Polyoxometalate/Cellulose Nanofibrils Aerogels for Highly Efficient Oxidative Desulfurization

Polyoxometalate (POM) presents great potential in oxidative desulfurization (ODS) reaction. However, the high dissolubility of POM in common solvents makes it difficult to recycle. Besides, the small specific surface area of POM also limits the interaction between them and the substrate. Depositing polyoxometalates onto three-dimensional (3D) network structured materials could largely expand the application of POM. Here, the surfaces of cellulose nanofibrils (CNFs) were modified with very few (3-Aminopropyl) trimethoxysilane (APTS) to endow positive charges on the surfaces of CNFs, and then phosphotungstic acid (PTA) was loaded to obtain the aerogel A-CNF/PTA as the ODS catalyst. FT-IR indicated the successful deposition of PTA onto aminosilane modified CNF surfaces. UV-VIS further suggested the stability of PTA in the aerogels. BET and SEM results suggested the increased specific surface area and the relatively uniform 3D network structure of the prepared aerogels. TGA analysis indicated that the thermal stability of the aerogel A-CNF/PTA50% was a little higher than that of the pure CNF aerogel. Most importantly, the aerogel A-CNF/PTA50% showed good catalytic performance for ODS. Catalysis results showed that the substrate conversion rate of the aerogel A-CNF/PTA50% reached 100% within 120 min at room temperature. Even after five cycles, the substrate conversion rate of the aerogel A-CNF/PTA50% still reached 91.2% during the dynamic catalytic process. This work provides a scalable and facile way to stably deposit POM onto 3D structured materials.

POM clusters have stable chemical properties, adjustable acidity and nanometer size, and are often used for catalytic ODS of fuel oil [15]. Discrete POM clusters can be viewed as transferable building blocks for the development of functional materials [16]. For example, organic-inorganic POM-containing hybrids or composites via non-covalent interactions (electrostatic static interaction, hydrogen bonding, van der Waals interactions) have been fabricated [17,18]. Compared with other ionic compounds, POM clusters possess lower surface charge density, which results in high dissolubility in a variety of solvents [19]. This is key for fabricating self-assembled POM-based hybrids or composites. Lay-by-lay (LbL) or Langmuir-Blodgett (LB) films obtained via the cation exchange method driven by electrostatic interaction are typical examples of POM-based self-assembled POM-containing The interaction between PTA and surface modified CNFs was obviously enhanced, which could be confirmed by the dissolution behaviors of the CNF aerogels. As shown in Figure 1B, when the aerogel CNF/PTA50% was soaked into acetonitrile, PTA partially dissolved into the solvent, which resulted in the obvious adsorption peak in the UV spectra. However, the UV spectrum of the aerogel A-CNF/PTA50% almost showed no presence of PTA adsorption peaks after depositing PTA onto aminosilanized CNFs [35]. This proved the CNF surface aminosilane modification could significantly enhance the stability of PTA on the aerogels [36].  W-Oc-W, W-O-P) from PTA ( Figure S2), which could be clearly observed in the FT spectra of the aerogels CNF/PTA50% and A-CNF/PTA50% [29][30][31][32][33][34]. This indicated PTA was successfully loaded on unmodified and modified CNFs. The interaction between PTA and surface modified CNFs was obviously enhan which could be confirmed by the dissolution behaviors of the CNF aerogels. As show Figure 1B, when the aerogel CNF/PTA50% was soaked into acetonitrile, PTA parti dissolved into the solvent, which resulted in the obvious adsorption peak in the UV s tra. However, the UV spectrum of the aerogel A-CNF/PTA50% almost showed no p ence of PTA adsorption peaks after depositing PTA onto aminosilanized CNFs [35]. proved the CNF surface aminosilane modification could significantly enhance the sta ity of PTA on the aerogels [36].  The interaction between PTA and surface modified CNFs was obviously enhanced, which could be confirmed by the dissolution behaviors of the CNF aerogels. As shown in Figure 1B, when the aerogel CNF/PTA50% was soaked into acetonitrile, PTA partially dissolved into the solvent, which resulted in the obvious adsorption peak in the UV spectra. However, the UV spectrum of the aerogel A-CNF/PTA50% almost showed no presence of PTA adsorption peaks after depositing PTA onto aminosilanized CNFs [35]. This proved the CNF surface aminosilane modification could significantly enhance the stability of PTA on the aerogels [36].

