EthyleneâVinyl Acetate Copolymer and Resin-Stabilized Asphaltenes

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Ethylene-Vinyl Acetate Copolymer (EVA) and Resin-stabilized Asphaltenes Synergistically Improve the Flow Behavior of Model Waxy Oils: 1. Effect of Wax Content and the Synergistic Mechanism Bo Yao, Chuanxian Li, Fei Yang, Xiaoping Zhang, Zhonghua Mu, Guangyu Sun, and Yansong Zhao Energy Fuels, Just Accepted Manuscript • DOI: 10.1021/acs.energyfuels.7b03657 • Publication Date (Web): 08 Jan 2018 Downloaded from http://pubs.acs.org on January 9, 2018

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Ethylene-Vinyl Acetate Copolymer (EVA) and Resin-stabilized Asphaltenes

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Synergistically Improve the Flow Behavior of Model Waxy Oils: 1. Effect of

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Wax Content and the Synergistic Mechanism

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Bo Yao a, b, Chuanxian Li a, b, Fei Yang a, b, *, Xiaoping Zhang a, b, Zhonghua Mu a, b, Guangyu Sun a, b and Yansong Zhao c

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a

College of Pipeline and Civil Engineering, China University of Petroleum, Qingdao, Shandong 266580, PR China

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b

Shandong Provincial Key Laboratory of Oil & Gas Storage and Transportation Safety, Qingdao, Shandong 266580, PR

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China

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c

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Norway University of Applied Sciences, Inndalsveien 28, 5063 Bergen, Norway

Department of Biomedical Laboratory Sciences and Chemical Engineering, Faculty of Engineering and Science, Western

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Abstract: Both polymeric pour point depressants (PPDs) and asphaltenes can improve the flowability of

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waxy oils. However, the effect of polymeric PPDs together with asphaltenes on the flowability of waxy oils

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is not clear. In this paper, the synergistic effect of EVA PPD (100 ppm) and resin-stabilized asphaltenes (0.75

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wt%) on the flow behavior of model waxy oils (10~20 wt% wax content) was investigated through

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rheological test, DSC analysis, microscopic observation and asphaltenes precipitation test. The results

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showed that the asphaltenes disperse well in the xylene/mineral oil solvent as small aggregates (around 550

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nm) with the aid of resins. The EVA or asphaltenes alone moderately improve the flow behavior of waxy oils

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by changing the wax crystals’ morphology from long needle-like to large radical pattern or fine particles,

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respectively. The wax precipitation temperatures(WPTs) of waxy oils are also slightly decreased by adding

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EVA or asphaltenes, meaning that the co-crystallization effect between the additives and waxes is dominant.

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The EVA together with asphaltenes cannot further decrease the WPT, but can dramatically decreases the

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pour point, gelation point, G′, G″ and apparent viscosity of waxy oils, indicating that a synergistic effect

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exists between EVA and asphaltenes. The synergistic effect deteriorates with increasing the wax content of

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waxy oils. The EVA molecules can adsorb on the surface of asphaltene aggregates, thus inhibiting the ACS Paragon Plus Environment

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asphaltenes precipitation and forming the EVA/asphaltenes composite particles. The formed composite

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particles can act as wax crystallizing templates and then greatly change the wax crystals’ morphology into

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large, compact and spherical-like wax crystal flocs, thus dramatically improving the waxy oil flow behavior.

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This work enriches the theory of micro/nano composite PPDs, which is helpful for developing new PPDs

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with high efficiency.

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1. Introduction

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Waxy crude oil with the wax content ≥ 10 wt% is an important fossil resource. The waxes in crude oil are

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usually denoted as the high molecular weight n-alkanes (paraffin waxes) with carbon number ranging from

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C18 to C40 [1]. The solubility of paraffin waxes decreases quickly with temperature drop; when the waxy

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crude oil temperature is below the wax appearance temperature (WAT), paraffin waxes crystallize out of the

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oil and start to build the three-dimensional network structure. Due to the irregular morphology of the

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crystals (plate-like or needle-like), a small amount of the precipitated wax crystals (around 1 wt%) is enough

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to build a stable network structure, resulting in gelling of the waxy crude oil [2-4]. The gelling significantly

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increases the oil viscosity and changes the rheological behavior to non-Newtonian, which causes huge

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economic losses in the production, pipeline transportation and storage processes of waxy crude oil. In

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addition, the gelling brings huge problems in the pipeline shutdown/restart processes. In such a case, the gel

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structure formed in waxy crude oil pipeline during shutdown makes the restart operation of the pipeline

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more difficult [5].

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In crude oil industry, a small amount of polymeric pour point depressants (PPDs) is often added into waxy

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crude oil to improve the flow behavior of the oil [6]. The molecular structure of polymeric PPDs normally

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contains both the non-polar moieties and the polar moieties [6]: the non-polar moieties are long alkyl chains

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with carbon number ≥ 18, which could participate in the precipitation process of paraffin waxes; the polar

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moieties such as ester, maleic anhydride (MA) and vinyl acetate (VA) groups, can interfere the growth of ACS Paragon Plus Environment

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wax crystals. According to the position of the long alkyl chains in the molecular structure, polymeric PPDs

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could be classified into two types: the linear copolymers with the long alkyl chains located in the backbone

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(such as the ethylene-vinyl acetate copolymer (EVA) [7-9]) and the comb-like copolymers with the long

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alkyl chains located in the side chain (such as the polyacrylates [10-12]). To guide the application of

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polymeric PPDs in crude oil pipelines, the effects of the molecular structure of PPDs [13-15], wax

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composition and content [16, 17], thermal/shear histories [6, 18] on the efficiency of the polymeric PPDs

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have been widely studied; the mechanisms of polymeric PPDs were also well discovered [6-18]: the

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polymeric PPDs could participate in the precipitation process of wax molecules and then change the

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morphology of precipitated wax crystals, thus improving the flow behavior of waxy crude oil.

