Method of synthesizing manganese oxide nanocorals

Abstract

A method of synthesizing manganese oxide nanocorals comprises the steps of a) heating a potassium permanganate solution; (b) providing manganese sulfate in a basic solution; (c) combining the manganese sulfate basic solution drop-wise with the heated potassium permanganate solution until a brown precipitate is formed; (d) stirring the brown precipitate for a period of about 12 hours at a temperature greater than 300 K; (e) isolating the precipitate; and (f) drying the precipitate inside an oven at a temperature greater than 300 K to provide manganese oxide nanocorals. The manganese oxide nanocorals include nanowires having a diameter typically ranging from about 20 nm to about 40 nm.

Claims

1. A method of synthesizing manganese oxide nanocorals comprising: (a) heating a potassium permanganate solution; (b) providing manganese sulfate in a basic solution; (c) adding the manganese sulfate basic solution drop-wise to the heated potassium permanganate solution until a brown precipitate is formed; (d) stirring the brown precipitate at a temperature greater than 300 K; (e) isolating the precipitate; and (f) drying the precipitate to provide the manganese oxide nanocorals.

2. The method of synthesizing manganese oxide nanocorals according to claim 1, wherein the potassium permanganate solution is heated to a temperature of about 343 K.

3. The method of synthesizing manganese oxide nanocorals according to claim 1, wherein the brown precipitate is dried in an oven at a temperature of about 383 K.

4. The method of synthesizing manganese oxide nanocorals according to claim 1, wherein the brown precipitate is stirred for about 12 hours.

5. The method of synthesizing manganese oxide nanocorals according to claim 1, wherein the potassium permanganate solution is stirred at 600 rpm.

6. The method of synthesizing manganese oxide nanocorals according to claim 1, wherein the manganese oxide nanocorals include nanowires having a diameter of about 20 nm to about 40 nm.

7. The method of synthesizing manganese oxide nanocorals according to claim 1, wherein the manganese oxide nanocorals have a sea coral shape.

8. The method of synthesizing manganese oxide nanocorals according to claim 1, wherein the manganese oxide nanocorals have an orthorhombic -MnO.sub.2 phase.

9. The method of synthesizing manganese oxide nanocorals according to claim 1, wherein the manganese oxide nanocorals have a B.E.T. specific surface area of about 168.9 m.sup.2 g.sup.1 and a total pore volume of about 0.0742 cm3 g.sup.1.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

(1) FIG. 1 shows the X-ray powder diffraction (XRD) pattern for the manganese oxide nanocorals (MONCs).

(2) FIGS. 2A-2B show the scanning electron microscope (SEM) images for the MONCs.

(3) FIG. 3 shows transmittance electron microscope (TEM) images for the MONC nanowires.

(4) FIG. 4 is a graph showing the time-on-line data for the conversion of CO to CO.sub.2 using MONCs at different temperatures, using 0.1 g MONCs.

(5) FIG. 5 is a graph showing the time-on-line data for the conversion of CO to CO.sub.2 using different amounts of MONCs.

(6) Similar reference characters denote corresponding features consistently throughout the attached drawings.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS

(7) A method of synthesizing manganese oxide nanocorals (MONCs) includes combining a manganese sulfate basic solution with a potassium permanganate solution. The potassium permanganate solution can be heated, for example to a temperature of about 343 K (70 C.), and stirred at a speed of about 600 rmp using a heater/magnetic stirrer prior to combining with the manganese sulfate basic solution. The manganese sulfate basic solution can be added drop-wise to the potassium permanganate solution until a brown precipitate is formed. The brown precipitate can be stirred at a temperature greater than 300 K. For example, the brown precipitate can be heated to a temperature of about 343 K and stirred overnight or for a period of about 12 hours. The brown precipitate can be isolated and dried inside an oven, e.g., at a temperature greater than 300 K, e.g., 383 K, to provide manganese oxide nanocorals. The manganese oxide nanocorals can include nanowires having a diameter ranging from about 20 nm and 40 nm and typically. The manganese oxide nanocorals can have a sea coral shape. The manganese oxide nanocorals can include nanocrystalline orthorhombic -MnO.sub.2 phase. The manganese oxide nanocorals have Brunauer, Emmett and Teller (B.E.T.) surface area equal to about 168.9 m.sup.2 g.sup.1, and total pore volume of about 0.0742 cm.sup.3 g.sup.1.

(8) The manganese oxide nanocorals can be used to remove toxic carbon monoxide from air by oxidizing CO. The method of converting carbon monoxide to carbon dioxide can comprise passing carbon monoxide and oxygen at a ratio of 1:1 over manganese oxide nanocoral surface at a fixed temperature and at a fixed applied pressure. The temperature is held between 348 to 423 K and the pressure is held at about 4 Torr. The process can be endothermic. The conversion efficiency from carbon monoxide to carbon dioxide is generally 100%. For example, 100% conversion can be achieved within 50 minutes using about 0.1 gram MONCs at 423 K, or within 60 minutes using 0.2 gram MONCs at 348 K, or within 30 minutes using about 0.4 gram MONCs at 348 K. The following examples will further illustrate the synthetic processes of making the manganese oxide nanocorals and its application in removing carbon monoxide.

