Evaluating the Electrochemical Characteristics of Babassu Coconut Mesocarp Ethanol Produced to Be Used in Fuel Cells

The aim of the present study is to assess the potential of ethanol deriving from the mesocarp of babassu coconut to be used in fuel cells. Babassu ethanol was generated through hydrolysis and fermentation processes. The Pt, PtRh and PtRu electrodes were prepared in carbon Vulcan XC72R through the reduction method and applied as electrocatalysts in ethanol oxidation reaction. X-Ray diffraction (XRD), energy-dispersive X-ray (EDX), stripping CO, cyclic voltammetry, chronoamperometry, and online differential electrochemical mass spectrometry (DEMS) were used to characterize the synthesized eletrocatalysts. The electrocatalyst Pt80Ru20/C presented larger active area and higher catalytic activity than other studied materials. The current efficiency of CO2 production rated less than 1% in all studied electrocatalysts, thus showing that babassu ethanol oxidation produces less pollutants than the commercial ethanol.


Introduction
Fossil fuel exploitation has generated great negative impacts on the environment.Fuel discharge into rivers, seas and oceans is common, a fact that results in endangered animal species, as well as in fuel burnings that release CO 2 into the atmosphere.][3] Accordingly, ethanol has emerged as an alternative fuel source; Brazil only produces sugarcane ethanol for commercial purposes.However, ethanol can be made from a large variety of natural and renewable sources; it is obtained through the fermentation of many raw materials such as sugarcane, corn, beet and barley. 4abassu palm tree has great economic value, almost all its parts can be used in the food, handcrafting and power generation sectors. 5Babassu palm fruit has great economic potential since it is the raw material for a wide variety of products such as coal, oil, glycerin, ethanol, etc. 5 Babassu coconut mesocarp ethanol emerged as an alternative to the alcohol P.A. sold by big industries.
Ethanol is a fuel derived from renewable natural sources; therefore, it became one of the main alternatives to gasoline replacement, since it is less polluting and produced on large scale from raw materials of renewable nature. 6tarch is a clean carbon source widely used as ethanol feedstock but, in turn, it derives from sugar fermentation processes performed by microorganisms such as Saccharomyces cerevisiae. 7,8accharomyces cerevisiae is commonly used to produce ethanol on large scale; however, this microorganism is not capable of degrading starch molecules into sugars.Thus, starch needs to pass through a hydrolysis process in order to be used as raw material in sugar ethanol. 9he starch hydrolysis process requires water and chemical, or enzymatic, agents capable of breaking glycosidic bonds. 9Starch ethanol production demands the gelatinization step, in which starch is cooked, liquefacted and saccharificated to form sugars and ferment glucose into ethanol. 10,11thanol is the most outstanding alcohol among the several ones that show direct use in fuel cells.6][17] Ethanol complete oxidation reaction involves the transfer of 12 electrons per ethanol molecule, which leads to the generation of many adsorbed intermediates and by-products during the oxidation process. 17he kinetics of electrochemical oxidation of ethanol is slow; 13 therefore, studies have been devoted to develop catalysts to be used in the electrooxidation of this alcohol. 13latinum-based catalysts are the most often studied for alcohol oxidation purposes. 13,18,19Platinum is a noble metal of high catalytic activity; however, it is not able to oxidize carbon monoxide (CO) molecules into carbon dioxide (CO 2 ) at low power.Therefore, it requires using a second metal along with platinum to favor CO oxidation into CO 2 at lower potentials. 13,18etals such as rhodium and ruthenium are examples of metals commonly used along with platinum to produce electrocatalysts.These metals favor the adsorption of oxygenated species through water molecule activation, which leads to CO oxidation into CO 2 at low potentials.1][22][23] The bifunctional mechanism lies on the supply of a second metal containing oxygen species to platinum in order to oxidize the CO molecule into CO 2 and to release platinum catalytic surface to a new adsorption. 20,21he metal added to platinum in the electronic effect modifies the platinum electronic structure and leads to bonding force decrease in the CO molecule of the electrocatalyst surface. 22,23he objective of the present study was to develop and apply platinum-based nanoparticles to oxidize babassu coconut mesocarp ethanol, as well as to assess the chemical and electrochemical characteristics of this ethanol type by using the cyclic voltammetry (CV), chronoamperometry and differential electrochemical mass spectroscopy (DEMS) techniques.

