INTRODUCTION
The economic, agricultural and industrial development and the steady increase in the automobile industry lead the world to the increasing demand for crude oil, which prompted scientists to devise easy and cheap ways to remove sulfur from crude oil and its derivatives and raise its quality by reducing the sulfur content [1-4].  From the lowest percentage of 0.05% to the highest percentage of 14% by weight depending on the source of crude oil, and the sulfur content in transportation fuels such as gasoline and kerosene must be less than 10 ppm according to environmental regulations [5,6].  Crude oil contains both organic and inorganic sulfur compounds (active sulfur), both sulfur and hydrogen sulfide, and light mercaptans that can interact directly with the metal.  As for the organic sulfur compounds (inactive sulfur) thiophene, thiol, dibenzo thiophene, benzo thiophene and many complex molecules that cannot interact directly with the metal, which in turn form sulfur oxides when the fuel is oxidized and thus cause health and environmental problems [7,8]. Crude oil treatment techniques can remove impurities and pollutants, especially sulfur pollutants, which can be treated by conventional methods, using a combination of physical, chemical and biological methods [9,10].  Many refineries use a variety of procedures to reduce the sulfur content of crude oil. Adsorption desulfurization (ADS) and oxidative desulfurization (ODS) are the most important desulfurization methods for many reasons, including moderate operating conditions, good desulfurization effect and high selectivity of thiophene compounds [11,12].
In the adsorption technique, the sulfur compounds present in the hydrocarbons are adsorbed on the solid surface made of an adsorbent material, where the adsorption efficiency depends on the selectivity of the adsorbent material, the most important examples of adsorbent surfaces are zeolite, activated carbon, silica, alumina and titanium dioxide, which drew the attention of researchers for its instinctive properties Which played an important role in the removal of heavy metals [13].
 It was also known as an environmentally friendly catalyst with little activity in ultraviolet radiation, which led to its use in many fields, including the field of environmental treatment [14,15]. Titanium dioxide exists in three forms; brookite, rutile, anatase. While the method of oxidation desulfurization is a new method for removing sulfur under moderate conditions (temperature and pressure) and has a low cost compared to the hydrogenation desulfurization method(HDS), molybdenum trioxide was recently selected as a promising material for oxidation desulfurization, molybdenum has many oxidation states (+2 - +6)  Which makes it attractive to researchers, as molybdenum trioxide is one of the most important oxides because of its excellent physical and chemical properties, and most importantly its distinct multi-layered structure and interesting optical and electrochemical properties [16]. There three types of MoO3: “Thermodynamically stable ortho-rhombic a-MoO3, the metastable monoclinic b-MoO3 and hexagonal h-MoO3” Molybdenum oxides have many uses in electronics, energy storage units, vital systems, sensors, superconductors, biomaterials, and lubricants [17]. Adsorption and oxidation desulfurization technology can be combined to produce an ultra-low sulfur fuel.  The removal efficiency was observed less when using nanoscale titanium oxide 3.5% while using nano molybdenum oxide 14.9%

MATERIALS AND METHODS
Sodium molybdate dihydrate (Na2MoO4.2H2O) from Merck, Germany Titanium isopropoxide (97%, Sigma-Aldrich), ethanol (99.9%), hydrochloric acid (37%), Ascorbic acid, Sodium decyl sulfate (SDS), Hydrogen peroxide (50%, Panreac applab., Spain), Formic acid (95%, Sigma-Aldrich).

Preparation Procedure
Prepare TiO2 nano particles was as carried out according to previous published study by ( N.S. ANWAR, A. KASSIM, H.N. LIM, S.A. ZAKARYA, N.M. HUANG) 1 With some modifications  by Titanium isopropoxide (5 ml ) was added dropwise in to a mixture of (2.5 ml) ethanol and (3.5 ml) dilution HCl while stirring and a clear solution was formed , After that was added 10 ml SDS ( 1.0 wt %) under stirring at room temperature for 15 mints , the mixture was then transferred in to a Teflon-lined autoclave and put it is in the oven at 120 C for 24 hr. , then it is cooled at room temperature and product is separated by centrifuge , washed with water and ethanol , then dried at 60 C for 24 hr. and  then stored  overnight  in  a  desiccator. 
Prepare α- MoO3 nano -belts articles was as carried out according to previous published study by researchers (Amani Jabbar Obaid and Luma Majeed Ahmed) 2 With some modifications   by using 1 mmol Sodium Molybdate dihydrate with 7ml HCl dilution(added in the form drops) while stirring for 15 mints then added 10 ml of ascorbic acid solution with mixing by a magnetic stirrer  , the mixture was transferred to steel Teflon tube autoclave and hydrothermal reaction was carried out at 180 C for 6 hr. , the result is also separated and washed with water and ethanol , and dried in an oven at 60 C for 6 hr. and  then stored  overnight  in  a  desiccator. 

