università degli studi di Napoli Federico II

MEDYNA 2020: 3rd Euro-Mediterranean Conference on Structural Dynamics and Vibroacoustics17-19 February 2020, Napoli (Italy)EXPERIMENTAL STUDY OF GRAPHENE AND CARBONNANOTUBES THERMAL SENSING PROPERTIESD. Passato 1 , M. Akermo2, P. Hallander3, S. De Rosa1 and G. Petrone11PASTA LabUniversita’ degli Studi di Napoli Federico II, Napoli, ItaliaEmail: d.passato@studenti.unina.it, sergio.derosa@unina.it, giuseppe.petrone@unina.it2Aeronautical and Vehicle EngineeringKTH, Stockholm, SwedenEmail: akermo@kth.se3SAAB AB SE-581 88Linkoping,SwedenABSTRACTToday there are several new and interesting Nano-particle materials on the market providing goodelectrical conductivity. Examples are carbon Nano-tubes and different versions of graphene deriva-tives, often provided as powder. In particular, the materials available were Multi-Walled CarbonNanotubes in Epoxy matrix and Reduced Graphene Oxide (rGOH). An initial literature survey un-derlined the lack of measurements and information about the conductivity of these materials duringheating up or curing. This work is part of a larger project aiming at producing ”sensing structuralcomposite material”, i.e. a composite material with integrated Nanoparticles, as eg. Carbon-nano-tubes or graphene, working as sensors reporting the status of the material during heating up,curing and/or tensioning. The principal results concerns the evaluation of the specific conductivityduring heating for both materials (rGOH and MWCNT in Epoxy Matrix) with the realization ofan experimental model for the gradient of the specific conductivity with temperature. The linearityunderlines the possibility of using the properties of these materials to create sensors, not only forstrain (with the advantage of high Gauge Factors), but also for temperature.MEDYNA 2020 17-19 February 2020, Napoli (Italy)1 INTRODUCTION: CARBON NANOTUBES AND GRAPHENEThe principal aim of this experimental work is to study thermal sensible properties of Graphene andMulti Walled Carbon Nanotubes (MWCNT). In particular, the materials available for experimentalinvestigations are Carbon Nanotubes in Epoxy matrix and Reduced Graphene Oxide (rGOH).Carbon nanotubes (CNTs) are tubes made of carbon with diameters typically measured innanometers. Carbon nanotubes often refers to single-wall carbon nanotubes (SWCNTs) with di-ameters in the range of a nanometer. They were discovered independently by Iijima and Ichihashi[1] and Bethune et al. [2] in carbon arc chambers similar to those used to produce fullerenes. Car-bon nanotubes also often refer to multi-wall carbon nanotubes (MWCNTs, also sometimes usedto refer to double- and triple-wall carbon nanotubes) consisting of nested single-wall carbon nan-otubes. Carbon nanotubes can exhibit remarkable electrical conductivity. They also have excep-tional tensile strength and thermal conductivity, because of their nanostructure. These propertiesare expected to be valuable in many areas of technology, such as electronics, optics, compositematerials (replacing or complementing carbon fibers), nanotechnology, and other applications ofmaterials science.A more detailed view has been considered on the effect of CNT inside Epoxy matrix. Themechanical and electrical properties of the composite with different weight percentages of nan-otubes have been investigated in [3]. Conductivity measurements on the composite samples showedthat the insulator-to-conductor transition took place for nanotube concentration between 0.5% and 1wt.%. The electrical and thermal conductivities of epoxy composites containing 0.005 \ 0.5 wt% ofsingle-walled (SWNTs) or multi-walled (MWNTs) carbon nanotubes have been also studied in [4].The MWNT composites had an electrical percolation threshold of 0.005 wt%, whereas the thermalconductivity of the same samples increased very modestly as a function of the filler content.Graphene is an allotrope of carbon in the form of a single layer of atoms in a two-dimensionalhexagonal lattice in which one atom forms each vertex. Graphene has a special set of propertieswhich set it apart from other allotropes of carbon. In proportion to its thickness, it is about 100times stronger than the strongest steel. It conducts heat and electricity very efficiently and is nearlytransparent. In its traditional