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Article

Fabrication of Biomass Derived Pt-Ni Bimetallic Catalyst and Its Selective Hydrogenation for 4-Nitrostyrene

by
Siyu Long
1,2,
Lingyu Zhang
1,2,
Zhuoyue Liu
1,2,
Huibin Jiao
3,
Aiwen Lei
4,
Wei Gong
1,2,* and
Xianglin Pei
1,4,*
1
School of Materials and Architectural Engineering, Guizhou Normal University, Guiyang 550025, China
2
Guizhou Key Laboratory of Inorganic Nonmetallic Functional Materials, Guizhou Normal University, Guiyang 550025, China
3
School of Materials Science and Engineering, Guizhou Minzu University, Guiyang 550025, China
4
College of Chemistry and Molecular Sciences, Wuhan University, Wuhan 430072, China
*
Authors to whom correspondence should be addressed.
Nanomaterials 2022, 12(17), 2968; https://0-doi-org.brum.beds.ac.uk/10.3390/nano12172968
Submission received: 18 July 2022 / Revised: 22 August 2022 / Accepted: 23 August 2022 / Published: 27 August 2022
(This article belongs to the Special Issue Nanostructures for Surfaces, Catalysis and Sensing)
Browse Figures
Versions Notes

Abstract

:
The hydrogenation products of aromatic molecules with reducible groups (such as C=C, NO2, C=O, etc.) are relatively critical intermediate compounds in fine chemicals, but how to accurately reduce only specific groups is still challenging. In this work, a bimetallic Pt-Ni/Chitin catalyst was prepared for the first time by using renewable biomass resource chitin as support. As the carrier, the chitin was constructed into porous nanofibrous microspheres through the sol-gel strategy, which was favorable for the adhesion of nano-metals and the exchange of reactive substances due to its large surface area, porous structure, and rich functional groups. Then the Pt-Ni/Chitin catalyst was applied to selective hydrogenation with the model substrate of 4-nitrostyrene. As the highly dispersed Pt-Ni NPs with abundant exposed active sites and the synergistic effect of bimetals, the Pt-Ni/Chitin catalyst could efficiently and selectively hydrogenate only NO2 or C=C with yields of ~99% and TOF of 660 h−1, as well as good stability. This utilization of biomass resources to build catalyst materials would be important for the green and sustainable chemistry.

1. Introduction

Catalytic hydrogenation based on transition metal catalysts is of great significance in both laboratory and industry and has been widely developed [1,2]. Typically, the hydrogenation products of arylamines (from nitroaromatics) and aralkyls (from aryl olefins) are all the critical intermediate compounds in fine chemicals, and have a wide range of applications in pharmaceutical, chemical, petroleum, cosmetic, and other fields [3,4]. However, the ability of aromatic molecules with reducible functional groups (such as C=C, NO2, C=O, etc.) to be activated or reduced is different [5,6]. How to accurately reduce the appointed groups is still a challenge. For example, in most reported literatures, Pd or Pt based supported catalysts showed excellent catalytic activity in hydrogenation of aromatic molecules with reducible C=C and NO2 groups [7,8,9]. However, due to the strong reduction ability of Pd or Pt nano-metals, the specific ability to reduce only NO2 (or C=C) is weak, i.e., the chemoselectivity is poor [10,11]. To improve the chemoselectivity, various attempts have been conducted, such as changing the hydrogen source, selecting different nano-metal catalysts, constructing alloy catalysts, designing the structure of catalyst supports, etc. [1,2,3,4,10].
Generally, the catalyst support materials play important roles in catalysis, which can disperse the nano-metal particles to improve their utilization, and contribute to the recycling of catalysts [12,13]. In particular, some support materials can interact with nano-metals, either to firmly anchor the nano-metals or change the coordination environment or surface electronic structure of nano-metals, thereby significantly improving the performance of the nano-metal catalysts [14,15]. In recent years, biomass resource chitin has gradually attracted widespread attention as a catalyst carrier material [16]. As the second largest natural polymer on Earth after cellulose, chitin has a wide range of sources and low price, which is suitable for industrial mass production [17,18,19]. Not only that, the chitin molecular chains are rich in characteristic functional groups such as hydroxyl and acetamide, which can coordinate with nano-metals to anchor them firmly, as well as adjusting the coordination environment of the nano-metal catalysts to improve the catalytic performance [18]. Importantly, based on the rigidity of the chitin molecular chain, chitin in nature mostly presents a multi-level micro-nano structure, which can efficiently disperse nano-metals and improve the utilization rate of metal catalysts [19,20]. In addition, the rigid structure of chitin leads to its good thermal and chemical stability, which is also an advantage as a catalyst support [16,17].
In our previous study, we have used the sol-gel strategy to construct a chitin microsphere woven by nanofibrous, which further gave the chitin a larger specific surface area [21]. Herein, going one step further, we used the above microspheres as support to fabricate a series of Pt-based monometallic/bimetallic catalysts and used them for the chemoselective hydrogenation of 4-nitrostyrene. Owing to the rich functional groups and large surface area of chitin microspheres, the nano-metals were well tightly dispersed on the chitin microspheres, proved by various characterizations. Notably, due to the synergistic effect of bimetals, the chitin supported Pt-Ni catalyst could efficiently and selectively hydrogenate only NO2 or C=C on aromatic molecules with good yields by changing the reaction conditions. By using the biomass resource chitin as a carrier, which not only broadens the application chitin materials, but also enables such biomass-based catalysts to be used in photocatalysis, electrocatalysis, and other fields.

