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Article

Excellent Catalytic Performance of ISOBAM Stabilized Co/Fe Colloidal Catalysts toward KBH4 Hydrolysis

by
Keke Guan
1,†,
Qing Zhu
1,†,
Zhong Huang
1,*,
Zhenxia Huang
1,2,
Haijun Zhang
1,*,
Junkai Wang
1,2,
Quanli Jia
3 and
Shaowei Zhang
4
1
The State Key Laboratory of Refractories and Metallurgy, Wuhan University of Science and Technology, Wuhan 430081, China
2
School of Materials Science and Engineering, Henan Polytechnic University, Jiaozuo 454003, China
3
Henan Key Laboratory of High Temperature Functional Ceramics, Zhengzhou University, Zhengzhou 450052, China
4
College of Engineering, Mathematics and Physical Sciences, University of Exeter, Exeter EX4 4QF, UK
*
Authors to whom correspondence should be addressed.
These authors contributed equally to this work.
Nanomaterials 2022, 12(17), 2998; https://0-doi-org.brum.beds.ac.uk/10.3390/nano12172998
Submission received: 27 July 2022 / Revised: 26 August 2022 / Accepted: 26 August 2022 / Published: 30 August 2022
(This article belongs to the Special Issue Nanostructured Materials for Energy Applications)
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Abstract

:
Recently, developing a cost-effective and high-performance catalyst is regarded as an urgent priority for hydrogen generation technology. In this work, ISOBAM-104 stabilized Co/Fe colloidal catalysts were prepared via a co-reduction method and used for the hydrogen generation from KBH4 hydrolysis. The obtained ISOBAM-104 stabilized Co10Fe90 colloidal catalysts exhibit an outstanding catalytic activity of 37,900 mL-H2 min−1 g-Co−1, which is far higher than that of Fe or Co monometallic nanoparticles (MNPs). The apparent activation energy (Ea) of the as-prepared Co10Fe90 colloidal catalysts is only 14.6 ± 0.7 kJ mol−1, which is much lower than that of previous reported noble metal-based catalysts. The X-ray photoelectron spectroscopy results and density functional theory calculations demonstrate that the electron transfer between Fe and Co atoms is beneficial for the catalytic hydrolysis of KBH4.

1. Introduction

Recently, hydrogen has been widely considered as a promising clean energy source to replace the traditional fossil fuels. Chemical hydrogen storage materials have aroused tremendous interest because of their inherent advantages such as high content of hydrogen, no toxicity, low hydrogen releasing temperature, and an easily controllable hydrogen generation process [1,2,3,4,5,6,7,8]. Among those materials, potassium borohydride (KBH4) stands out owing to its safe production process, harmless hydrolysis product, low activation energy and enthalpy [9,10,11,12,13,14]. Unfortunately, the low hydrogen production rate of KBH4 self-hydrolysis hinders its large-scale practical application.
Many researchers found that metal nanoparticles (NPs) could catalyze the hydrolysis of KBH4 and accelerate the generation rate of hydrogen [7,15,16]. For example, Kilinc et al. [7] successfully prepared the Pd complex catalysts for promoting the KBH4 hydrolysis. The catalytic activity of the as-prepared catalysts was up to 37,900 mL-H2 min−1 g-catalyst−1. Recently, a series of colloidal metal catalysts were synthesized and used for catalyzing the hydrolysis of KBH4 [17,18,19,20]. For instance, Wang et al. [19] successfully synthesized colloidal Co single-atom catalysts for the effective production of hydrogen from KBH4 hydrolysis by using ISOBAM (isobutylene-alt maleic anhydride) as a protectant. The synthesized colloidal metal catalysts possess a clearly intrinsic catalytic activity of metal without the influence of support. Besides, those colloidal metal catalysts are stabilized by protective agents and present excellent catalytic activity and recyclability.
It has been widely accepted that the bimetallic catalysts exhibited a high catalytic activity for hydrogen production owing to the synergistic effects between different constituents [21,22,23,24,25]. In detail, the addition of another metal component could modify the electronic structure and then improve the catalytic activity [25,26]. For example, a previous report displayed that the Rh10Ni90 bimetallic nanoparticles (BNPs) possessed a higher catalytic activity for the KBH4 hydrolysis than that of Rh or Ni MNPs [27]. The catalytic activity of the reported Au/Ni BNPs was several times higher than their corresponding monometallic counterparts [28]. In addition, some non-noble metal catalysts (including Fe [29,30,31], Ni [18,32,33], Co [19,34], and Cu [35,36]) attract increasing attention owing to their considerable natural abundance, low cost, and competitive catalytic activity. However, the preparation of bimetallic catalysts with noble-free metal constituents is scarcely retrieved.
Herein, we reported a co-reduction method to prepare the ISOBAM-104 stabilized Co/Fe colloidal catalysts, which were then used for the hydrogen production from KBH4 hydrolysis. The effects of the molar ratio of ISOBAM-104 to metal ion, concentration of metal ion, and molar ratio of Co/Fe were investigated. The as-synthesized ISOBAM-104 stabilized Co10Fe90 colloidal catalysts possess an unexpected catalytic activity for hydrogen production from KBH4 hydrolysis at room temperature. The activation energy of the as-prepared Co10Fe90 colloidal catalysts towards KBH4 hydrolysis was calculated by the Arrhenius formula. In addition, the electronic property of metal atoms was investigated based on the DFT calculations.