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Most of the crude oil contains a certain amount of asphaltenes, which are the heaviest and most polar

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portion of crude oils [19, 20]. Asphaltenes are often composed of condensed polyaromatic rings containing

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aliphatic and naphthenic side chains and sulfur, oxygen, nitrogen as heteroelements or functional groups.

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Metals such as vanadium and nickel are also present in this fraction as part of porphyrinic or nonporphyrinic

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groups [19, 20]. Asphaltene molecules often exist in the crude oil as asphaltene aggregates due to the strong

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self-association propensity of the molecules, and the aggregate size could range from nano- to micro-meter

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[21, 22]. During the last two decades, the effects of asphaltenes on the flow behavior of model waxy oil have

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been widely studied. The asphaltenes were first extracted from real crude oil by n-pentane/n-heptane

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precipitation, and then the extracted asphaltenes were re-dispersed in waxy oil with the aid of heating and

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agitation [23-28]. The results showed that [23-28]: (a) the asphaltenes disperse in oil phase as asphaltene

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aggregates; (b) a small dosage of asphaltenes (around 0.1 wt%) can greatly modify the morphology of

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precipitated wax crystals, thus improving the flow behavior of waxy oil; (c) the effect of asphaltenes on the

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WAT of waxy oil is controversial: some works show the WAT decreases after adding asphaltenes, but some

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other works get the opposite result; (d) re-dispersion of asphaltenes in waxy oil is difficult due to the lack of ACS Paragon Plus Environment

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resins, and the dispersion state of asphaltenes in waxy oil is quite different from that in real crude oil.

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Therefore, a more reasonable method should be proposed to make sure the similar dispersion state of

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asphaltenes in model waxy oil and real crude oil.

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Obviously, both the polymeric PPDs and asphaltenes could improve the flow behavior of waxy oil.

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However, the effect of polymeric PPDs together with asphaltenes on the flow behavior of waxy oil is unclear.

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Recently, several researchers stated that the performance of polymeric PPDs is influenced by asphaltenes.

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Zhang et al [29, 30] synthesized a series of terpolymer PPDs with the octadecyl acrylate, MA and VA as the

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reacting monomers and found that the terpolymer PPDs have good pour point depressing efficiency on waxy

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oils. They deduced that the terpolymer PPDs could interact with the resins and asphaltenes and then form

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asphaltene-PPD-resin agglomerates. The new agglomerates could change the crystallization process of wax

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molecules, thus obviously improving the flowability of waxy oils. Guo et al [13, 31] synthesized comb-like

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maleic alkylamide-α-octadecene copolymers (MACs) and its derivatives, and evaluated the efficiency of the

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copolymers as PPDs for waxy oils. They found that the MACs with an appropriate ratio of polar/nonpolar

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group or with small aromatic pendants possess the best effect on the flowability of waxy oils. They supposed

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that the MACs could adsorb on the surface of asphaltenes and then form assembly model of MACs and

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asphaltenes, which contributed to the improvement of cold flowability of waxy oils. However, the works

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mentioned above are preliminary and do not provide convincible evidences upon the interactions between

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the PPDs and asphaltenes. An in-depth understanding of the synergistic effect of polymeric PPDs and

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asphaltenes on the flow behavior of waxy oils is urgent because it not only enriches the polymeric PPDs’

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theory but also favors the development of new PPDs with high efficiency.

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Linear EVA copolymer is a kind of effective polymeric PPDs and has been widely studied as model PPD

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due to its explicit molecular structure. In this paper, the synergistic effect of EVA (100 ppm) and

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resin-stabilized asphaltenes (0.75 wt%) on the microstructure and flow behavior of model waxy oils with ACS Paragon Plus Environment

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different wax content (10~20 wt%) was investigated through rheological test, differential scanning

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calorimetric (DSC) analysis, microscopic observation and asphaltenes precipitation test. The results showed

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that the EVA together with asphaltenes can synergistically modify the precipitated wax crystals’ morphology,

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thus dramatically improving the flow behavior of the waxy oils. The synergistic mechanism was also well

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discovered base on the interaction between the EVA and asphaltene aggregates.

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2. Experimental

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2.1 Materials

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The mineral oil, n-pentane, xylene and EVA PPD were purchased from Sigma-Aldrich Co., Ltd. The

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mineral oil is mainly composed of isoalkanes with the carbon number ranging from C16 to C26 and contains

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little paraffin waxes (see Figure S1 in the support information file). The solid wax used here is the same as

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that mentioned in a former published paper [32], which is a mixture of two paraffin waxes with different

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melting point ranges. As seen in Figure S2 in the support information file, the solid wax has a wide carbon

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number distribution (C19~C50), which is similar to the carbon number distribution of waxes in the real crude

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oil. The VA content and the melting index of the EVA PPD are 28 wt% and 6, respectively. According to the

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melting index, the average molecular weight of EVA copolymer is calculated as 20000 [33]. The dosage of

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EVA in the subsequent model waxy oils was fixed at 100 ppm.

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The model waxy oils were prepared by dissolving a certain amount of solid wax in the xylene/mineral oil

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solvent. The xylene content in waxy oils was fixed at 20 wt%, while the solid wax content was fixed at

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10~20 wt%. The rest part of the waxy oils was the mineral oil. In order to keep the original dispersion state

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of asphaltenes in crude oil, a small amount of Tahe heavy oil was directly added into the waxy oils. As seen

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in Figure S3 and Table 1 in the support information file, the heavy oil has little paraffin wax and the contents

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of n-petane precipitated asphaltenses (C5-asphaltenes) and resins are 29.8 wt% and 5.1 wt%, respectively.