Synthesis of electrocatalysts
The electrocatalysts Pt/C 20%, Pt80Rh20/C and Pt80Ru20/C were prepared through the alcohol reduction method, also known as polyol method, which is easy to be performed and allows nanoparticles to be produced in nanometer scale. 19The electrocatalysts were synthesized in 20% of metal mass and 80% Vulcan XC72R (Cabot) carbon support.The Vulcan carbon was treated with 5.0 mol L -1 HNO 3 in a reflux system for 5 h at a controlled temperature between 70-80 °C.After the reflux, the Vulcan carbon was washed with deionized water until pH 5 was reached (the water was distilled in a Fanem distiller model 724 and purified (18.2 mΩ cm) in a Millipore Milli-Q Academic system).The solid phase retained in the filter was then placed in an oven at 60 °C for 24 h. 19latinum, rhodium and ruthenium impregnation into the treated Vulcan carbon occurred due to the addition of precursor salt solutions and of an ethylene glycol/water solution (75/25, v/v).Such addition was conducted in order to get to the desired mass of each metal. 19The mixture was subjected to reflux system at controlled temperature (between 70 and 80 °C) for 2 h.The mixture was washed and filtered after reflux.The resulting solid phase was oven-dried at 70 °C for 24 h, then macerated and stored. 19,24talytic suspensions and electrochemical cell Catalytic suspensions were prepared with 5.0 mg of electrocatalyst, 1.0 mL of methanol due to its high volatility, 100 μL of Nafion and 1.4 mL of deionized water.It remained in ultrasound for 30 min to completely homogenize the mixture.25 The working electrode surface (vitreous carbon) was polished before catalytic suspension deposition through diamond spray, a water soluble spray manufactured with monocrystalline dimond powder.Next, it was washed in deionized water and left to dry.A total of 20 μL of catalytic suspension was added to the surface of the working electrode; the solvent was evaporated through hot air flow, using a hair dryer.

Methods to set the physico-chemical characteristics X-Ray diffraction (XRD)
The X-ray diffractograms were taken in Rigaku diffractogram model ULTIMA IV by using Cu Kα radiation.The crystallite sizes and network parameters of the electrocatalysts were calculated based on XRD analysis results of the plane (220) of the platinum face-centered cubic (fcc) through Scherrer's equations 1 and 2, respectively: 24,25 (1) (2)  wherein d is the mean crystallite size; p is the lattice parameter; λ is the wavelength of the used radiation, in which Cu Kα is equal to 1.54056 Å; k is a constant equal to 0.9, when the crystallites are assumed to have spherical morphology; B 2θ is diffraction peak width at half height in radian; and θ is the Bragg angle, in degrees, to the maximum height point of the analyzed peak. 25ergy-dispersive X-ray (EDX) Electrocatalyst atomic compositions were set through X-ray dispersive energy analysis conducted in the scanning electron microscope Phenom-World ProX.

CO stripping
Electrocatalyst active areas were set according to the CO stripping method. 25,26The adopted system was the same one used in cyclic voltammetric analysis, although it was performed in exhaust hood.The CO was bubbled into the supporting electrolyte solution for 5 min, next, nitrogen was bubbled for 10 min. 25,26The method has been used since 1960 26 and allows to determine the electric charge (mC) required to remove CO monolayers from the surface of catalysts during an anode oxidation. 25,26clic voltammetry and chronoamperometry Cyclic voltammetry and chronoamperometry were performed in an Autolab PGSTATXX (Metrohm) equipment coupled to a computer.Electrocatalyst voltammograms were taken in a one-chamber electrochemical glass cell containing a reference hydrogen electrode (RHE) prepared with the same sulfuric acid solution used as electrolyte carrier, as well as with a working (glassy carbon), a counter and a platinum electrodes.Ethanol electrooxidation studies were carried out in 0.1 mol L -1 ethanol solutions in 0.5 mol L -1 H 2 SO 4 medium at range 0.03-1.0V, and scanning speed 10 mV s -1 in system purged with N 2 .19