2. Experimental Section

2.1. Materials

Potassium borohydride (KBH4), sodium hydroxide (NaOH), iron nitrate nonahydrate (Fe(NO3)3·9H2O) and cobalt nitrate hexahydrate (Co(NO3)2·6H2O) were purchased from Sinopharm Chemical Reagent Co., Ltd., Shanghai, China. ISOBAM-104 (NO. 52032-17-4, Figure S1) was purchased from Kuraray Co., Ltd., Tokya, Japan. The deionized water was produced via a PINGGUAN ultrapure water purification system (Wuhan, China).

2.2. Preparation of Co/Fe Colloidal Catalysts and Hydrogen Generation

Firstly, certain concentrations of Co(NO3)2·6H2O and Fe(NO3)3·9H2O solution were mixed together in a three-neck flask (Figure S2). Next, a certain amount of ISOBAM-104 was added into the flask and it was then filled with deionized water to 50 mL. After that, the mixed solution was continuously stirred for 24 h at room temperature. Subsequently, the configured KBH4 and NaOH solution were rapidly added into the above solution to obtain ISOBAM-104 protected Co/Fe BNPs.
The influence of the molar ratio of ISOBAM-104 to metal ion concentration (denoted as RISO, from 10 to 80), metal ion concentration (from 0.6 to 1.5 mM), and chemical composition (Fe, Co10Fe90, Co30Fe70, Co50Fe50, Co70Fe30, Co90Fe10, and Co) were investigated. The detailed batch compositions are shown in the Table S1. The volume of generated H2 was measured by an electronic balance, which was automatically recorded based on the displacement level of water every two seconds. During this process, the generated gas was passed through a trap containing concentrated H2SO4 to remove H2O and any NH3 that might have been generated. The rate of hydrogen generation (k, mL-H2·min−1) could be obtained from the slope of H2 volume–time curve in the initial stage of the reaction.
The catalytic activity (mL-H2·min−1·g-cat−1) could be calculated by the ratio of the hydrogen generation rate (k) to the mass of catalyst (m). It should be noted that the ISOBAM-104 used in this work contains the NH4+ group, which also possesses a catalytic effect for KBH4 hydrolysis [19,37]. Therefore, under the same condition, the catalytic activities of ISOBAM-104 stabilized Co/Fe colloidal catalysts and ISOBAM-104 (NH4+ group) were measured. The intrinsic catalytic activity value of Co/Fe colloidal catalysts were obtained by subtracting the value of ISOBAM-104 from that of ISOBAM-104 stabilized catalysts. All the catalytic experiments were repeated no less than three times under the identical condition. The average values, which were normalized to mL-H2 min−1 g-Co−1, were used to determine the catalytic activity (detailed calculation procedures are provided in the supporting information).

2.3. Material Characterization

UV-vis absorption spectra were recorded at 200–800 nm by a Shimadzu UV-2550 spectrophotometer (Shimadzu Company, Kobe, Japan). Transmission electron microscopy (TEM) and high-resolution transmission electron microscopy (HRTEM) images were collected by using a JEM-2100F (JEOL Company, Tokyo, Japan). The average size of the nanoparticles in each sample was estimated by measuring at least 200 particles from different parts of the grid. Fourier transform infrared (FTIR) spectra were obtained on a FTIR spectrometer (VERTEX 70, Bruker Corporation, Karlsruhe, Germany), and the samples were embedded in KBr pellet. X-ray photoelectron spectroscopy (XPS) measurements were performed on a VG MultiLab 2000 instrument (Thermo Electron Corporation, Massachusetts, USA) equipped with a 300 W Al Kα excitation source. The obtained XPS spectra were calibrated using a reference energy of 284.6 eV for the C 1s level and analyzed by Avantage software.