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The final content of C5-asphaltenes in the waxy oils was fixed at 0.75 wt%, that is, the content of the heavy ACS Paragon Plus Environment

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oil in the waxy oils should be around 2.5 wt%. The dispersion state of the asphaltenes in the xylene/mineral

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oil solvent (the mass ratio of xylene/mineral oil is same as that of the 10 wt% waxy oil) is shown in Figure

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S4 of the support information file. Obviously, the asphaltenes stabilized by resins disperse well in the

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xylene/mineral oil solvent as asphaltene aggregates, which have a wide particle size distribution (113

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nm~1.45 µm) and an average particle sizes around 550 nm.

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2.2 Methods

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2.2.1 Pour point tests

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The pour points of the undoped/doped waxy oils were measured on the basis of the method given in the

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Chinese Standard SY/T 0541-2009 [34].

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2.2.2 Rheological tests

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All the rheological tests were conducted by using an AR-G2 Rheometer (TA instrument Co., USA)

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equipped with a coaxial cylinder system (a standard cup having a diameter of 30 mm, configured with a DIN

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Rotor having a diameter of 28 mm). A plastic cover was placed over the measuring cell to minimize

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evaporation. Before loaded into the rheometer for testing, the undoped/doped waxy oils were preheated at

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60 °C for 20 min in sealed glass bottles. The cooling rate of each rheological test was fixed at 0.5 °C/min.

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Structural development of the undoped/doped waxy oils under static cooling condition. The

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undoped/doped waxy oils were cooled from 60 °C to 15 °C under the oscillation mode, during which the

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elastic modulus G′, viscous modulus G″ and loss angle δ were monitored. The gelation point, at which the G′

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equals G″ or δ equals 45°, was also obtained. The oscillatory amplitude was fixed at 0.0005, which was so

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small that the formation of the waxy oil gel would not be disturbed (that is, static cooling condition) [32,34].

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The oscillatory frequency was fixed at 1 Hz.

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Structural development of the undoped/doped waxy oils under dynamic cooling condition. A constant

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shear rate (10 s-1) was imposed on the undoped/doped waxy oils during the cooling process from 60 °C to ACS Paragon Plus Environment

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15 °C. The variation of the oil viscosity/apparent viscosity with temperature drop was monitored.

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2.2.3 Crystallization exothermic characteristics tests

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By using a DSC 821e calorimeter (Mettler-Toledo Co., Switzerland), the exothermic characteristics of

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undoped/doped waxy oils were analyzed. The temperature scanning range was fixed at 85~-20°C and the

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cooling rate was fixed at 2, 5, 7 and 10 °C/min, respectively. Based on the exothermic DSC curves, the wax

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precipitation temperature (WPT) and amount of precipitated wax crystals at different temperatures were also

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calculated and recorded.

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2.2.4 Microstructure observation tests

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By using a high-resolution OLYMPUS BX51 microscope (Olympus Co., Japan) fitted with an automatic

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thermal stage, the microstructure of the undoped/doped waxy oil was observed under both the normal optical

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and the polarized optical conditions. After being preheated at 60 °C for 20 mins, one droplet of the oil sample

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was transferred to a glass slide covered by a coverslip. The loaded oil sample was cooled statically from 60 °C

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to 30 °C and 20 °C on the thermal stage under a fixed cooling rate of 0.5 °C/min. The microstructure of the oil

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samples at 30 °C and 20 °C was observed and photographed.

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2.2.5 Asphaltenes precipitation test

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A certain amount of Tahe heavy oil was first dispersed in the mineral oil/xylene solution (with the mass

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ratio of mineral oil/xylene at 4:1) to obtain the mixed solution containing 0.75 wt% asphaltenes (with the

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mass of the mixed solution as W ). Then the effect of EVA PPD on the stability of asphaltenes in the mixed

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solution was investigated through n-pentane precipitation. The dosage of EVA was fixed at 100 ppm, while

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the volume ratio of the mixed solution/n-pentane was fixed at 1:1, 1:3, 1:5, 1:10 and 1:20, respectively. The

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precipitated sediments (that is, the asphaltenes) were high-speed centrifuged, vacuum dried and weighted as

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W1 . Therefore, the precipitated asphaltenes percentage f ASP could be calculated as f ASP =

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addition, the morphology of the dried asphaltenes was tested by Zeiss Merlin SEM (Zeiss Co., German).

W1 ×100% . In W

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3. Results and discussions

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3.1 Effect of EVA together with asphaltenes on the pour point of waxy oils

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To eliminate the influence of deasphaltened oil on the flow behavior of waxy oils, the pour point of the

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waxy oils doped with deasphaltened oil was first measured here. The deasphaltened oil was prepared by

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removing the asphaltenes from Tahe heavy oil using excess n-pentane. The content of deasphaltened oil in

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the waxy oils was fixed at 1.75 wt%. As seen in Table S2 of support information file, the addition of

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deasphaltened oil slightly decreases the pour point of 10 wt% waxy oil from 36 °C to 35 °C. For 15 wt% and

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20 wt% waxy oils, adding deasphlatened oil does not affect the pour point of the waxy oils. Obviously,

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adding 1.75 wt% deasphaltened oil has little influence on the flow behavior of waxy oils, which is in

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agreement with the previously reported works [29, 35].