Morphology and Porosity of CNF Aerogels
The micromorphology of the aerogels was characterized by SEM [37,38]. As shown in Figure 2, compared with the SEM image of the pure CNF aerogel, the aerogels CNF/PTA50% and A-CNF/PTA50% showed the more uniform 3D network structures. This would benefit for the interaction between the substrate and the PTA, resulting in the improved catalysis efficiency [26,[39][40][41][42]. The formation of the relatively uniform 3D networks is highly related with the hydrogen bonding interaction between PTA and CNFs. Compared with the aerogel CNF/PTA50%, the surface of the aerogel A-CNF/PTA50% became rougher, which is highly relevant to the enhanced electrostatic interaction between the positively charged aminosilanized CNFs and the anionic clusters of PTA.
in Figure 2, compared with the SEM image of the pure CNF aerogel, the aerogels CNF/PTA50% and A-CNF/PTA50% showed the more uniform 3D network structures. This would benefit for the interaction between the substrate and the PTA, resulting in the improved catalysis efficiency [26,[39][40][41][42]. The formation of the relatively uniform 3D networks is highly related with the hydrogen bonding interaction between PTA and CNFs. Compared with the aerogel CNF/PTA50%, the surface of the aerogel A-CNF/PTA50% became rougher, which is highly relevant to the enhanced electrostatic interaction between the positively charged aminosilanized CNFs and the anionic clusters of PTA.
The porosity of CNF aerogels was explored by BET. As shown in Figure 3A, compared with the pure CNF aerogel, the specific surface area of the aerogels CNF/PTA50% and A-CNF/PTA50% increased to 14.71 and 7.08 m 2 /g, respectively (Table S1). Besides, compared with the pure CNF aerogel, the average pore size diameter of the aerogels CNF/PTA50% and A-CNF/PTA50% both decreased to 4.36 and 6.15 nm ( Figure 3B), respectively. The increased specific surface area and decreased pore diameter both facilitate the interaction between substrate and catalyst, resulting in improved catalysis efficiency [43][44][45].

Static Catalysis
PTA shows high catalytic activity for ODS reaction. In this paper, methyl phenyl sulfide was used as the substrate for ODS reaction, transforming into the middle product methyl phenyl sulfone (MPSX), and then transforming the final catalytic product methyl phenyl sulfone (MPSO) under the catalytic oxidation of CNF/PTA aerogels [27,[46][47][48][49]. Methyl phenyl sulfide is toxic, but sulfoxide and sulphone are widely used in many fields, such as pharmaceutical material chemistry [50].
The substrate could not be absorbed by the CNF aerogels, while the catalytic products could be absorbed by the CNF aerogels, as evidenced by the GC spectra ( Figure S5). The porosity of CNF aerogels was explored by BET. As shown in Figure 3A, compared with the pure CNF aerogel, the specific surface area of the aerogels CNF/PTA50% and A-CNF/PTA50% increased to 14.71 and 7.08 m 2 /g, respectively (Table S1). Besides, compared with the pure CNF aerogel, the average pore size diameter of the aerogels CNF/PTA50% and A-CNF/PTA50% both decreased to 4.36 and 6.15 nm ( Figure 3B), respectively. The increased specific surface area and decreased pore diameter both facilitate the interaction between substrate and catalyst, resulting in improved catalysis efficiency [43][44][45].
Molecules 2022, 27, x FOR PEER REVIEW