2. Experimental Section

2.1. Materials

Chitin was purchased from Zhejiang Golden Shell Biochemical Co., Ltd. (Taizhou, China). Metal salts such as chloroplatinic acid hexahydrate (AR, Pt ≥ 37.5%, H2PtCl6·6H2O), Nickel(II) acetate tetrahydrate (99.9%, Ni(CH3COO)2·4H2O), Palladium acetate (99.9%, Pd(OAc)2), and 4-nitrostyrene (>98%, stabilized with TBC) were purchased from Aladdin (Aladdin Inc., Shanghai, China). Commercial Pt/C (20%) and nano-Pt (99.9%) were purchased from Macklin (Macklin Inc., Shanghai, China). Span 85 (Aladdin Inc., Shanghai, China), Tween 85 (Aladdin Inc., Shanghai, China), and isooctane (99.7%, Tianjin Damao Chemical Reagent Factory, Tianjing, China) were used as received. All other reagents, such as isopropanol, toluene, and hydrochloric acid, were obtained from various commercial sources and used without further purification.

2.2. Synthesis of the Chitin Supported Nano-Metal Catalysts

2.2.1. Synthesis of the Chitin Microspheres

Chitin powders purchased from Zhejiang Golden Shell Biochemistry Co., Ltd. (Zhejiang, China) were dispersed in 100 g NaOH/urea water system (11 wt%/4 wt%) and placed in a low-temperature cold trap for freezing/thawing 3–4 times to obtain a clear, transparent, and mobile chitin solution. The above chitin solution was added into a mixed solution of isooctane, span 85, and tween 85, then fully stirred under ice conditions for 2 h through the suspension emulsion strategy. Then, the reaction mixture temperature was heated to 90 °C, and maintained for 5 min. Subsequently, pH of the solution was adjusted to neutral with 10% HCl to obtain the chitin emulsion microspheres. The chitin emulsion microspheres were further washed with ethanol and water, filtered, and dried for later use.

2.2.2. Synthesis of the Chitin Supported Monometallic Catalysts

Taking Pt/Chitin as an example, a certain amount of H2PtCl6·6H2O ([Pt]:chitin = 1.8 wt%) dissolved in deionized water was added dropwise to 200 mg of chitin microspheres. The mixed solution was stirred for 4 h at room temperature, then washed with deionized water for several times, subsequently reduced with NaBH4 and separated by filtration to obtain the monometallic Pt/Chitin catalyst. The other monometallic catalysts such as Fe/Chitin, Co/Chitin, Ni/Chitin, Cu/Chitin, etc. in this work were prepared using the above method.

2.2.3. Synthesis of the Chitin Supported Bimetallic Catalysts

Taking Pt-Ni/Chitin (3:1) as an example, a certain proportion of well-mixed H2PtCl6·6H2O and Ni(CH3COO)2 ·4H2O ([Pt]:[Ni] = 3:1, mol%) aqueous solution was stirred for 0.5 h at room temperature, and then added dropwise to 200 mg of chitin microspheres ([Pt-Ni]:chitin = 1.8 wt%). The mixed solution was stirred for 4 h at room temperature, then washed with deionized water for several times, subsequently reduced with NaBH4, and separated by filtration to obtain the bimetallic Pt-Ni/Chitin catalyst. The other bimetallic catalysts such as Pt-Fe/Chitin, Pt-Co/Chitin, Pt-Ni/Chitin, Pt-Cu/Chitin, etc. in this work were prepared using the above method.