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The pour points of the waxy oils undoped/doped with EVA, asphaltenes and EVA/asphaltenes are

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illustrated in Table 1. For 10 wt% waxy oil, the original pour point is 36 °C. Adding 100 ppm EVA depresses

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the pour point to 31 °C; adding 0.75 wt% asphaltenes depresses the pour point to 30 °C; adding EVA

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together with asphaltenes can suppress the pour point to < -10 °C. For 15 wt% waxy oil, the original pour

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point increases to 40 °C, and the pour point depressing ability of neat EVA (37 °C) or neat asphaltenes

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(36 °C) is slightly inhibited. However, adding EVA together with asphaltenes can still suppress the pour

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point of 15 wt% waxy oil to < -10 °C. For 20 wt% waxy oil, the original pour point is the highest (42 °C),

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and the pour point depressing ability of neat EVA (41 °C) or neat asphaltenes (39 °C) is further inhibited.

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Nevertheless, the EVA together with asphaltenes still exhibit a much better performance in suppressing the

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pour point of 20 wt% waxy oil to 30 °C. It could be concluded here that the EVA together with asphaltenes

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can synergistically depress the pour point of waxy oils, and the synergistic effect deteriorates with increasing

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the wax content of waxy oils.

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3.2 Effect of EVA together with asphaltenes on the structural development of waxy oils ACS Paragon Plus Environment

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3.2.1 Structural development of waxy oils under static cooling condition

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The viscoelastic test under oscillation mode is an efficient way to investigate the sol-gel transition process

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of waxy crude oil under static cooling condition [4, 32, 34, 36]. Figure 1 shows the viscoelastic development

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of undoped/doped 10 wt% waxy oils with temperature drop. For the pure waxy oil (Figure 1a), although

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both G′ and G″ are very small at temperatures higher than or around the WPT, G″ (around 10-2 Pa) is quite

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higher than G′ (around 10-3 Pa), resulting in the value of δ approaching 90° and a pure viscous fluid behavior

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of the oil. With the decrease of oil temperature, both G′ and G″ increase quickly due to the continuous

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precipitation of wax crystals, and the rising speed of G′ is much larger than that of G″, finally leading to a

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cross of the G′ and G″ at the gelation point of the oil (37 °C). After that, G′ and G″ increase continuously

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with the further decrease of oil temperature and the value of G′ is always higher than G″, indicating that

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elastic response of the oil is dominant below the gelation point. Adding 100 ppm EVA PPD or 0.75 wt%

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asphaltenes decreases the gelation point to 25.3 °C and 30.9 °C, respectively, indicating that the waxy oil

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gelation process is retarded after the addition of EVA or asphaltenes. Meanwhile, the values of G′ and G″ are

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also decreased by adding the EVA or asphaltenes: at the test temperature 15 °C, the G′ and G″ of the

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undoped waxy oil are 2.011×105 Pa and 1.207×104 Pa, respectively, confirming a strong gel structure of

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undoped waxy oil; the G′ and G″ decrease to 3.198×104 Pa and 5.922×103 Pa after adding neat EVA and

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decrease to 5.068×104 Pa and 1.105×104 Pa after adding neat asphaltenes. For the waxy oil doped with

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EVA/asphaltenes, during the entire cooling process (55~15°C), the value of G″ presents a very slow

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increasing trend with the decrease of temperatures (always lower than 10-1 Pa), while the value of G′ is

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around 10-3~10-2 Pa without any dramatic increase. At the test temperature 15 °C, the G′ and G″ of the waxy

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oil doped with EVA/asphaltenes are only 2.240×10-3 Pa and 6.391×10-2 Pa, respectively. This indicates that

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the waxy oil doped with EVA/asphaltenes behaves as a viscous fluid under the experimental condition.

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The viscoelastic development of undoped/doped 15 wt% waxy oil with temperature drop is displayed in ACS Paragon Plus Environment

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Figure 2. The gelation point of the undoped waxy oil increases to 40.4 °C due to the increase of wax content.

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The G′ and G″ of the undoped waxy oil at 25 °C are 1.014×105 Pa and 2.104×104 Pa, respectively. Adding

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neat EVA or asphaltenes decreases the gelation point to 30.9 °C and 37.6 °C, respectively. The G′ and G″ at

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25 °C decrease to 8.370×102 Pa and 2.490×102 Pa after adding neat EVA and decrease to 2.980×104 Pa and

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1.199×104 Pa after adding neat asphaltenes. Similar to the 10 wt% waxy oil, the 15 wt% waxy oil doped

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with EVA/asphaltenes has very small values of G′ (around 7.000×10-3 Pa) and G″ (around 4.000×10-2 Pa),

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and behaves as a viscous fluid under the experimental condition.

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When the wax content increases to 20 wt% (see Figure 3), the performance of the additives is greatly

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inhibited. The gelation point of the undoped waxy oil increases to 43.3 °C. The G′ and G″ of the undoped

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waxy oil at 30 °C are 2.430×105 Pa and 3.612×104 Pa, respectively. Adding neat EVA or asphaltenes could

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only decrease the gelation point to 39.9 °C and 40.2 °C, respectively. The G′ and G″ at 30 °C decrease

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slightly to 2.361×105 Pa and 2.975×104 Pa after adding neat EVA but increase slightly to 3.412×105 Pa and

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3.740×104 Pa after adding neat asphaltenes. Adding EVA/asphaltenes still takes synergistic effect and

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decreases the G′ and G″ at 30 °C to 2.758×102 Pa and 3.590×101 Pa, respectively; but the viscoelastic curve

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starts to exhibit the gelation point at 38.4 °C.

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Based on the results mentioned above, it could be concluded that the EVA together with asphaltenes can

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synergistically improve the viscoelastic properties of waxy oils, and the synergistic effect deteriorates with

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increasing the wax content of waxy oils.