form, graphene is one atomic layer thick and usually exists as a filmof sorts; however, the proliferation of graphene research and testing has led to the creation of vari-ous graphene forms, each used for unique purposes. These forms include graphene films producedthrough chemical vapor deposition (CVD), graphene oxide (GO), reduced graphene oxide (rGO)and graphene nanoplates (GNPS). The material studied in this thesis project was Reduced GrapheneOxide. There are numerous ways to produce rGO such as annealing, hydrazine vapor treatment,and microwave reduction.Studies conducted on thin graphene layers underline the possibility of temperature sensingapplications. In [5], a temperaturedependent study of thermal (10300 K) and electrical (103000K) transport in annealed RGO films indicates the potential application of RGO films for sensingtemperatures across an extremely wide range. Also applications with a highperformances flexibletemperature sensor composed of polyethyleneimine and rGO have been realised [6]. The preparedsensor exhibits high sensitivity (1.30% ◦C−1), linearity (R2 = 0.999), accuracy (0.1 ◦C), and dura-bility (60 d) for temperature sensing between 25 and 45 ◦C.2 EXPERIMENTAL2.1 Set-UpPrincipally the evaluation of the specific conductivity of the different materials has been realizedby a Bio-Logic Potentiostat and two different ovens. Temperature measurements in the ovens havebeen made by a thermocouple and the different geometric data have been measured using a caliber.To collect data from different sources a LabView Script has been realized. Finally Matlab has beenused to post process results.2.2 MWCNTs in Epoxy MatrixAs concerns the CNTs forest impregnated by a epoxy film (from Hexcel) on Steel Sheets, themean value of conductivity for cured samples is about 0.24 (S/m). Moreover the variance of thevalues obtained from different samples (with different number of layers and different geometry) is2MEDYNA 2020 17-19 February 2020, Napoli (Italy)6.7× 10−4. It was also interesting to collect data on the level of current during heating up in orderto study the sensing properties of the Carbon Nanotubes.Figure 1. Sample and Measurements during curingConsidering the geometry of the sample a value of dσ/dT (S/m)/◦C has been get. The mean valueof dσ/dT is 3.45E-4 (S/m)/◦C. The value of conductivity during the cure has been also measured.On average the value of conductivity has been increased by the treatment (considering the value0.24 S/m), but the values are not stable. After that, the support of the nanotubes has been replaced,using a carbon fibre prepreg. The principal problem with this kind of acquisition is linked with themechanical characteristics of the prepreg before curing. Moreover the curing process has squeezedthe matrix making not easy the following measurements. The principal problem is linked with theclamping and with the fact that the samples do not offer a continuum field for the propagation ofthe current. To understand (at least) if there is a dependence from the temperature of the value ofthe conductivity, the samples have been tested during heating up and cooling down cycle: there isa dependence from the temperature of the value of the current (we can see it considering the abruptdecreasing of current after the abrupt cooling down).2.3 Graphene (rGOH)As for the MWCNT we studied the conductivity of a Reduced Hydrogenated Graphene Oxide (acoated Kapton film from Danubia NanoTech [7]) in different conditions starting from a SingleLayer configuration. Each layer is 0.5cm*4cm. First of all, a single layer of rGOH has beenanalysed. Clearly, to define a conductivity is necessary to define the resistivity of the material. Inthis case is not simple because we should have the area of the cross section of the film. Graphenefilms exhibits a stable behaviour. The value of the current seems to depend weakly from the sampleand clearly the difference is due to different geometric characteristics and imperfections. The lawtesion/current is linear. At this point, we put the graphene layer inside a prepreg sandwich made upof 4 layers. We have noticed a weak growth of the current for a fixed level of voltage (1V ) from theprevious test. This phenomenon could be explained considering that the prepreg has a better valueof conductivity, so putting the film inside