Desulfurization Procedure
Two solutions are prepared by mixing 25 ml of prosses oil taken from the (Bazerkan field in Maysan) with (2 ml) hydrogen peroxide, (2 ml) formic acid with (2 ml) distilled water and equal amounts of (0.4 g) of binary Titanium oxide for the first solution and molybdenum trioxide for the second solution. These solutions are symbolized by the symbols S1 and S2, respectively. The solutions, S1, S2, are placed in a water bath at (500) revolutions per minute and (50 ᴼC) for an hour and a half. The solutions are cooled at room temperature, then the nanomaterials are separated from them using a centrifuge from the oil solution. The sulfur content of the two models S1, S2 is measured with the original sulfur content measured in the original model S0 (the treated oil) by an X-ray fluorescence Sulfur in oil analyzer. SLFA-6100 in Misan Oil training institute is shown in the Fig. 1.

RESULTS AND DISCUSSION
Characterization of nano Oxide
Nanocomposite materials’ size, aggregation state, and morphology are all important considerations in this field. Consequently, to assess the surface morphology of nanocomposites, scanning electron microscopy was employed, as shown in SEM images. According to the SEM images, the produced TiO2 nanoparticles morphology was shown in Fig 2.A which appeared as spherical NPs with size diameter about 34 nm. While   MoO3 NPs was shown in Fig 2. B. which indicated that The nanoparticles were spherical form with 41 nm in size.
It is possible to examine the phase composition and crystal size of the generated NPs using X-ray diffraction analyses. 
The standard XRD peaks of Anatase TiO2 are in good agreement with the peaks in the TiO2 XRD pattern (Fig. 3) corresponding to  (JCPDS Card No. 040477). The MoO3 diffraction peaks that can be precisely indexed to pure MoO3 are shown in Fig. 4.  (JCPDS data file no. 05-0508).

(FT-IR) Fourier-Transform Infrared Spectroscopy
The FTIR spectra of TiO2 and MoO3 NPs were shown in Figs. 5, and 6. Broadband with a center at 3419 cm-1 is thought to be responsible for the stretching vibration of the -OH on the oxide surfaces under varied conditions. The broad bands in the TiO2 spectrum that are centered between 500 and 600 cm-1 are responsible for the bending vibration (Ti-O-Ti) bonds.

Analysis of the sulfur content of crude oil
The measurement of sulfur content in the treated and untreated oil samples was performed by X-ray analysis. The desulfurization percentage is obtained as the ratio of the sulfur that is reduced (or removed) to that present in the crude oil as in the following equation

Where:
DE: desulfurization efficiency 
??: the sulfur content of the original oil sample 
??: the sulfur content in the oil sample after treatment.
The used nanomaterials showed the highest removal efficiency when using nano molybdenum oxide 14.9%. This may be attributed to the removal by oxidation as a synergistic function with the adsorption that is characteristic of this compound. However, the removal efficiency was observed less when using nanoscale titanium oxide 3.5% less, which depends only on removal by adsorption.
Nanomaterials have peculiar characteristics in contrast to their bulk counterparts. Their high surface-to-volume ratio confers unique physiochemical characteristics, such as a variety of functions and increased reactivity or selectivity [18-25]. Numerous products, processes, and applications that might surely support environmental and other biological applications can make use of nanotechnology’s distinctive properties [26,27].

CONCLUSION
The increasing demand for cleaner fuels and the recent severe regulations on commercial fuel standards have pushed the need for innovative approaches to enhance the current industrial desulfurization technology. Nanotechnology is one such possible solution. TiO2 and MoO3 nanoparticles, however, appear to have the potential for industrial applications, whether used alone or in a multistage process with other adsorbents for desulfurization.

CONFLICT OF INTEREST
The authors declare that there is no conflict of interests regarding the publication of this manuscript.