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3.2.2 Structural development of waxy oils under dynamic cooling condition

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Figure 4a displays the viscosity/apparent viscosity increase of 10 wt% undoped/doped waxy oils with

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decreasing temperature measured at 10 s-1. At temperatures above the WPT, the viscosities of the

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undoped/doped waxy oils exhibit a strict linear dependence with the decreasing temperatures (in the

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semi-log coordinate), and the additives show no viscosity reducing performances but slightly increase the ACS Paragon Plus Environment

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viscosity of the oil. When the temperature decreases to below WPT, the apparent viscosity of undoped waxy

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oil first increases sharply. After adding the neat asphaltenes, the sharp increase of the apparent viscosity

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shifts to a lower temperature, verifying the rheological improvement after the asphaltenes beneficiation.

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However, the apparent viscosity of the waxy oil doped with neat asphaltenes exhibits a quick increase trend,

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and finally, grows over that of undoped waxy oil at 29.5 °C. For the waxy oil doped with neat EVA, the

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apparent viscosity development below WPT is a slowly increasing process. At temperatures above 16 °C,

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EVA reduces the apparent viscosity of waxy oil effectively, but below 16 °C, the apparent viscosity of waxy

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oil doped with EVA even exceeds that of undoped waxy oil. The waxy oil doped with EVA/asphaltenes

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displays no sharp apparent viscosity increase during the entire cooling process (60~15 °C) and the apparent

240

viscosity at 15 °C is only 8.07 mPa·s, which is orders of magnitude smaller than the other oil samples.

241

As seen in Figure 4b, for 15 wt% waxy oils, the viscosity reducing efficiency of the neat EVA and neat

242

asphaltenes has deteriorated a lot, while adding EVA together with asphaltenes still takes a good effect in

243

reducing the apparent viscosity of waxy oil. When the wax content increases to 20 wt%, adding the

244

individual additives (EVA or asphaltenes) nearly exhibits no viscosity reducing performance. Adding EVA

245

together with asphaltenes can still effectively decrease the apparent viscosity of 20 wt% waxy oil, but its

246

efficiency has been greatly hindered.

247

Obviously, add EVA together with asphaltenes can synergistically decrease the apparent viscosity of waxy

248

oils under dynamic cooling, and the synergistic effect deteriorates with increasing the wax content of waxy

249

oils.

250

3.3 Crystallization exothermic characteristics of the undoped/doped waxy oils

251

The DSC curves at cooling rate of 10 °C/min and the precipitated wax crystals’ amount of the

252

undoped/doped waxy oil are exhibited in Figure S5 and S6 of support information file. It is clear that adding

253

different additives takes prominent effect in decreasing the WPT of waxy oil, meaning that the ACS Paragon Plus Environment

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Page 12 of 31

254

co-crystallization effect between the additives and waxes is dominant. The precipitated wax crystals’ amount

255

at low temperatures changes little, indicating that adding different additives has little influence on the final

256

amount of the precipitated wax crystals.

257

It is well known that the WPT of waxy oil measured by DSC instrument is closely related to the applied

258

cooling rate. The DSC curves of the undoped/doped waxy oils at different cooling rates (2 °C/min, 5 °C/min,

259

7 °C/min and 10 °C/min) were measured, and the WPTs corresponding with different cooling rates were

260

obtained and shown in Figure 5 and Table 2. Obviously, the WPTs of the undoped/doped waxy oils decrease

261

linearly with the increase of cooling rate corresponding to the results in previous works [37-40], which could

262

be explained by the combination effects of wax crystals’ nucleation and growth, and the thermal lag between

263

sample and DSC platform [41,42].

264

Based on Figure 5, the WPTs of the undoped/doped waxy oils at the cooling rate of 0.5 °C/min were

265

calculated and shown in Table 2. At fixed wax content, adding 100 ppm EVA can slightly decrease the WPT

266

of waxy oil. On the one hand, EVA molecules can co-crystallize with the wax molecules, promoting the

267

effective solubility of wax molecules in the oil phase. On the other, the incoming of impurities (VA groups)

268

increase the interfacial tension between the contaminated wax crystals and liquid phase, effectively

269

increasing the critical nucleation radius as well as the nucleation potential barrier of wax crystals, thereby

270

inhibiting the wax precipitation [7,34]. The WPT of waxy oil is decreased further after adding 0.75 wt%

271

asphaltenes. Asphaltenes can provide large amount of nucleation sites for the crystallization of wax

272

molecules (see Figure 8), which should increase the WPT of waxy oil. However, the resin-stabilized

273

asphaltenes aggregates are often surrounded by large amounts of aliphatic lateral chains, which can

274

co-crystallize with wax molecules and then decrease the WPT of the oil. We consider that the

275

co-crystallization effect dominates over the nucleation effect, thus causing the decrease of the WPT after

276

adding 0.75 wt% asphatlenes. Adding EVA together with asphaltenes cannot further decrease the WPT of the ACS Paragon Plus Environment

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277

Energy & Fuels

waxy oils.

278

Based on the discussions mentioned above, it could be concluded that the co-crystallization effect

279

between the additives and waxes is dominant and results in the decrease of WPT, but adding different

280

additives has little influence on the precipitated wax crystals amount at low temperatures.

281

3.4 Microstructures of the undoped/doped waxy oils

282

Microstructure images of the undoped 10 wt% waxy oil at 30 °C (Figure 6a and b) show that the

283

precipitated wax crystals are long needle-like with high aspect ratios. This kind of wax crystal is easier to

284

form a continuous network structure, thus causing high pour point/gelation point of the oil. When the oil

285

temperature drops to 20 °C (Figure 6c and d), the precipitated wax crystals become longer with larger

286

amount, resulting in the formation of a strong three-dimensional network structure.