2.4. Density Functional Theory (DFT) Calculation

The spin-polarized density functional theory (DFT) calculations were carried out using a generalized gradient approximation (GGA) with Perdew–Burke–Ernzerhof (PBE) exchange-correlation functional [38], as implemented in the DMol3 package (BIOVIA Company, San Diego, CA, USA) [39]. The double numerical basis set and polarization functions (DNP) were carried out to describe the valence electrons, and an electron relativistic core treatment was used to perform full optimization of the investigated cluster model of Co6Fe49 BNP without symmetry constraint. The convergence criteria were set to medium quality with a tolerance for the self-consistent field (SCF), optimization energy, maximum force, and maximum displacement of 10−5 Ha, 2 × 10−5 Ha, 0.004 Ha/Å and 0.005 Å, respectively. The charge analysis was performed on the basis of the Mulliken population distribution scheme [40,41].

3. Results and Discussion

3.1. Effect of RISO on the Activity of Co/Fe Colloidal Catalysts

To explore the optimized reaction condition, the effect of RISO on the preparation and catalytic activity of the Co/Fe BNPs was systematically investigated. The TEM images (Figure 1) and size distribution histograms (Figure S3) indicate that the average particle sizes of Co50Fe50 BNPs are about 4.6 nm (RISO = 10), 3.7 nm (RISO = 30), 3.2 nm (RISO = 50), and 2.3 nm (RISO = 80), respectively. Obviously, the average particle size decreases with the increase of RISO value, which may be ascribed to the fact that the increase of the protective agents could provide a large number of −COO and −NH2 groups to prevent the agglomeration of particles. Figure 2 displays the catalytic activities of the obtained Co50Fe50 colloidal catalysts for hydrogen production at different RISO. It can be clearly observed that the Co50Fe50 colloidal catalysts with RISO = 50 possess a higher catalytic value (17,500 mL-H2 min−1 g-Co−1) than those synthesized at RISO = 10, 30, and 80 (6800, 6600, and 5500 mL-H2 min−1 g-Co−1, respectively). This result may be attributed to the fact that Co50Fe50 nanoparticles cannot receive effective protection at low RISO and are prone to agglomeration, leading to a low catalytic activity. Comparatively, when RISO was superfluous, the surface of the nanoparticles would be covered by ISOBAM-104, resulting in the decrease of active sites and catalytic activity [28]. Thus, based on the above results, the Co50Fe50 catalysts with moderate particle size and high catalytic activity could be synthesized when RISO = 50.

3.2. Effect of Metal Ion Concentration on the Activity of Co/Fe Colloidal Catalysts

The effect of ion concentration on the preparation and catalytic activity of Co50Fe50 colloidal catalysts was also investigated. TEM morphologies and size distribution histograms of the as-prepared Co50Fe50 BNPs are presented in Figure 3 and Figure S4. The average particle sizes are about 2.3, 3.2, 2.6, and 3.4 nm at the metal ion concentrations of 0.6, 0.9, 1.2, and 1.5 mM, respectively. It is found that the metal ion concentration exerts a significant influence on the particle size of the obtained catalysts. Although the Co50Fe50 BNPs with the smaller particle sizes are obtained at the metal ion concentrations of 0.6 mM, the low concentration of metal ion impedes the large-scale preparation of catalysts. Hence, the concentration of metal ion is set as 1.2 mM in the following discussion.