EXAMPLE 1

Synthesis of the MONCs

(9) Potassium permanganate solution (75 ml, 0.5M) was heated to 343 K (70 C.) and stirred at 600 rpm using a heater/magnetic stirrer. Sodium hydroxide (NaOH) solution (50 ml, 2.5 M) and manganese sulfate solution (75.0 ml, 2.0M) were then added drop-wise to the hot potassium permanganate solution using two separate burettes until a brown precipitate formed. The brown precipitate was then stirred over night at 343 K, filtered, washed with de-ionized water and then dried in an oven at 383 K (100 C.). The MnO.sub.2 was formed according to the following equations:
MnSO.sub.4+2NaOH.fwdarw.Mn(OH).sub.2+NaSO.sub.4(1)
3Mn(OH).sub.2+2KMnO.sub.4.fwdarw.5MnO.sub.2+KOH+2H.sub.2O(2)

(10) The crystalline structure and the identity of the as-prepared manganese oxide were explored using XRD analysis. FIG. 1 shows the XRD recorded for the manganese oxide nanostructures. The XRD measurement of the manganese oxide showed a pattern similar to crystalline orthorhombic -MnO.sub.2 phase, as observed in a previous study, with broad peaks at (2=23.5, 37.1, 42.5, 56.3) and a single peak at (2)=66.8 of -MnO2 phase. MONCs mainly include nanocrystalline orthorhombic -MnO.sub.2 phase. The broadness of the peaks indicate that the formed compound exists predominantly in nano-scale. According to the Scherrer equation, the crystallite size is inversely related to the FWHM (full width at half maximum) of an individual peak. This is because of the periodicity of the individual crystallite domains, in phase, reinforcing the diffraction of the X-ray beam, resulting in a tall narrow peak. If the crystals are defect free and periodically arranged, the X-ray beam is diffracted to the same angle even through multiple layers of the specimen.

(11) If the crystals are randomly arranged, or have low degrees of periodicity, the result is a broader peak. Further characterizations were performed using SEM, TEM, and surface area analyses to explore the morphology and properties of the -MnO.sub.2. The SEM images at different magnifications showed that -MnO.sub.2 have a sea-coral shape in microstructure form, composed of nanowires with diameters between 20.0-40.0 nm as presented in FIGS. 2A-2B. The TEM images confirmed the shapes of the MONCs and their existence as nanowires with average diameter of 25.0 nm and a length of a few microns, as shown in FIG. 3. The average diameter in MNOCs was calculated manually from both SEM and TEM images based on 10 MONCs nanowires for each measurement. The nitrogen adsorption/desorption isotherms were measured at 77 K and the B.E.T.-specific surface area was calculated from them. The B.E.T. surface area was equal to 168.9 m.sup.2 g.sup.1, and total pore volume equaled 0.0742 cm.sup.3 g.sup.1.

EXAMPLE 2

MONCs Catalyst Testing

(12) The MONCs were used to oxidize CO to CO.sub.2 in the laboratory. The catalytic oxidation of CO by O.sub.2 on MONCs surface was conducted at temperatures between 348 and 423 K. A stoichiometric mixture of CO and O.sub.2 at a pressure of 4 Torr was used under a dynamic method. This method allows the measure of the drop in pressure of the reacting gases as a function of time and temperature in a closed circulating manifold system made of Pyrex glass. A fresh sample of MONCs, activated at 423 K for 3 hours, under a reduced pressure of 10.sup.5 T was attained prior to adsorption of reacting gases. The conversion data was determined by gas chromatograph equipped with a thermal conductivity detector (TCD) detector with pure helium (He) as a carrier gas (20 ml min.sup.1).

(13) Conversion of carbon monoxide (CO) by MONCs results revealed that the conversion process significantly depended on the operational temperature and the amount of MONCs. Increasing the temperature greatly enhanced the conversion of CO, indicating the endothermic nature of the reaction. The maximum CO conversion of 100% was achieved at a temperature of 423 K (150 C.) within 50 min as shown in FIG. 4. Also, the results showed that increasing the MONCs dosage accompanied with significant increase in the percentage of carbon monoxide (CO) conversion (FIG. 5). This effect is due mainly to the availability of more active sites. The results revealed that 100% CO conversion could be obtained using 0.2 g MONCs within 60 minutes at 348 K (75 C.), and that this effect could also be achieved within 30 minutes by using 0.4 g MONCs at the same temperature.

(14) Using the manganese oxide nanocoral catalysts (MONCs) described herein, carbon monoxide could be eliminated easily from the environment by catalytic oxidation process at normal conditions. The active MONCs could be synthesized easily in the laboratory at ordinary conditions.

(15) It is to be understood that the present invention is not limited to the embodiments described above, but encompasses any and all embodiments within the scope of the following claims.