287

As illustrated in Figure 7a and b, adding neat EVA greatly modifies the microstructures of the precipitated

288

wax crystals at 30 °C. Compared to the undoped waxy oil, the morphology of single wax crystal is still

289

needle-like but much shorter in length, and the precipitated needle-like crystals tend to aggregate into loose

290

radical pattern wax flocs, which favor the flow improvement of the oil. When the oil temperature drops to

291

20 °C (Figure 7c and d), the radical pattern wax flocs become larger in size and more obvious, indicating

292

that more waxes precipitate from the oil.

293

As seen in Figure 8a and b, the precipitated wax crystals at 30 °C become fine particles with relatively

294

large amount after adding 0.75 wt% asphaltenes, meaning that the asphaltenes act as the wax nucleates. The

295

fine wax particles are helpful for the initial flow improvement of the oil. When the oil temperature drops to

296

20 °C (Figure 8c and d), the precipitated wax crystal size is still small but with very large amount, which is

297

adverse for the flow improvement of the oil.

298

As shown in Figure 9a and b, the precipitated wax crystals at 30 °C begin to aggregate into large, compact

299

and spherical-like wax crystal flocs after adding EVA/asphaltenes. With the decreasing of temperatures ACS Paragon Plus Environment

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300

(Figure 9c and d), the sizes of wax crystal flocs grow continuously and the morphology of the wax crystal

301

flocs is still compact and spherical-like. This kind of wax crystal flocs is very difficult to build a continuous

302

network structure, thus dramatically improving the oil flowability.

303

3.5 Asphaltenes precipitation test

304

SEM images of the precipitated asphaltenes without and with the addition of EVA are present in Figure

305

10a and b. It is clear that adding EVA greatly decreases the size of the precipitated asphaltene aggregates,

306

which indicates that the EVA molecules adsorb on the asphaltene aggregates and inhibit the agglomeration

307

of the asphaltene aggregates. The percent of precipitated asphaltenes f ASP at different volume ratios of

308

mixed solution and n-pentane is shown in Figure 10c. The f ASP first increases quickly with the increase of

309

n-pentane ratio, and then reaches nearly saturated when n-pentane ratio is high. Meanwhile, at each

310

n-pentane ratio, the value of f ASP decreases obviously after adding EVA, which also means that the EVA

311

molecules adsorb on the asphaltene aggregates and act as asphaltenes dispersant. As reported in previous

312

works [43,44], EVA is a macro-surfactant whose structure contains both polar and nonpolar moieties, which

313

can act as asphaltene dispersant to adsorb onto the asphaltene flocs, thus forming the EVA/asphaltenes

314

composite particles.

315

3.6 Synergistic mechanism of EVA and asphaltenes on improving the flow behavior of waxy oils

316

Recently, introducing inorganic nano/micro particles, such as silica [45,46], clay [12,47] and graphene

317

oxide [48], into the polymeric PPDs’ matrix to improve the performance of the PPDs has become a hot

318

research spot. Yang et al [12,34,47,49] detailedly investigated the effects of different nano/micro particles on

319

the performance of the polymeric PPDs (such as EVA and POA). They found that the polymeric PPDs and

320

inorganic particles can form nano/micro composite particles in oil phase, which could act nucleation

321

templates of wax crystals and then further modify the morphology of precipitated wax crystals. Therefore,

322

the rheology of waxy crude oil is further improved after the addition of nano/micro composite PPDs. ACS Paragon Plus Environment

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Energy & Fuels

323

As illustrated in section 3.5, the EVA PPD can adsorb on the asphaltene aggregates to form the

324

EVA/asphaltenes composite particles. Like the nano/micro composite PPDs, we consider that the

325

EVA/asphaltenes composite particles can also effectively act as the heterogeneous nucleation templates for

326

wax molecules to precipitate, thus forming large, compact and spherical-like wax crystal flocs (see Figure

327

11). On the one hand, the larger size of the wax flocs with regular morphologies greatly reduces the wax

328

crystal/oil interface area and then weakens the interactions among the precipitated wax crystals; on the other,

329

the compact microstructure of the wax flocs enables the wax flocs to occlude less liquid oils. Both of two

330

sides dramatically improve the flow behavior of the oil. The synergistic mechanism of EVA together with

331

asphaltenes on the waxy oil flow behavior not only enriches the theory of nano/micro composite PPDs, but

332

also helps for developing new PPDs with high efficiency.

333

4. Conclusions

334

In this paper, the synergistic effect of EVA PPD (100 ppm) and resin-stabilized asphaltenes (0.75 wt%) on

335

the flow behavior of model waxy oils (10~20 wt% wax content) was studied detailed by using through

336

rheological test, DSC analysis, microscopic observation and asphaltenes precipitation test. The following

337

conclusions are drawn:

338

(a) With the aid of resins, the asphaltenes stabilized by resins disperse well in the xylene/mineral oil

339

solvent as asphaltene aggregates, which have a wide particle size distribution (113 nm~1.45 µm) and an

340

average particle sizes around 550 nm.

341

(b) Adding the EVA or asphaltenes alone moderately improve the flow behavior of waxy oils by changing

342

the wax crystals’ morphology from long needle-like into large radical pattern wax crystal flocs or fine wax

343

crystal particles, respectively. The WPTs of waxy oils are also slightly decreased by adding EVA or

344

asphaltene alone.