Online DEMS
The online DEMS analysis was performed according to the methodology described in the literature, 27 with a single compartment cell with input for the electrodes: work, auxiliary and reference, plus gas inlet and temperature controller.
The electrodes were prepared through sputter deposition (gold) on a Teflon membrane (50 nm thick) for the DEMS analysis.The Teflon membrane was added with 180 μL of aqueous suspension containing the catalytic material.A mixture containing 2 mg of catalyst powder and 25 μL of Nafion was done to assure catalytic material adhesion. 27olatiles deriving from babassu coconut mesocarp ethanol oxidation were monitored according to m/z 44 and 22, which correspond to the ionized [CO 2 ] + and doubly ionized [CO 2 ] 2+ , in addition to the acetaldehyde signals m/z 29 and 44, which correspond to [CHO] + and [CH 3 CHO] + , respectively.It was decided to monitor CO 2 and acetaldehyde formation through m/z 22 and 29, which correspond to the species [CO 2 ] 2+ and [CHO] + , respectively, since the m/z 44 signal may correspond to the ionized [CO 2 ] + and [CH 3 CHO] + species. 27,28

Results and Discussion
Physico-chemical characterization of the synthesized eletrocatalysts XRD Diffractograms of metal alloys Pt80Rh20/C, Pt80Ru20/C and Pt/C are shown in Figure 1.Peaks at approximately 2θ = 39, 45, 67 and 81° are assigned to planes (111), ( 200), (220), and (311), respectively, of platinum face-centered cubic (fcc) and of platinum containing metal alloys. 24,25ectrocatalyst crystallite sizes and the lattice parameters were calculated based on the peak associated with the platinum plane (220), because this plane is less influenced by the carbon carrier C (002). 25 The mean crystallite size values of each electrocatalyst are shown in Table 1.It is possible to notice that the crystallite sizes of the bimetallic electrocatalysts are smaller than those of the Pt/C monometallic electrocatalyst.Therefore, the bimetallic electrocatalysts have larger surface areas and, consequently, more catalytic activity. 24,28attice parameters values are shown in Table 1.These results evidence that bimetallic electrocatalysts record lower net parameter values than the Pt/C monocatalyst.Such result indicates Pt80Rh20/C and Pt80Ru20/C formation. 24The lattice parameters values of the electrocatalysts are similar to those found in literature, 24,28 which used catalysts prepared through the alcohol reduction method to assess ethanol oxidation.

EDX
Synthesized and evaluated electrocatalyst compositions were defined through the EDX technique, which allows us to evaluate the atomic composition of a compound in a given region of the sample (Table 2).Because EDX is a point technique, it gives us indications about the content of chemical elements found in a certain point of the sample studied.

Electrochemical characterization of synthesized electrocatalysts
Determining the active areas of electrocatalysts through CO stripping Figure 2 shows the CO adsorption cyclic voltammograms of different electrocatalysts in 0.5 mol L -1 H 2 SO 4 solution.
It was possible to set the active areas of the electrodes (AAE) through equation 3 based on the electrical charges of adsorbed CO (CO ads ) (Table 3) found after integrating the highlighted areas in the voltammograms. 25,26) wherein (mC) is the CO adsorption charge of the cyclic voltammetries in Figure 2; and Q CO is the theoretical electrical charge required to oxidize a CO monolayer in Pt (420 μC cm -2 ).26 Determination through the cyclic voltammetry of the amount of charge (Table 3) required to oxidize a CO monolayer adsorbed by a platinum electrode must take into consideration that the CO molecule is adsorbed by each platinum atom.25,26 The determined AAE values are shown in Table 3. Alcohol oxidation in the fuel  cell may present higher catalytic sample activity 24 in the case of bimetallic catalysts.