2.2.4. Selective Hydrogenation for 4-Nitrostyrene

Selective hydrogenation of C=C to C-C for 4-nitrostyrene: The hydrogenation of 4-nitrostyrene was used to evaluate the catalytic activity of the chitin supported catalysts. In a typical experiment, 0.5 mmol of 4-nitrostyrene, 4 mg of nano-metal catalysts, and 5 mL of solvents were added to a 25 mL reaction flask, the reactor was charged with H2 with pressure of 1 bar, and the reaction was stirred in a water bath for several hours. The reaction mixture was analyzed with gas chromatography (GC) to analyze the reaction mixture with biphenyl as the internal standard substance. Control experiments were performed with Pd/Chitin, Fe/Chitin, Co/Chitin, Ni/Chitin, Cu/Chitin, etc.
Selective hydrogenation of NO2 to NH2 for 4-nitrostyrene: In a typical procedure, 0.5 mmol of 4-nitrostyrene, 2 mmol of NaBH4, 4 mg of Pt-Ni/Chitin, and 5 mL of solvents were added to a 25 mL reaction flask, and the mixture was magnetically stirred with magnetic stirring for several hours. After the reaction was complete, the reaction mixture was analyzed with GC to analyze the reaction mixture with biphenyl as the internal standard substance.

2.3. Characterization

X-ray diffraction (XRD) pattern was recorded by an X-ray powder diffraction (XRD, Rigaku Miniflex600 with Cu Kα radiation, λ = 1.5406 Å, Tokyo, Japan). Infrared spectroscopy was carried out by using a Fourier transform infrared spectrometer (FT-IR, PerkinElmer Corporation/model 1600, MA, USA). Nitrogen adsorption and desorption measurements were recorded by a Micromeritics AsAp2020 (Norcross, GA, USA). X-ray photoelectron spectroscopy (XPS) was collected on a VG Multi Lab 2000 system with a monochromatic A1 X-ray source (Thermo Fisher scientific ESCALAB 250Xi, MA, USA). GC yields were recorded through a Varian GC 2014 gas chromatography instrument with an FID detector. Scanning electron microscopy (SEM) images were observed by field emission scanning electron microscopy (FESEM, Zeiss SUPRA 55 Sapphire, Oberkochen, Bartenburg State, Germany) at an accelerating voltage of 5 kV. Transmission electron microscopy (TEM) images were collected on a JEM-2010 (HT) electron microscope (JEOL, Tokyo, Japan) with an accelerating voltage of 200 kV. Before the TEM observation, the sample was thoroughly ground, then we impregnated it with ethanol and dropped the suspension onto a copper grid.