Morphology and Porosity of CNF Aerogels
The micromorphology of the aerogels was characterized by SEM [37,38]. As s in Figure 2, compared with the SEM image of the pure CNF aerogel, the ae CNF/PTA50% and A-CNF/PTA50% showed the more uniform 3D network struc This would benefit for the interaction between the substrate and the PTA, resulting improved catalysis efficiency [26,[39][40][41][42]. The formation of the relatively uniform 3 works is highly related with the hydrogen bonding interaction between PTA and Compared with the aerogel CNF/PTA50%, the surface of the aerogel A-CNF/PTA50 came rougher, which is highly relevant to the enhanced electrostatic interaction be the positively charged aminosilanized CNFs and the anionic clusters of PTA.
The porosity of CNF aerogels was explored by BET. As shown in Figure 3A pared with the pure CNF aerogel, the specific surface area of the aerogels CNF/PT and A-CNF/PTA50% increased to 14.71 and 7.08 m 2 /g, respectively (Table S1). Be compared with the pure CNF aerogel, the average pore size diameter of the ae CNF/PTA50% and A-CNF/PTA50% both decreased to 4.36 and 6.15 nm ( Figure 3 spectively. The increased specific surface area and decreased pore diameter both fac the interaction between substrate and catalyst, resulting in improved catalysis effi [43][44][45].

Static Catalysis
PTA shows high catalytic activity for ODS reaction. In this paper, methyl phen fide was used as the substrate for ODS reaction, transforming into the middle pr methyl phenyl sulfone (MPSX), and then transforming the final catalytic product m phenyl sulfone (MPSO) under the catalytic oxidation of CNF/PTA aerogels [27,4 Methyl phenyl sulfide is toxic, but sulfoxide and sulphone are widely used in many such as pharmaceutical material chemistry [50].
The substrate could not be absorbed by the CNF aerogels, while the catalytic ucts could be absorbed by the CNF aerogels, as evidenced by the GC spectra (Figu