Electrocatalytic performance
Figure 3 shows the cyclic voltammetry curves of different electrocatalysts supported on Vulcan carbon in 0.5 mol L -1 H 2 SO 4 medium, in absence of ethanol.The profile of the synthesized bimetallic electrocatalysts presents the hydrogen region (0.03-0.4 V) in a much more clear fashion than the monometallic electrocatalyst; there are peaks showing hydrogen adsorption and desorption. 12,24e bimetal electrocatalysts supported on Vulcan carbon Pt80Rh20/C and Pt80Ru20/C showed slight increase in currents in the electric double layer (0.4-0.8 V) region in comparison with the Pt/C monometallic catalyst.Oxides formed on the catalyst surface, due to the addition of other metal to platinum in the catalyst composition, helped increase the active area of the synthesized electrocatalysts and, consequently, gave them greater oxidative power. 12,24igure 4 shows the voltammetric profiles of different electrocatalysts (Pt/C, Pt80Rh20/C and Pt80Ru20/C) deposited on Vulcan carbon in the presence of 0.1 mol L -1 commercial ethanol (Figure 4a) and 0.1 mol L -1 babassu ethanol (Figure 4b).The current densities were normalized by the electrocatalytic surfaces of the electrocatalysts, which were estimated through the electrooxidation of a CO monolayer adsorbed on the working electrode.4 evidenced that the electrocatalyst Pt80Ru20/C proved to be more efficient in the oxidation of both herein studied alcohols (babassu and commercial ethanols).The process triggers oxidation at potentials lower than that of other electrocatalysts: approximately 100 mV less than the platinum monometallic electrocatalyst; besides, it presents higher current density in the studied alcohols.Similar results were recorded by Ribeiro et al. 12 In order to determine the oxidation initiation potential in all catalysts, the point where no current oscillation occurs was verified.From this point, the current went up until the complete oxidation of the products.

Data in Table
Figure 4 shows that the maximum current density in all electrocatalysts of the babassu coconut mesocarp ethanol occurs in potentials lower than 0.8 V, while for commercial ethanol, the maximum current occurs only after 0.8 V.According to Pech-Rodrígues et al., 25 who assessed ethanol oxidation, the ethanol molecule undergoes complex molecule dissociation and adsorption mechanisms, C-C binding breakage and dehydrogenation to achieve complete ethanol oxidation into CO 2 .There is intermediate formations such as carboxylic acid, aldehyde and carbon monoxide, which poison the Pt catalyst. 25,28thanol equilibrium equations 4-6 in acidic medium, with main products and the balance of generated electrons are herein presented.
The electrocatalyst presenting the highest electric current density was the bimetallic electrocatalyst Pt80Ru20/C in the two studied alcohols; this electrocatalyst showed its high catalytic power.On the other hand, the Pt/C monometallic electrode presented lower electrical current density in the oxidation of both alcohols.
However, the catalytic activity of an electrocatalyst is given by the potential in which the alcohol redox process is triggered, i.e., the lower the oxidation/reduction initiation potential, the greater its catalytic power. 19It is known that the Pt/C monometallic electrocatalyst is not a good oxidizing agent to electrooxidize ethanol, because of the poisoning caused by the strong adsorption of reaction intermediates such as CO ads . 12,29Thus, the monometallic catalyst was the least efficient synthesized catalyst against alcohol oxidation reaction among all the synthesized ones.It initiated oxidation at potentials above 0.25 V, thus revealing that the use of other metal next to platinum on the carbon support significantly increases the catalytic power of the electrocatalyst and decreases the cost with rare earth metals. 29ssumingly, both herein assessed alcohols have very similar profiles, their oxidation starts at very close potentials in all the synthesized electrocatalysts tested in the present study.

Chronoamperometry
Electrode equilibrium time at 0.6 V potential and electrocatalyst poisoning in active areas of continuous operation for 15 min were assessed through chronoamperometry analysis.Figure 5 shows how the chronoamperometry curves (current density vs. time) of different synthesized electrocatalysts have their current density normalized by the active area of the respective electrodes.
The curves of the assessed commercial ethanol and babassu seen in Figure 5 show remarkable decay in the electric current density during the first seconds of  the analysis.Such decay was followed by slow decay throughout the following minutes; however, it remained constant during the remaining analysis time.
Ribeiro et al. 12 studied alcohol oxidation and concluded that ethanol molecules can be adsorbed onto sites that were initially covered by water molecules at potentials below 0.4 V.After adsorption, the ethanol molecule can dissociate itself and produce CO molecules strongly adsorbed by the electro surface along with other reaction intermediates.Oxygenated species, such as OH ads , adsorbed by the electrode surface are necessary for the ethanol molecule to be completely oxidized, a fact that leads to CO 2 formation or to the formation of acetic acid molecules. 3,12esults of the chronoamperometry analysis validate the herein conducted cyclic voltammetry analysis, since the electrode with the highest electric current density in the commercial ethanol oxidation was the electrocatalyst Pt80Ru20/C, followed by Pt80Rh20/C and Pt/C.The same was recorded for babassu mesocarp ethanol oxidation, in which the Pt80Ru20/C electrode recorded the highest electrical current density, followed by the Pt80Rh20/C and Pt/C electrodes.These results follow the same order of cyclic voltammetric analysis at 0.6 V potential, which is used in chronoamperometry studies.