345

(c) Adding the EVA together with asphaltene cannot further decrease the WPT, but can synergistically ACS Paragon Plus Environment

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Page 16 of 31

346

decreases the pour point, gelation point, G′, G″ and apparent viscosity of waxy oils. Meanwhile, the

347

synergistic effect deteriorates with increasing the wax content of waxy oils.

348

(d) Asphaltenes precipitation test shows that the EVA molecules can adsorb on the surface of asphaltene

349

aggregates, thus inhibiting the asphaltenes precipitation and forming the EVA/asphaltenes composite

350

particles. The formed composite particles can act as wax crystallizing templates and then greatly change the

351

wax crystals’ morphology into large, compact and spherical-like wax crystal flocs, thus outstandingly

352

improving the waxy oil flow behavior. The synergistic mechanism of EVA together with asphaltenes on the

353

waxy oil flow behavior not only enriches the theory of nano/micro composite PPDs, but also helps for

354

developing new PPDs with high efficiency.

355

Acknowledgement

356

This work was financially supported by National Natural Science Foundation of China (51774311),

357

Natural Science Foundation of Shandong Province of China (ZR2017MEE022), Key Research Project of

358

Shandong Province of China (GG201703230122), and the Fundamental Research Funds for the Central

359

Universities-China.

360

References

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469

Figures

470 471 5

10

5

10

80

4

10

4

10

10 G' G'' / Pa

1

10

GP: 37.0 °C

G' G'' δ

0

10

-1

10

40 20

2

60

doped with EVA GP: 25.8 °C

10

1

10

δ/°

10% undoped waxy oil

G' G'' / Pa

60

2

10

80

3

10

3

δ/°

40

G' G'' δ

0

10

-1

10

20

-2

10

-2

10

0

-3

10

0

-3

10

20

30 40 Temperature / °C

472

50

20

(a)


50

(b)

4

10

80

G' G '' / Pa

1

10

G' G'' δ

0

10

-1

10

60

40

-1

10

GP: N/A

20

10

40

-2

20

10

0

-3

10

20

473 474 475

Figure 1

60

10

-3

-2

G' G'' δ

δ/°

GP: 30.9 °C

doped with EVA/asphaltenes G' G'' / Pa

doped with asphaltenes

2

10

80

0

10

3

10

δ/°

1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 25 26 27 28 29 30 31 32 33 34 35 36 37 38 39 40 41 42 43 44 45 46 47 48 49 50 51 52 53 54 55 56 57 58 59 60

Energy & Fuels


50

(c)

20


50 (d)

Viscoelasticity development during cooling of the 10 wt% waxy oil undoped/doped with EVA, asphaltene and EVA/asphaltene.

476


19

Energy & Fuels

477 478 4

10

5

10

80

3

10

4

10

3

10

GP: 40.4 °C

1

10

40 G' G'' δ

0

10

-1

10

20

G' G'' / Pa

10

10

60

15% undoped waxy oil

2

1

doped with EVA

10

GP: 30.9 °C

0

10

G' G'' δ

40

-1

10

-2

-2

10

-3

10

10

20

-3

10

30

35

479


50

0

55

60

δ/°

G' G'' / Pa

80

2

δ/°

30

35

(a)

40 45 50 Temperature / °C

55 (b)

5

10

4

80

10

80

10

0

10

doped with asphaltenes

1

10

GP: 37.6 °C

0

10

40

G' G'' δ

-1

10

-2

10

40 20

-3

0

10

-4

30

482

60

20

10

Figure 2

G' G'' δ

-2

-3

480

-1

10

doped with EVA/asphaltenes GP: N/A

10

10

481

60

δ/°

G' G'' / Pa

2

10

G' G'' / Pa

3

δ/°

1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 25 26 27 28 29 30 31 32 33 34 35 36 37 38 39 40 41 42 43 44 45 46 47 48 49 50 51 52 53 54 55 56 57 58 59 60

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30

55 (c)

35


55 (d)


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Page 21 of 31

485 486 6

10

5

10

5

10

10

3

10

3

1

10

60

20% undoped waxy oil GP: 43.3 °C

40

G' G'' δ

0

10

-1

10

2

10

G' G'' / Pa

2

60

doped with EVA GP: 39.9 °C

1

10

-1

10 20

-2

10

40

G' G'' δ

0

10

δ/°

G' G'' / Pa

10 10

80

4

80

4

10

δ/°

20

-2

10

-3

10

-3

-4

10

30

35

487


50

10

0

30

55 (a)

35


55

0 (b)

5

10

2

10

3

1

G ' G '' / Pa

2

10

1

10

G' G'' δ

0

10

-1

60 40

10

-2

10

-4

488 489 490

Figure 3

30

35


50

55

doped with EVA/asphaltenes 60 GP: 38.4 °C

0

10

10

0

10

40

G' G'' δ

-1

10

20

-3

10

10

δ/°

doped with asphaltenes GP: 40.2 °C

G' G'' / Pa

10

10

80

10

80

4

δ/°

1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 25 26 27 28 29 30 31 32 33 34 35 36 37 38 39 40 41 42 43 44 45 46 47 48 49 50 51 52 53 54 55 56 57 58 59 60

Energy & Fuels

20

-2

-3

0 30

35

(c)


55 (d)


491 492


21

Energy & Fuels

493 494 495 0

10 wt% undoped waxy oil doped with EVA doped with asphaltenes doped with EVA/asphaltenes

-1

10

-2

10

40

10

20

496 0

15 wt% undoped waxy oil doped with EVA doped with asphaltenes doped with EVA/asphaltenes

10

-1

10

-2

10

10

497

20


45

50


60 (b)

55

60

60 (a) 20 wt% undoped waxy oil doped with EVA doped with asphaltenes doped with EVA/asphaltenes