3. Results and Discussion

3.1. Formation of the Chitin-Supported Metal Catalysts and Its Selective Hydrogenation of C=C to C-C

According to the sol-gel strategy, chitin raw materials acquired from the market were physically dispersed in the aqueous NaOH/urea system at low temperature to break up its large numbers of inter- and intra-molecular hydrogen bonds. Then, we used isooctane as the oil phase, Span 85 and Tween 85 as the surfactant, and obtained a nanofibrous chitin microsphere via emulsion method by sol-gel process. During the sol-gel process, the hydrogen bonds between the chitin molecular chains recombine, resulting in the aggregation and re-arrangement of chitin molecular chains, and then form spherical nanofibrous microspheres through the suspension emulsion method [21]. Further, the chitin microspheres were used as supports and impregnated with metal precursors, which were subsequently reduced with reductant to obtain the chitin supported nano-metal catalysts. The schematic diagram of the formation process is shown in Figure 1.
Before figuring out the structure of the chitin supported nano-metal catalysts, we directly used these catalysts for catalytic chemical reactions. Usually, it is difficult for aromatic molecules with reducible C=C or NO2 groups to selectively hydrogenate only C=C or NO2 groups [3,4,6]; for example, the aralkyl products, which play important roles in large chemical production, petroleum, cosmetic, organic intermediates, material chemistry, medicinal chemistry, etc. Herein, first of all, the aim of selectively hydrogenating only C=C was attempted, and the 4-nitrostyrene was used as the model substrate to evaluate the catalytic activity of these different chitin supported catalysts. First, we took the most common hydrogenation catalysts of Pd and Pt species reported in the literature as examples [22]. To select the best reaction conditions, the reaction solvent (Table S1 entries 1–8) and temperature (Table S1 entries 8–11) were screened. As shown in Table 1, by using isopropyl alcohol as the solvent, the Pt/Chitin catalyst could selectively hydrogenate only C=C with 4-nitroethylbenzene yield of 87% at room temperature in 24 h or even longer (Table 1, entry 1; Table S1, entry 8). Although the selectivity was good, the reaction time was too long. In contrast, the Pd/Chitin catalyst could give 92% yield of 4-nitroethylbenzene and 3% yield of 4-aminoethylbenzene in 1 h (Table 1, entry 2). However, the 4-nitroethylbenzene gradually turned into 4-aminoethylbenzene with an increase in the reaction time (Table 1, entry 3). Combining the high activity of Pd metal and the high selectivity of Pt metal, Pt-Pd/Chitin bimetallic catalyst was designed, which was effective in improving the selectivity of 4-nitroethylbenzene (Table 1, entry 5), but also did not solve the problem of -NO2 to NH2 group by extending the reaction time (Table 1, entry 6). To further improve the selectivity of 4-nitroethylbenzene and taking into account the consideration of low cost, a series of bimetallic catalysts combining Pt with common non-precious metals (Fe, Co, Ni, Cu) were designed [15,23,24,25,26]. It could be seen that the Pt-Ni/Chitin bimetallic catalyst could achieve the best selectivity of 4-nitroethylbenzene with a yield of 99% in 3 h or even longer time (Table 1, entries 7–10). As comparisons, the monometallic Fe/Chitin, Co/Chitin, Ni/Chitin, Cu/Chitin catalysts and blank chitin could not complete the conversion with poor activity (Table S2; Table 1, entry 4). In addition, the commercial Pt/C and nano-Pt catalysts could only give the target product yield of 42% and 5%, respectively (Table 1, entries 14–15), further suggesting the good catalytic activity of Pt-Ni/Chitin catalyst. Moreover, the optimal ratio of Pt to Ni in chitin was also explored, and it was found that the best selectivity of 4-nitroethylbenzene with yield of 99% was achieved when Pt:Ni was 3:1 (mol%, Table 1, entries 10–12), and the calculated TOF and TON were 660 h−1 and 1980, respectively (entry 10). After 48 h, the yield could also be maintained at 99%, effectively realizing the selective hydrogenation only C=C group (Table 1, entry 13). The probable mechanism for the selective hydrogenation of C=C to C-C was shown in Figure S5, the Pt-Ni NPs on the catalyst promoted the dissociation of hydrogen to form metal-H, which further attacked C=C to lead to the formation of saturated C-C. We believed that the Pt-Ni bimetallic catalyst formed by the introduction of Ni metal effectively promoted the selective hydrogenation of 4-nitrostyrene to 4-nitroethylbenzene.