Static Catalysis
PTA shows high catalytic activity for ODS reaction. In this paper, methyl phenyl sulfide was used as the substrate for ODS reaction, transforming into the middle product methyl phenyl sulfone (MPSX), and then transforming the final catalytic product methyl phenyl sulfone (MPSO) under the catalytic oxidation of CNF/PTA aerogels [27,[46][47][48][49]. Methyl phenyl sulfide is toxic, but sulfoxide and sulphone are widely used in many fields, such as pharmaceutical material chemistry [50].
The substrate could not be absorbed by the CNF aerogels, while the catalytic products could be absorbed by the CNF aerogels, as evidenced by the GC spectra ( Figure S5). This means that the disappearance of substrate peaks in the GC spectrum is not due to adsorption by aerogels, but transformation, and it also indicates that aerogels can collect part of intermediates and products. Therefore, in this paper, the catalysis efficiency was evaluated by the substrate conversion rate, which was calculated according to Equations (1) and (2). The substrate conversion rate of the aerogels CNF/PTA50% reached nearly 100% within 60 min at the first-time catalysis. However, the substrate conversion rate of the aerogel CNF/PTA50% started to decrease from the third-time catalysis, and sharply decreased to 60% at the fifth-time catalysis ( Figure 4A). This is because that part of the PTA fell off from the CNF aerogel during the catalysis, resulting in reduced catalytic efficiency [25,[51][52][53][54][55]. This was consistent with the dissolution behavior of the CNF/PTA aerogels. This means that the disappearance of substrate peaks in the GC spectrum is not due to adsorption by aerogels, but transformation, and it also indicates that aerogels can collect part of intermediates and products. Therefore, in this paper, the catalysis efficiency was evaluated by the substrate conversion rate, which was calculated according to Equations (1) and (2). The substrate conversion rate of the aerogels CNF/PTA50% reached nearly 100% within 60 min at the first-time catalysis. However, the substrate conversion rate of the aerogel CNF/PTA50% started to decrease from the third-time catalysis, and sharply decreased to 60% at the fifth-time catalysis ( Figure 4A). This is because that part of the PTA fell off from the CNF aerogel during the catalysis, resulting in reduced catalytic efficiency [25,[51][52][53][54][55]. This was consistent with the dissolution behavior of the CNF/PTA aerogels. Loading PTA onto the surfaces of aminosilanized CNFs can effectively prevent PTA falling off from the aerogels. The positive charges on aminosilanized CNF surfaces benefit for PTA stabilization, while excessive aminosilane groups suppressed the catalysis activity of PTA, as shown in Figure 4B. This is due to the aminosilane groups being slightly alkaline in water, which suppresses the catalytic activity of PTA. The excessive aminosilane groups would also affect the stability of PTA [56]. However, CNFs with slight APTS (0.1%) modification still showed the poor catalytic stability during the cycle catalysis process (Figure S3), in which the substrate conversion rate reduced to about 60% at the fourth-time catalysis. However, the CNF aerogel with 1.0% APTS modification showed a good substrate conversion rate (82.64%) at the fourth-time catalysis ( Figure S3). Compared with the initial catalysis, the substrate conversion rate of the aerogel A-CNF/PTA50% slightly decreased, which probably resulted from the poor dispersibility of CNFs and the Loading PTA onto the surfaces of aminosilanized CNFs can effectively prevent PTA falling off from the aerogels. The positive charges on aminosilanized CNF surfaces benefit for PTA stabilization, while excessive aminosilane groups suppressed the catalysis activity of PTA, as shown in Figure 4B. This is due to the aminosilane groups being slightly alkaline in water, which suppresses the catalytic activity of PTA. The excessive aminosilane groups would also affect the stability of PTA [56]. However, CNFs with slight APTS (0.1%) modification still showed the poor catalytic stability during the cycle catalysis process ( Figure S3), in which the substrate conversion rate reduced to about 60% at the fourth-time catalysis. However, the CNF aerogel with 1.0% APTS modification showed a good substrate conversion rate (82.64%) at the fourth-time catalysis ( Figure S3). Compared with the initial catalysis, the substrate conversion rate of the aerogel A-CNF/PTA50% slightly decreased, which probably resulted from the poor dispersibility of CNFs and the aggregated structure resulting in the destruction of the aerogels. When the dosage of APTS was fixed at 1.0% and the dosage of PTA was higher than 50%, the substrate conversion efficiency of the aerogel A-CNF/PTA50% could reach 100% within 30 min ( Figure 4C). To improve the stability of PTA on the CNF surfaces and preserve the high catalytic performance of PTA, the optimal preparation conditions for CNF aerogels were as follows: Volume ratio 1.0% (APTS/CNF suspension, V/V) of APTS, and mass percentage 50% (PTA/CNF, m/m) of PTA.

Dynamic Catalysis
In fact, compared with static catalysis experiments, dynamic catalysis shows greater potential for industrial applications [57]. Static catalysis experiments have confirmed the optimal substrate conversion rate of the aerogel A-CNF/PTA50% under mild catalytic conditions. Unfortunately, we found that a small amount of CNFs fell off from the aerogels during the catalytic process, which might have resulted from the highly aggregated and poorly dispersed structure of CNFs. In order to avoid the destruction of the CNF aerogel affecting the catalytic process, we further homogenized the raw material and diluted it to 0.6 wt% before modifying it with APTS. Figure 5D shows the comparison of cyclic substrate efficiency of the aerogels CNF/PTA50% and A-CNF/PTA50%. As shown in Figure 4D, the aerogels CNF0.6/PTA50% and A-CNF0.6/PTA50% showed highly different dynamic catalysis behavior. The substrate conversion rate of the aerogel A-CNF0.6/PTA50% was up to 90% even after five cycles, while the substrate conversion rate of the aerogel CNF0.6/PTA50% was lower than 50% after five cycles. This further confirmed that depositing PTA onto positively charged CNFs could preserve the high catalysis performance of PTA and avoid the dissolution of PTA.
Molecules 2022, 27, x FOR PEER REVIEW 6 of aggregated structure resulting in the destruction of the aerogels. When the dosage APTS was fixed at 1.0% and the dosage of PTA was higher than 50%, the substrate co version efficiency of the aerogel A-CNF/PTA50% could reach 100% within 30 min (Figu 4C). To improve the stability of PTA on the CNF surfaces and preserve the high cataly performance of PTA, the optimal preparation conditions for CNF aerogels were as f lows: Volume ratio 1.0% (APTS/CNF suspension, V/V) of APTS, and mass percentage 50 (PTA/CNF, m/m) of PTA.