Online DEMS of babassu coconut mesocarp ethanol
Load signal m/z 22 calibration was necessary to quantify part of the total electrooxidation current of ethanol into CO 2 , according to results recorded through online DEMS. 3,27,28,30,31Figure 6 shows the stripping of CO results from acidic medium, 0.5 mol L -1 H 2 SO 4 , 10 mV s -1 , of the used electrocatalysts.The CO stripping was used as electrochemical reaction reference, since the number of electrons exchanged during CO electrooxidation adsorbed by the surface of the working electrode, CO 2 is already well known, as can be observed in equation 7. 30,32 CO ads + H 2 O → CO 2 + 2H + + 2e - Figure 6 shows the signals of the m/z 22 and 44 analyzed through DEMS during the acid stripping of CO, 0.5 mol L -1 H 2 SO 4 , 10 mV s -1 .The m/z 22 signal is attributed to doubly ionized CO 2 ([CO 2 ] 2+ ) production during the electrooxidation of ethanol in the online electrochemical mass spectrometry. 28,30,31The m/z 44 signal is also used in the literature to quantify ionized CO 2 ([CO 2 ] + ); however, this signal is also attributed to acetaldehyde ([CH 3 CHO] + ).Therefore, the m/z 22 signal was used in order to not compromise CO 2 quantification results. 28,30,31e ionic currents of signal m/z 22 and the faradaic current recorded through stripping of CO of different electrocatalysts can be correlated through equation 8: 3,31 (8) I m/z 22,CO is the current of the mass/charge signal m/z 22; I f,CO is the faradaic current of the CO stripping; 2 is the number of electrons exchanged during CO electrooxidation into CO 2 ; and K * 22 is the calibration constant of signal m/z 22, which is required to quantify part of the current deriving from ethanol electrooxidation into CO 2 . 30,31The K * 22 values of different electrocatalysts used in the present study are shown in Table 5.

Ethanol oxidation reaction (EOR)
It is known that the EOR into CO 2 (at balance 12e -per ethanol molecule) can be incomplete due to different paths.Such result leads to acetaldehyde (at balance 2e -per ethanol molecule) and acetic acid (at balance 4e -per ethanol molecule) formation.The kinetic mechanisms involved in EOR have been widely studied. 3,27,31hus, products from the electrooxidation reaction of babassu coconut mesocarp ethanol using Pt/C, Pt80Rh20/C and Pt80Ru20/C electrocatalysts were monitored through online DEMS.The CO 2 formation was monitored through mass/charge signal m/z 22, which corresponds to the double ionized ion [CO 2 ] 2+ .Acetaldehyde formation was followed by signal m/z 29, which corresponds to [CHO] + . 3,27,31igure 7 shows the cyclic voltammograms of DEMS recorded during electrooxidation experiments involving carbamate coconut mesocarp ethanol at 0.1 mol L -1 in 0.5 mol L -1 H 2 SO 4 acid medium, in the synthesized electrocatalysts Pt/C, Pt80Rh20/C and Pt80Ru20/C.These results evidence that bimetallic electrocatalysts present higher current densities and initiate potential ethanol oxidation at 0.3 V, on average, whereas Pt/C monometallic electrocatalyst initiates ethanol oxidation at potential 0.4 V, on average.Such phenomenon can be explained by the fact that the dehydrogenation process more often occurs in bimetallic electrocatalysts. 3,27,31igure 7 shows mass signals m/z 22, 29, and 44, which were analyzed through DEMS during babassu coconut mesocarp ethanol oxidation reaction experiments.Results show that CO 2 (m/z 22, [CO 2 ] 2+ ) formation starts at 0.5 V, on average, in all the used electrocatalysts.These electrocatalysts present ionic current values at potential close to 0.8 V, but the bimetallic electrocatalysts record higher ionic current densities.
On the other hand, acetaldehyde formation, accompanied by signal m/z 29, which corresponds to the [CHO] + fragment, starts at potentials lower than 0.4 V.It presents ionic current densities higher than the ionic current densities attributed to CO formation.The bimetallic electrocatalysts Pt80Rh20/C and Pt80Rh20/C stand out in relation to the Pt/C monometallic electrocatalyst.All the electrocatalysts presented maximum near-current densities of approximately 0.7 V.These results show that acetaldehyde (m/z 29 [CHO] + ) is the major product in the process of alcohol oxidation of babassu coconut mesocarp, since this product presented higher currents and initiation of potential formation smaller than those shown for the CO 2 signals. 27he CO 2 current efficiency in the different herein used electrocatalysts was set based on the faradaic and ionic current values recorded during babassu coconut mesocarp ethanol oxidation reaction through equation 9: 3,27,31 (9) wherein is the CO 2 current efficiency expressed in percentage; the factor 6 refers to the number of electrons needed for the formation of one CO 2 molecule from ethanol; I m/z 22 is the ion current corresponding to the signal m/z 22; If is the faradaic current resulting from the ethanol oxidation reaction; and K * 22 is the calibration constant of signal m/z 22. 3,27,28 The CO 2 current efficiency results, , of different electrocatalysts used during the oxidation reaction of babassu coconut mesocarp alcohol are shown in Table 6.
The values shown in Table 6 show that electrocatalysts Pt/C, Pt80Rh20/C and Pt80Ru20/C contain CO 2 current efficiency below 1%.It evidences that the largest portion of babassu coconut mesocarp ethanol oxidation is formed by acetaldehyde, which has less environmental impact than the CO 2 released into the atmosphere during fuel burning.Studies such as that by Queiroz et al. 27 present CO 2 efficiency calculations performed through DEMS to assess commercial ethanol oxidation.It was done by using different platinum-based electrocatalysts values, and between 2 and 20% of currents are attributed to CO 2 formation, which suggests that the oxidation of commercial ethanol using platinum-based electrocatalysts leads to CO 2 formation up to 20 times higher than the babassu coconut mesocarp ethanol oxidation using the same electrocatalyst types. 27The research shows the oxidation of babassu coconut mesocarp ethanol is low polluting.