3.2. Structure of the Pt-Ni catalyst

The good catalytic activity and selectivity of Pt-Ni catalyst encourage us to explore its structure. In the study of the crystal structures, X-ray diffraction (XRD) patterns in Figure 2a showed that these chitin-supported catalysts all had distinct characteristic diffraction peaks at 2θ = 9.4°, 12.8°, 19.2°, and 26.3° after loading the nano-metals, and these peaks were attributed to the characteristic peaks of carrier chitin [17,27]. The new appeared characteristic peak at about 2θ = 39.5° was attributed to Pt (111) (JCPDS no. 04-0802) [28]. However, the peak attributed to Ni species could not be detected by XRD, which may be due to the small size or uniform dispersion of Ni particles [29]. Further, in the amplification analysis of 2θ = 35–50° ranges, a new weak peak of ~ 42.57° appeared (Figure 2b), which may arise from the formation of Pt-Ni alloy [27,28]. Bahrami et al. also reported a Pt-Ni/rGO counter electrode, and found that the reflection from (111) in the crystal planes was corresponding to Pt-Ni, with approximately 2θ = 42.64° [28]. In the Fourier transform infrared (FT-IR) spectra, as shown in Figure 2c, the blank chitin possessed characteristic absorption peaks of 3430 cm−1 attributed to -OH, 1670 or 1580 cm−1 attributed to amide, and 1070 cm−1 attributed to -C-O-C, etc. [17]. After the introduction of nano-metals, these chitin-supported catalysts likewise all contained above characteristic peaks with little change, further indicating the good stability of chitin [19].
To further demonstrate the chemical state of the Pt-Ni/Chitin catalyst, X-ray photoelectron spectroscopy (XPS) was conducted, and it could be seen that these Pt-Ni/Chitin catalysts contained C, O, N, Pt, and Ni elements (Figure 2d), further suggesting the successful introduction of Pt and Ni species. Moreover, in the Pt 4f of Pt-Ni/Chitin catalyst (Herein, taking catalyst of Pt-Ni/Chitin, Pt:Ni = 3:1 [mol%] as an example), the Pt 4f spectra in Figure 2g could mainly split into Pt 4f7/2 and Pt 4f5/2. The two peaks with binding energy (BE) of 71.89 and 74.81 eV were attributed to Pt0, and the BE of 72.77 and 75.88 eV were attributed to Pt2+. It was also noteworthy that there was a weak peak at 75.32 eV presumably attributed to Pt-N/O-Ni or Pt-Ni [25,26,27,28,29,30], which further proved the formation of Pt-Ni alloy. Pires et al. also reported a Pt-Ni bimetallic catalyst, and found that the Pt hydroxide and Pt oxide peaks were attributed to Pt-O-C or Pt-O-Ni bonds in the Pt 4f spectra, which suggested the Pt-C and Pt-Ni bonds and the formation of Pt-Ni alloy [30]. Similarly, in the Ni 2p spectra, the characteristic peaks in Pt-Ni/Chitin corresponding to Ni0 (853.37 eV, 870.27 eV) and Ni2+ (857.53 eV, 874.20 eV) were also be found (Figure 2h) [11,27]. The interaction between chitin and nano-metals was also investigated by the binding energy of XPS spectrum; here the catalyst of Pt-Ni/Chitin (Pt:Ni = 3:1 [mol%]) was still used as an example, and the spectrum had been calibrated with a C 1s of 284.80 eV. As shown in Figure 2e, the peak of N 1s spectra in blank chitin shifted from 399.74 to 399.85 eV after the loading of Pt-Ni NPs. In addition, in the O 1s spectra, the two peaks at 532.43 (O-C) and 530.94 eV (O=C) also shifted to higher values after the addition of Pt-Ni NPs (Figure 2f). In contrast, the C 1s spectra of the Pt-Ni/Chitin had almost no shift relative to that of blank chitin (Figure S1). Overall, the binding energy of N 1s and O 1s in Pt-Ni/Chitin moved toward a higher binding energy compared to that of blank chitin, which indicated that there was an interaction between N/O and nano-metals [19,25,27].
Further, nitrogen adsorption and desorption measurement of the chitin microspheres indicated that the isotherms were type IV with an H3 hysteresis loop (Figure S2), and the Brunauer-Emmett-Teller (BET) surface area of the chitin microspheres was calculated as 253 m2g−1. Meanwhile, the Barret-Joyner-Halenda (BJH) theory pore-size distribution data (inset in Figure S2) revealed that the pores presented in chitin microspheres were mainly mesoporous [17]. Scanning electron microscopy (SEM) images in Figure 3a–c revealed that the chitin microspheres were woven by nanofibrous with nanoporous structure [31]. We believed that the large specific surface area and rich pore structure were favorable for the adhesion of nano-metals and the exchange of reactive substances. After loading the nano-metals, the nanofibrous morphology of chitin microspheres was well maintained (Figure S3) [4], indicating that the nano-metal loading did not affect the structure of the chitin microspheres. Energy dispersive X-ray spectroscopy (EDX) mapping analysis of Pt-Ni/Chitin in Figure 3(d1–d5) showed that the Pt-Ni NPs were uniformly dispersed throughout the chitin microspheres relative to the framework C/O/N elements [27,29,32].
To determine the morphology of the Pt-Ni NPs immobilized on chitin, transmission electron microscopy (TEM) was conducted, which further the proved the porous structure of chitin microspheres and revealed that the Pt-Ni NPs (catalyst of Pt-Ni/Chitin, Pt:Ni = 3:1 [mol%]) were uniformly distributed on the surface of the support without obvious aggregation (Figure 3e–g), and the average particle size of Pt-Ni NPs was about 2.1 nm (inset in Figure 3e). Moreover, high resolution TEM (HR-TEM) images in Figure 3g and Figure S4 showed that in a typical dark spot (i.e., nano-metal particle), clear lattices attributed to the Pt (111) (d = 0.223 nm) and Ni (111) (d = 0.203 nm) phases were observed [26,33,34], further suggesting the formation of Pt-Ni NPs, which was consistent with the results of XRD and XPS. Duan et al. reported am Ag-Fe bimetallic catalyst and used it for degradation of 4-nitrophenol. In a typical dark spot of nano-metal particle, they found the characteristic lattice spacing of Ag (111) (d = 0.235 nm), Ag (200) (d = 0.203 nm) and Fe (311) (d = 0.251 nm), Fe (511) (d = 0.162 nm), respectively, indicating the formation of Ag-Fe alloy [33]. Similarly, Zhang, et al. synthesized a PtNix/CNTs catalyst, and proved the Pt-Ni alloy by characteristic lattice spacing of Pt (111) (d = 0.223 nm) and NiO (d = 0.241 nm) in a typical dark spot of nano-metal particle [29]. Evidently, a highly dispersed Pt-Ni bimetallic catalyst supported on chitin was successfully fabricated.