it we increase the global conductivity of the sample. Atthis point the samples have been cured under vacuum. In order to avoid the oxidation of the film,we waited the Tamb before removing the samples from the vacuum pump. After that we have testedthe samples with the potentiostat at Tamb. The value of conductivity seems to be unchanged. Thenext step has been to measure the level of current for a fixed voltage during heating up. In Figure2.3, the Temperature is measured in the oven, while the sensor measures inside the material. Thedelayed signal is therefore due to heating up. Moreover, to avoid the oxidation of the samples, theyhave been placed under vacuum. This has made the measurements quite unstable and complicated:first of all the action of the vacuum make worse the grip of the cable, then, since the film is veryfragile, the action of the pup has destroyed most of the samples. For the survived ones we haverealized a linear model where the samples exhibit a linear behaviour increasing temperature. Usingthat linear model we obtain a value of dI/dT = 0.0001173 with a Root Mean Squared Error:0.000346. (according to the F-test we can apply the linear model; F-statistic vs. constant model:739, p-value = 1.08e-34). Further tests should be done to have a more numerous selection of valuesof the dI/dT , but the principal future goal is to find a way to test the samples under vacuum withoutdestroying the most of them!3MEDYNA 2020 17-19 February 2020, Napoli (Italy)Figure 2. Sample and Measurements during Heating3 CONCLUSIONTalking about the MWCNTs, the most of the results have been obtained for the case study ofMetal Sheets with MWCNTs inside epoxy matrix. In this case there were enough data to realizeand experimental linear model for the gradient of the specific conductivity with temperature. Asconcerns rGOH, also this time we could estimate a value for the dσ/dT , but probably the mostinteresting results is that to perform this kind of experiment a complete different set-up is needed inorder to measure in a more easily way the current through the material. A solution could be the useof an hot press. Another important result is that to avoid the oxidation of the graphene film duringheating and curing, the measurement of the conductivity must be realized in a vacuum package.On the whole, we can say that the linearity of the law dσ/dT underlines the possibility of usingthe properties of these materials to create sensors, not only for strain (with the advantage of highGauge Factors), but also for temperature.ACKNOWLEDGEMENTSThe project was performed as an initials study within the Vinnova funded project Cosing. LinneaSelegrd and SAAB Aeronautics is acknowledged for fruitful discussions and supply of CNT. VieraSkakalov at Danubia Nanotech has kindly supported with knowledge and rGOH film.REFERENCES[1] Sumio Iijima and Toshinari Ichihashi. Single-shell carbon nanotubes of 1-nm diameter.363(6430):603–605, Jun 1993.[2] D. S. Bethune, C. H. Klang, M. S. de Vries, G. Gorman, R. Savoy, J. Vazquez, and R. Beyers.Cobalt-catalysed growth of carbon nanotubes with single-atomic-layer walls. 363(6430):605–607, Jun 1993.[3] A Allaoui, S Bai, H.M Cheng, and J.B Bai. Mechanical and electrical properties of amwnt/epoxy composite. Composites Science and Technology, 62(15):1993 – 1998, 2002.[4] A. Moisala, Q. Li, I.A. Kinloch, and A.H. Windle. Thermal and electrical conductivity ofsingle- and multi-walled carbon nanotube-epoxy composites. Composites Science and Tech-nology, 66(10):1285 – 1288, 2006.[5] Yuqiang Zeng, Tian Li, Yonggang Yao, Tangyuan Li, Liangbing Hu, and Amy Marconnet.Thermally conductive reduced graphene oxide thin films for extreme temperature sensors. Ad-vanced Functional Materials, 29(27):1901388, 2019.[6] Qingxia Liu, Huiling Tai, Zhen Yuan, Yujiu Zhou, Yuanjie Su, and Yadong Jiang. A high-performances flexible temperature sensor composed of polyethyleneimine/reduced grapheneoxide bilayer for real-time monitoring. Advanced Materials Technologies, 4(3):1800594, 2019.[7] https://www.danubiananotech.com.4

Experimental study of graphene and carbon nanotubes thermal sensing properties

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Experimental study of graphene and carbon nanotubes thermal sensing properties

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