0

10 Apparent viscosity / Pas

Apparent viscosity / Pas

10

Apparent viscosity / Pas

1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 25 26 27 28 29 30 31 32 33 34 35 36 37 38 39 40 41 42 43 44 45 46 47 48 49 50 51 52 53 54 55 56 57 58 59 60

Page 22 of 31

-1

10

-2

10

10

20


60 (c)

498

Figure 4

Apparent viscosity-temperature curves under dynamic cooling of the waxy oils undoped/doped

499

with EVA, asphaltene and EVA/asphaltene. (a: 10 wt% waxy oil; b: 15 wt% waxy oil; c: 20 wt% waxy oil)

500


22

Page 23 of 31

wax precipitation point / °C

36

35

34 10% undoped waxy oil doped with EVA doped with asphaltenes doped with EVA/asphaltenes

33

2

4

6 8 -1 VT / °Cmin

501

37 36 15% undoped waxy oil doped with EVA doped with asphaltenes doped with EVA/asphaltenes

35 34

502

504

wax precipitation point / °C

38

2

503

10

(a)

42

39 wax precipitation point / °C

1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 25 26 27 28 29 30 31 32 33 34 35 36 37 38 39 40 41 42 43 44 45 46 47 48 49 50 51 52 53 54 55 56 57 58 59 60

Energy & Fuels

Figure 5

4

6 8 -1 VT / °Cmin

41 40 39 38 37 36

10

20% undoped waxy oil doped with EVA doped with asphaltenes doped with EVA/asphaltenes

2

(b)

4

6 -1 VT / °Cmin

8

10

(c)

WPTs at different cooling rates of the waxy oil undoped/doped with EVA, asphaltene and EVA/asphaltene. (a: 10 wt% waxy oil; b: 15 wt% waxy oil; c: 20 wt% waxy oil)

505


23

Energy & Fuels 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 25 26 27 28 29 30 31 32 33 34 35 36 37 38 39 40 41 42 43 44 45 46 47 48 49 50 51 52 53 54 55 56 57 58 59 60

Page 24 of 31

506 507 508

509

510 511 512

Figure 6

Microstructure of the 10 wt% undoped waxy oil (a: 30 °C, normal optical; b: 30 °C, polarized optical;c: 20 °C, normal optical;d: 20 °C, polarized optical).

513


24

Page 25 of 31 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 25 26 27 28 29 30 31 32 33 34 35 36 37 38 39 40 41 42 43 44 45 46 47 48 49 50 51 52 53 54 55 56 57 58 59 60

Energy & Fuels

514 515 516 517

518

519 520 521

Figure 7.

Microstructure of the 10 wt% waxy oil doped with EVA (a: 30 °C, normal optical; b: 30 °C, polarized optical;c: 20 °C, normal optical;d: 20 °C, polarized optical).

522


25

Energy & Fuels 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 25 26 27 28 29 30 31 32 33 34 35 36 37 38 39 40 41 42 43 44 45 46 47 48 49 50 51 52 53 54 55 56 57 58 59 60

Page 26 of 31

523 524 525 526 527

528

529 530 531

Figure 8.

Microstructure of the 10 wt% waxy oil doped with asphaltenes (a: 30 °C, normal optical; b: 30 °C, polarized optical;c: 20 °C, normal optical;d: 20 °C, polarized optical).

532


26

Page 27 of 31 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 25 26 27 28 29 30 31 32 33 34 35 36 37 38 39 40 41 42 43 44 45 46 47 48 49 50 51 52 53 54 55 56 57 58 59 60

Energy & Fuels

533 534 535 536 537

538

539 540 541

Figure 9.

Microstructure of the 10 wt% waxy oil doped with EVA/asphaltenes (a: 30 °C, normal optical; b: 30 °C, polarized optical;c: 20 °C, normal optical;d: 20 °C, polarized optical).

542


27

Energy & Fuels

543 544 545

546 Percentage of precipitated asphaltenes / wt%

1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 25 26 27 28 29 30 31 32 33 34 35 36 37 38 39 40 41 42 43 44 45 46 47 48 49 50 51 52 53 54 55 56 57 58 59 60

Page 28 of 31

547 548 549

Figure 10.

7.5

7.46

7.36

7.51 7.15

7.0 6.87

6.85

6.5

6.39 6.34

without EVA with EVA

6.0 5.5 5.0

5.65 5.52

1:3 1:20 1:1 1:5 1:10 Volume ratio of mixed solution/n-pentane (c)

The precipitated asphaltenes without (a) and with (b) the addition of EVA; the percentage of

precipitated asphaltenes at different volume ratios of mixed solution and n-pentane (c).

550


28

Page 29 of 31 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 25 26 27 28 29 30 31 32 33 34 35 36 37 38 39 40 41 42 43 44 45 46 47 48 49 50 51 52 53 54 55 56 57 58 59 60

Energy & Fuels

551

552 553 554

Figure 11

Schematic illustration of the synergistic mechanism of EVA and resin stabilized asphaltenes for improving the flow behavior of waxy oil.

555


29

Energy & Fuels 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 25 26 27 28 29 30 31 32 33 34 35 36 37 38 39 40 41 42 43 44 45 46 47 48 49 50 51 52 53 54 55 56 57 58 59 60

556

Page 30 of 31

Tables

557 558

Table 1.

The pour points of the waxy oils undoped/doped with EVA, asphaltenes and EVA/asphaltenes. Waxy oil type

Dosage

Pour point / °C

undoped

36

+100 ppm EVA

31

+0.75 wt%asphaltenes

30

+100 ppm EVA/0.75 wt% asphaltenes

EthyleneâVinyl Acetate Copolymer and Resin-Stabilized Asphaltenes

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