3.3. Selective Hydrogenation of NO2 to NH2 for the Pt-Ni/Chitin Catalyst

It is also very important to convert nitroalkenes into aminoalkene compounds, and the aminoalkene compounds are of great significance in the synthesis of pharmaceutical intermediates, pesticides, natural products, etc. [6,8]. Further, we also attempted the Pt-Ni/Chitin catalyst for selective hydrogenation of NO2 to NH2 with the model substrate of 4-nitrostyrene. It was striking that the Pt-Ni/Chitin catalyst could selectively hydrogenate only NO2 to NH2, i.e., 4-nitrostyrene to 4-aminostyrene, when the hydrogen source was changed to NaBH4 (Table 2). In screening the solvents, toluene:H2O = 1:1 was determined to be the optimal solvent for the reaction, which could reach 99% yield of 4-aminostyrene (Table 2, entries 1–9), and the calculated TOF and TON were 660 h−1 and 1980, respectively (entry 9). When screening the effect of temperature on the reaction, it was found that the product yield increased with increasing the temperature and peaked at 60 °C, and the lower yield of the target product at high temperature may be due to the occurrence of side reactions caused by high temperature (Table 2, entries 9–13). Commercial Pt/C, commercial nano-Pt and un-supported H2PtCl6▪6H2O catalysts were also used as controls, as shown in Table S3. The commercial Pt/C and nano-Pt catalysts showed lower target product yields compared to the Pt-Ni/Chitin catalyst. Although the in situ reduced Pt in this system by using un-supported H2PtCl6▪6H2O could give target product yield of 57% (Table S3, entry 3), it could not be reused for lack of carrier. Furthermore, the optimal ratio of Pt to Ni in chitin for the selective hydrogenation only NO2 to NH2 were also evaluated. As shown in Table S4 (entries 1–3), the Pt-Ni/Chitin with Pt:Ni ratio of 3:1 (mol%) could also give the best yield. Notably, the Pt-Ni/Chitin catalyst was active for the selective hydrogenation of NO2 or C=C group by adjusting the reaction condition. The proposed mechanism for selective hydrogenation of NO2 to NH2 is shown in Figure S6, as the interaction between the center of the Pt-Ni/Chitin catalyst and H. The activated hydrogen consequently interacted with the nitro compounds to generate the hydroxylamine intermediate. Following the removal of water, the aniline product and the Pt-Ni/Chitin would be released to complete the catalytic cycle.
For supported catalysts, the cycle stability was also an important indicator. Here, we performed multiple reaction cycles on the Pt-Ni/Chitin catalyst with the model reaction of 4-nitrostyrene to 4-aminostyrene, and it could be seen that the catalyst showed good stability in five consecutive cycle reactions (Figure 4). The yield of the target product could still maintain 93% after 5 runs, indicating that the catalyst we obtained had excellent reusability. TEM image in Figure S7 for the five reused Pt-Ni/Chitin catalysts showed that the Pt-Ni NPs were slightly agglomerated, but there was no obvious aggregation. Inductive coupled plasma emission spectrometer (ICP) results revealed that the Pt to Ni loading in Pt-Ni/Chitin changed little from the initial 1.21, 0.39 wt% to 1.12, 0.36 wt% after five runs, respectively (Table S5), suggesting that very little nano-metal was lost to the reaction solution. Evidently, the Pt-Ni/Chitin bimetallic catalyst had good activity, selectivity, and stability on the hydrogenation of NO2 or C=C. The good catalytic performance of the Pt-Ni/Chitin bimetallic catalyst may be due to the following reasons: (1) The porous chitin microspheres woven by nanofibrous could provide abundant adhesion sites for nano-metals, as well the exchange of reactive substances. (2) The rich functional groups of -OH, NH2, etc. in chitin microspheres could interact with nano-metals to anchor them tightly, thus enhancing the stability of the catalyst. (3) The tiny and highly dispersed nano-metal particles could expose more active sites to improve the reactivity. (4) The formed bimetallic catalyst with synergistic effect of bimetals facilitated the selective hydrogenation of the catalyst.