Dynamic Catalysis
In fact, compared with static catalysis experiments, dynamic catalysis shows grea potential for industrial applications [57]. Static catalysis experiments have confirmed t optimal substrate conversion rate of the aerogel A-CNF/PTA50% under mild catalytic co ditions. Unfortunately, we found that a small amount of CNFs fell off from the aerog during the catalytic process, which might have resulted from the highly aggregated a poorly dispersed structure of CNFs. In order to avoid the destruction of the CNF aerog affecting the catalytic process, we further homogenized the raw material and diluted it 0.6 wt% before modifying it with APTS. Figure 5D shows the comparison of cyclic su strate efficiency of the aerogels CNF/PTA50% and A-CNF/PTA50%. As shown in Figu  4D, the aerogels CNF0.6/PTA50% and A-CNF0.6/PTA50% showed highly different d namic catalysis behavior. The substrate conversion rate of the aerogel A-CNF0.6/PTA50 was up to 90% even after five cycles, while the substrate conversion rate of the aerog CNF0.6/PTA50% was lower than 50% after five cycles. This further confirmed that depo iting PTA onto positively charged CNFs could preserve the high catalysis performance PTA and avoid the dissolution of PTA. Figure 5. C1s spectra of A-CNF/PTA50% before (A) and after (C) catalysis. W4f spectra of CNF/PTA50% before (B) and after (D) catalysis. Figure 5. C1s spectra of A-CNF/PTA50% before (A) and after (C) catalysis. W4f spectra of A-CNF/PTA50% before (B) and after (D) catalysis.

Changes of CNF Aerogels before and after Catalysis
In order to investigate the elemental composition change, the aerogel A-CNF/PTA50% before and after catalysis were characterized with XPS [30]. As shown in Table 1 and Figure 5, the peaks at 284.6 eV, 285.7 eV, 287.6 eV are attributed to C-C, C-O, C=O, and the binding energy at 37.3 and 35.1 eV correspond to W-4f1 and W-4f2, respectively [26,30,31,34]. The content of C=O and C-O increased from 6.98% to 8.36% and 44.45% to 46.46%, respectively, while the content of C-C decreased from 48.37% to 45.18%. This is probably due to the oxidation reaction on CNFs during the catalytic process, in which H 2 O 2 partially oxidized CNFs resulting in the increased C=O and C-O [58,59]. The content of the different valence states of element W basically remained unchanged, indicating a stable chemical structure of PTA during the catalytic process.

Thermal Stability of CNF Aerogels
The thermal stability of the CNF aerogels was assessed by thermogravimetric analysis (TGA) [20]. As shown in Figure 6, the slight weight loss lower than 100 • C was due to loss of water that is possibly from the adsorbed moisture of the aerogels during storage. The main pyrolysis process of cellulose is accompanied by a large weight loss [60]. Compared with the CNF aerogel, the initial degradation and mid-degradation temperatures of the aerogel A-CNF/PTA50% increased from 284.2 • C to 293.2 • C, and from 291.5 • C to 295.8 • C (increased by 3.2% and 0.9%, respectively). Correspondingly, the temperature at the maximum degradation rate of the aerogels CNF/PTA50% and A-CNF/PTA50% decreased by 16.3 • C and 17.7 • C, respectively ( Figure 6B). It can be seen that with the addition of PTA, the thermal stability of the CNF aerogels is slightly improved. The aerogel A-CNF/PTA showed the slightly enhanced thermal stability, which can ensure the smooth catalytic process without degradation of catalyst [61].