Conclusions
The method to prepare the electrocatalysts proved to be very effective and of good metal dispersion on the Vulcan carbon support.The bimetallic electrocatalysts showed better performance than the Pt/C monometallic catalyst when it comes to the oxidation reaction of the alcohols assessed in acid medium.The bimetallic electrocatalysts Pt80Rh20/C and Pt80Ru20/C presented very approximate compositions of the values obtained by EDX, the largest active areas and the best catalytic activity, thus demonstrating that the addition of a second metal to platinum helps get better electrocatalyst performance.
DEMS studies showed that all electrocatalysts assessed during the alcohol oxidation reaction of babassu mesocarp presented CO 2 current efficiency close to 1%.It means that most evaluated ethanol oxidation products are acetaldehyde, which is less harmful to the environment than CO 2 released during the oxidations of fuels.
Results recorded in the present study show that babassu coconut mesocarp ethanol has potential to be used in fuel cells.Due to its ability to oxidize producing small amount of CO 2 and higher amount of acetaldehyde, it is less harmful to the environment.In addition, babassu coconut ethanol has similar behavior to commercial ethanol in terms of its energy density.

Figure 2 .
Figure 2. Cyclic voltammetry to find the active areas in the studied electrocatalysts: (a) Pt/C, (b) Pt80Rh20/C and (c) Pt80Ru20/C in 0.5 mol L -1 H 2 SO 4 , 10 mV s -1 scan rate, purged by CO and N 2 for 5 and 10 min, respectively.

Table 1 .
Lattice parameters and crystallite size of electrocatalysts Pt/C, Pt80Rh20/C and Pt80Ru20/C

Table 2 .
Experimental compositions of Pt/C, Pt80Rh20/C and Pt80Ru20/C electrocatalysts set through EDX

Table 3 .
Load needed to oxidize CO (C) monolayer and to activate electrocatalysts areas determined through CO stripping

Table 4 .
Initial oxidation potential and current at potential 0.6 V in electrocatalysts Pt/C, Pt80Rh20/C and Pt80Ru20/C in commercial ethanol medium and 0.1 mol L -1 babassu ethanol in 0.5 mol L -1 H 2 SO 4

Table 6 .
Effective current rate of CO 2 (Aq CO 2 ) during the electrooxidation of babassu coconut mesocarp ethanol at concentration of 0.1 mol L -1 in different synthesized electrocatalysts