4. Conclusions

In summary, for the first time, a highly dispersed Pt-Ni bimetallic catalyst anchored on porous nanofibrous chitin microspheres was successfully constructed, confirmed by diverse physicochemical characterizations. As the carrier, the chitin microspheres possessed abundant functional groups of hydroxyl and acetamide, as well large surface area, which promoted the high dispersion of Pt-Ni NPs. Importantly, the formed Pt-Ni bimetallic catalyst with synergistic effect of bimetals could significantly improve the performance of the catalyst. The Pt-Ni/Chitin catalyst was used for selective hydrogenation of 4-nitrostyrene, which showed good catalytic activity, selectivity, and cycling stability by adjusting the reaction conditions. This research enriches the application of chitin-based materials by using residual biomass resource chitin as the catalyst carrier, as well as promotes the development of green and sustainable chemistry.

Supplementary Materials

The following supporting information can be downloaded at: https://0-www-mdpi-com.brum.beds.ac.uk/article/10.3390/nano12172968/s1, Figure S1: XPS spectra of C 1s for pure chitin, Pt/Chitin and Pt-Ni/Chitin; Figure S2: Nitrogen adsorption & desorption isotherms and BJH pore-size distribution of the chitin microspheres; Figure S3: SEM image of the Pt-Ni/Chitin catalyst; Figure S4: HR-TEM images of an individual Pt-Ni alloy particle; Figure S5: The probable mechanism for the selective hydrogenation of C=C to C-C for 4-nitrostyrene; Figure S6: The probable mechanism for the selective hydrogenation of NO2 to NH2 for 4-nitrostyrene; Figure S7: TEM image of the Pt-Ni/Chitin after 5 runs, inset (f) with the particle size istribution; Table S1: Hydrogenation of 4-nitroethylene in various reaction conditions; Table S2: Some common non-precious metal catalysts; Table S3: Some commercial catalysts for hydrogenation of 4-nitrostyrene; Table S4: Effect of different ratios of Pt-Ni on the hydrogenation of 4-nitrostyrene; Table S5: The nano-metal content in Pt-Ni/Chitin (3:1) catalyst.

Author Contributions

Conceptualization, X.P., W.G. and A.L.; methodology, S.L. and X.P.; software, S.L.; validation, S.L., L.Z. and Z.L.; formal analysis, S.L. and H.J.; investigation, S.L. and H.J.; resources, X.P. and W.G.; data curation, S.L. and H.J.; writing—original draft preparation, S.L. and X.P.; writing—review and editing, S.L. and X.P.; visualization, L.Z.; supervision, Z.L.; project administration, S.L. and H.J.; funding acquisition, X.P., W.G. and A.L. All authors have read and agreed to the published version of the manuscript.

Funding

This work was supported by the Guizhou Provincial Science and Technology Foundation (No. [2020] 1Y212), the Science and Technology Top Talent Project of Guizhou Province (No. [2021] 029), the National Natural Science Foundation of China (No. 52063008), the Guizhou Province Science and Technology Plan Project (No. ZK [2021] Key 050), the Guizhou Province Young Scientific and Technological Talents Growth Project (No. [2022] 172), the Guizhou Key Laboratory of Inorganic Nonmetallic Functional Materials (No. [2022] 012), the Hundred Talents Project of Guizhou Province (No. [2016] 5673), and the Graduate Education Innovation Project of Guizhou Province (No. [2020] 099).

Institutional Review Board Statement

Not applicable.

Informed Consent Statement

Not applicable.

Data Availability Statement

Data will be available upon request from the corresponding authors.

Conflicts of Interest

The authors declare that they have no known competing financial interests or personal relationships that could have appeared to influence the work reported in this paper.