Changes of CNF Aerogels before and after Catalysis
In order to investigate the elemental composition change, the aerogel A-CNF/PTA50% before and after catalysis were characterized with XPS [30]. As shown in Table 1 and Figure 5, the peaks at 284.6 eV, 285.7 eV, 287.6 eV are attributed to C-C, C-O, C=O, and the binding energy at 37.3 and 35.1 eV correspond to W-4f1 and W-4f2, respectively [26,30,31,34]. The content of C=O and C-O increased from 6.98% to 8.36% and 44.45% to 46.46%, respectively, while the content of C-C decreased from 48.37% to 45.18%. This is probably due to the oxidation reaction on CNFs during the catalytic process, in which H2O2 partially oxidized CNFs resulting in the increased C=O and C-O [58,59]. The content of the different valence states of element W basically remained unchanged, indicating a stable chemical structure of PTA during the catalytic process. Table 1. Elemental analysis of A-CNF/PTA50% before and after the catalytic process.

Sample
Elemental Quantitative Analysis by XPS (%)

Thermal Stability of CNF Aerogels
The thermal stability of the CNF aerogels was assessed by thermogravimetric analysis (TGA) [20]. As shown in Figure 6, the slight weight loss lower than 100 °C was due to loss of water that is possibly from the adsorbed moisture of the aerogels during storage. The main pyrolysis process of cellulose is accompanied by a large weight loss [60]. Compared with the CNF aerogel, the initial degradation and mid-degradation temperatures of the aerogel A-CNF/PTA50% increased from 284.2 °C to 293.2 °C, and from 291.5 °C to 295.8 °C (increased by 3.2% and 0.9%, respectively). Correspondingly, the temperature at the maximum degradation rate of the aerogels CNF/PTA50% and A-CNF/PTA50% decreased by 16.3 °C and 17.7 °C, respectively ( Figure 6B). It can be seen that with the addition of PTA, the thermal stability of the CNF aerogels is slightly improved. The aerogel A-CNF/PTA showed the slightly enhanced thermal stability, which can ensure the smooth catalytic process without degradation of catalyst [61].
CNFs was further homogenized and dispersed into 0.6 wt% suspension; 1.0% APTS was added into 20 g of 0.6 wt% CNF suspension. The mixture was stirred at room temperature for 2 h and then 50% PTA was added into the suspension and stirred at room temperature (25 • C) for 30 min. After pre-freezing in an ultra-low temperature refrigerator and freeze-drying for 48 h, A-CNF0.6/PTA50% was obtained.

Characterization
The samples were characterized by FT-IR (Nicolette IS50-Nicolet Continuum, Thermo Fisher Scientific, Waltham, MA, USA), and the spectra were recorded in 4000-400 cm −1 . The microstructures of aerogels were obtained by SEM (Sigma 300, Zeiss, Jena, German). The specific surface area was analyzed with BET (ASAP 2020, Micromeritics Company, Lawrenceville, GA, USA). The thermal stability of CNF aerogels was measured by TG-DSC (TGA, Mettler TGA/DSC3+, Columbus, OH, USA). The CNF aerogels before and after catalysis were analyzed by XPS (Axis Ultra DLD, Kratos, Manchester, UK). The dissolution of the catalysts was measured by using ultraviolet-visible spectrophotometry (UV-VIS) (UV-1800, Shimadzu, Kyoto, Japan). Gas chromatograph (GC) (GC7920-TF2A, Zhong Jiao Jin Yuan, Beijing, China) was used to detect the conversion rate of the substrate during the catalyst process.