References

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Nanomaterials 12 02968 g001 550
Figure 1. Schematic diagram of the formation process for the chitin supported nano-metal catalyst: The chitin resource (a). The chitin solution (b). The chitin emulsion (c). The chitin microspheres (d). The chitin microspheres supported nano-metals (e).
Figure 1. Schematic diagram of the formation process for the chitin supported nano-metal catalyst: The chitin resource (a). The chitin solution (b). The chitin emulsion (c). The chitin microspheres (d). The chitin microspheres supported nano-metals (e).
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Figure 2. XRD patterns of the chitin supported catalysts (a). A partial enlargement of XRD patterns (b). FT-IR spectra of the chitin supported catalysts (c). The full scale XPS spectra of the Pt-Ni bimetallic catalysts (d). XPS spectra of N 1s (e), O 1s (f) of the pure chitin, Pt/Chitin, and Pt-Ni/Chitin. Pt 4f spectrum of the Pt-Ni/Chitin (g). Ni 2p spectrum of the Pt-Ni/Chitin (h).
Figure 2. XRD patterns of the chitin supported catalysts (a). A partial enlargement of XRD patterns (b). FT-IR spectra of the chitin supported catalysts (c). The full scale XPS spectra of the Pt-Ni bimetallic catalysts (d). XPS spectra of N 1s (e), O 1s (f) of the pure chitin, Pt/Chitin, and Pt-Ni/Chitin. Pt 4f spectrum of the Pt-Ni/Chitin (g). Ni 2p spectrum of the Pt-Ni/Chitin (h).
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Figure 3. SEM images of the chitin microspheres (ac). EDX mapping of the Pt-Ni/Chitin (d1d5). TEM images of the Pt-Ni/Chitin (eg), inset (f) with the particle size distribution, inset (g) with the HR-TEM image of a single Pt-Ni particle.
Figure 3. SEM images of the chitin microspheres (ac). EDX mapping of the Pt-Ni/Chitin (d1d5). TEM images of the Pt-Ni/Chitin (eg), inset (f) with the particle size distribution, inset (g) with the HR-TEM image of a single Pt-Ni particle.
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Figure 4. The reusability of the Pt-Ni/Chitin catalyst for selective hydrogenation of 4-nitrostyrene to 4-aminostyrene.
Figure 4. The reusability of the Pt-Ni/Chitin catalyst for selective hydrogenation of 4-nitrostyrene to 4-aminostyrene.
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Table
Table 1. Selective hydrogenation of C=C to C-C for 4-nitrostyrene a.
Table 1. Selective hydrogenation of C=C to C-C for 4-nitrostyrene a.
Nanomaterials 12 02968 i001
EntryCatalyst Time
(h)		Yield b
(%)		Yield c
(%)
1Pt/Chitin2487Trace
2Pd/Chitin1923
3Pd/Chitin44653
4Chitin36--
5Pt-Pd/Chitin299-
6Pt-Pd/Chitin104622
7Pt-Fe/Chitin387-
8Pt-Co/Chitin1082-
9Pt-Cu/Chitin1072-
10Pt-Ni/Chitin (3:1)399-
11Pt-Ni/Chitin (1:1)339-
12Pt-Ni/Chitin (1:3)359-
13Pt-Ni/Chitin (3:1)4899-
14Commercial Pt/C d2442Trace
15Commercial nano-Pt e245-
a Reaction conditions: 4-nitrostyrene (0.5 mmol), nano-metal catalyst (4 mg), isopropanol (IPA, 5 mL), H2 (1 bar) at room temperature. b,c b was the yield of 1b, c was the yield of 1c, and the yield was GC yield. d,e The [Pt] content in these catalyst was the same as Pt-Ni/Chitin (3:1).
Table
Table 2. Effect of solvent and temperature on the hydrogenation of 4-nitrostyrene a.
Table 2. Effect of solvent and temperature on the hydrogenation of 4-nitrostyrene a.
Nanomaterials 12 02968 i002
EntrySolventTemperature
(°C)		Time
(h)		Yield b (%)
1Toluene603Trace
2H2O60343
3MeOH60324
4THF603Trace
5DCM60313
6DMF60316
7IPA60334
8MeOH: H2O = 1:160337
9Toluene: H2O = 1:160399
10Toluene: H2O = 1:130328
11Toluene: H2O = 1:175389
12Toluene: H2O = 1:190382
13Toluene: H2O = 1:1120316
a Reaction conditions: 4-nitrostyrene (0.5 mmol), catalyst (4 mg), solvent (5 mL), NaBH4 (2 mmol). b The yield was GC yield.
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Long, S.; Zhang, L.; Liu, Z.; Jiao, H.; Lei, A.; Gong, W.; Pei, X. Fabrication of Biomass Derived Pt-Ni Bimetallic Catalyst and Its Selective Hydrogenation for 4-Nitrostyrene. Nanomaterials 2022, 12, 2968. https://0-doi-org.brum.beds.ac.uk/10.3390/nano12172968

AMA Style

Long S, Zhang L, Liu Z, Jiao H, Lei A, Gong W, Pei X. Fabrication of Biomass Derived Pt-Ni Bimetallic Catalyst and Its Selective Hydrogenation for 4-Nitrostyrene. Nanomaterials. 2022; 12(17):2968. https://0-doi-org.brum.beds.ac.uk/10.3390/nano12172968

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Long, Siyu, Lingyu Zhang, Zhuoyue Liu, Huibin Jiao, Aiwen Lei, Wei Gong, and Xianglin Pei. 2022. "Fabrication of Biomass Derived Pt-Ni Bimetallic Catalyst and Its Selective Hydrogenation for 4-Nitrostyrene" Nanomaterials 12, no. 17: 2968. https://0-doi-org.brum.beds.ac.uk/10.3390/nano12172968

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