Dissolution Behaviors of the CNF Aerogels
The 7 mg aerogel samples were immersed in a 6.6 mL solution of acetonitrile and H 2 O (acetonitrile: H 2 O, V:V, 10:1), respectively. After standing for 48 h, the solution was analyzed by UV-VIS.

Static Catalytic Experiments
The catalytic experiments of the CNF aerogels were performed as follows. At different stages of the catalytic reaction, 10 µL of the substrate solution (260 µL substrate, 130 µL n-octane, 600 µL H 2 O 2 and 6 mL acetonitrile and 7 mg catalyst) was collected and injected into the gas chromatograph. Catalytic experiments were carried out at room temperature (25 • C) and samples were taken every 30 min. The whole catalytic reaction process was 90 min. The substrate conversion rate can be calculated according to the change of relative (1) in which I (species, t) is the peak area of the sample at time t; I (octane, t) is the peak area of the internal standard n-octane at time t; I (sulfide, t 0 ) is the peak area of the substrate at time t 0 ; I (octane, t 0 ) is the peak area of the internal standard n-octane at time t 0 ; C is the relative value of the peak; α t is the substrate conversion rate.

Dynamic Catalytic Experiments
A 28 mg amount of the aerogel A-CNF/PTA was filled into the catalytic column. The substrate solution (the same as in Section 3.4) flowed through the catalytic column at a rate of 2 mL/h. The whole process was carried out at 40 • C and lasted for 2 h. A 10 µL amount of the liquid which flowed out of the catalytic column was collected and injected into the gas chromatograph. The substrate conversion rate was calculated according to Equations (1) and (2).

Conclusions
In summary, we successfully prepared aminolisanized CNFs for depositing PTA (the aerogel A-CNF/PTA), and we proved that the aminosilanization of CNF surfaces could obviously enhance the stability of PTA. The optimal preparation conditions of the A-CNF/PTA aerogel were as follows: Volume ratio of APTS 1.0%, and mass percentage of PTA 50%. The aerogel A-CNF/PTA50% presented a relatively uniform 3D network structure with a specific surface area of 7.08 m 2 /g, and the average pore size was 6.15 nm. The aerogel presented high static catalytic activity; that is, the substrate conversion rate was close to 100% within 30 min at room temperature. The aerogel A-CNF/PTA50% also showed excellent dynamic catalytic performance during the cycle catalytic process, in which the substrate conversion rate was above 90% after catalysis occurred five times. The facile strategy developed here may offer great possibility for the production of economical and recyclable biomass-based ODS catalysts.
Supplementary Materials: The following supporting information can be downloaded at: https: //www.mdpi.com/article/10.3390/molecules27092782/s1, Table S1. BET surface areas, pore volumes and pore sizes of the aerogels; Table S2. BJH surface areas, pore sizes of the aerogels; Figure S1. Catalysis process of PTA; Figure S2. The structure of PTA (H3O40PW12·xH2O); Figure S3. Effect of different APS addition amount on cyclic catalysis; Figure S4. UV spectrum of PTA (H3O40PW12·xH2O); Figure S5. GC chromatograms of different catalytic reactions at 0 min and 90 min; Figure S6. SEM of aerogels before (A, B) and after catalytic reaction (C, D).

Author Contributions:
This work was carried out in collaboration between all authors. R.S. performed the experimental investigation. R.S. and H.W. performed the data curation and the analysis. R.S. wrote the first draft of the manuscript. X.Z., performed the funding acquisition. C.L. performed the writing-review and the editing, funding acquisition, and the project administration. All authors have read and agreed to the published version of the manuscript.

Conflicts of Interest:
The authors declare that there is no conflict of interest.
Sample Availability: Samples of the compounds are not available from the authors.