3.3. Effect of Chemical Composition on the Activity of Co/Fe Colloidal Catalysts

The UV-vis spectra of the obtained Co/Fe BNPs with various compositions are shown in Figure S5. It was found that no surface plasma resonance peak of Fe or Co nanoparticles could be detected, which agrees with the previous reports [26,27,42]. The spectra of the dispersed Co/Fe nanoparticles BNPs with a featureless absorbance were located between the spectra of single Co and Fe nanoparticles, exhibiting a featureless absorbance. These obvious differences of the absorbance at various Fe content suggest the formation of alloy-structured Co/Fe BNPs. Figure 4 presents the TEM images of the obtained Co/Fe BNPs at various Co/Fe atomic ratios. It can be clearly seen that the particles possessed a sphere-like morphology. The average sizes of ISOBAM-104 stabilized Fe, Co10Fe90, Co30Fe70, Co50Fe50, Co70Fe30, Co90Fe10, and Co colloidal catalysts are respectively about 3.0, 3.2, 2.6, 2.6, 2.2, 2.5, and 1.8 nm (Figure S6). The corresponding catalytic activities of the above colloidal catalysts are displayed in Figure 5. By comparison, the above-mentioned Co/Fe BNPs presented a superior catalytic activity than that of Co or Fe MNPs. More importantly, the catalytic activity of the Co10Fe90 colloidal catalysts reaches up to 37,900 mL-H2 min−1 g-Co−1, which is about 5 and 4 times higher than that of Fe (7400 mL-H2 min−1 g-Fe−1) and Co (9600 mL-H2 min−1 g-Co−1), respectively. Base on the above results, the desirable Co/Fe colloidal catalysts with high catalytic performance can be synthesized at the chemical composition of Co10Fe90, RISO = 50, and ion concentrations of 1.2 mM.
The structure of the obtained Co10Fe90 colloidal catalysts was further characterized by the high-resolution transmission electron microscope (HRTEM). As shown in Figure 6, the interplanar spacings of the four individual randomly-chosen Co/Fe BNPs are measured as 0.168, 0.172, 0.174, and 0.169 nm, respectively. These values are inconsistent with the theoretical interplanar spacing values of Co and Fe (Table S2). However, it is worth noting that this measured interplanar spacing located between the interplanar distance of Co (200) and Fe (200) (Table S3), suggests the alloy structure of the formed Co/Fe BNPs.
In order to understand the protecting role of ISOBAM-104 in the catalysts stabilization, the FTIR spectra of ISOBAM-104 stabilized Co/Fe catalysts, ISOBAM-104, Co(NO3)2, and Fe(NO3)3 are displayed in Figure S7. The absorption peak at 1400, 1680, 2300, and 3400 cm−1, respectively, correspond to the stretching vibration of –OH, –COOH, –CO2, and the –NH2 group of ISOBAM-104. By comparison, it can be clearly seen that the –COOH group of ISOBAM-104 disappeared, while the –OH and –NH2 group still appeared in the ISOBAM-104 stabilized Co/Fe catalysts, demonstrating that the –NH2 group in ISOBAM-104 should play a protective role on the as-prepared metal catalyst [18].

3.4. Kinetic Study and Catalytic Mechanism of Co/Fe Colloidal Catalysts

To calculate the apparent activation energy (Ea), the catalytic performance of Co10Fe90 colloidal catalysts were evaluated under the perturbation of the reaction temperature. As shown in Figure S8, it can be seen that the catalytic activity of the Co10Fe90 colloidal catalysts increases from 8400 to 15,200 mL-H2 min−1 g-catalyst−1 as the temperature increases from 293 to 308 K. The Ea is calculated by using the Arrhenius method [43]. As shown in Figure 7, the slope of the linear curve between the natural logarithm of catalytic activity and the reciprocal of temperature is −Ea/R, where R is the universal gas constant. The calculated Ea of Co10Fe90 colloidal catalysts is 14.6 ± 0.7 kJ mol−1, which is much lower than most of the reported metal-based catalysts (Table 1). Interestingly, the corresponding catalytic activity of the Co10Fe90 colloidal catalysts is much higher than these metal-based catalysts. Thus, it can be confirmed that the excellent catalytic activity of Co10Fe90 colloidal catalysts is closely related to the lower activation energy towards KBH4 hydrolysis.
An XPS measurement was subsequently carried out to clarify the elemental composition and valence state of the Co10Fe90 BNPs. In Figure S9a, the element of Co, Fe, O, N, C, and B are detected in the obtained Co/Fe colloidal catalysts. The high-resolution XPS spectra of Co 2p (Figure S9b) shows that the electron binding energy of Co0 2p3/2 (776.0 eV) is about 2.3 eV lower than that of the bulk Co (778.3 eV), indicating a negatively-charged characteristic of Co atoms in Co10Fe90 BNPs. Meanwhile, the electron binding energy of Fe0 2p3/2 (708.5 eV) was about 1.8 eV higher than that of the bulk Fe (706.7 eV), suggesting that the Fe atoms were positively charged (Figure S9c). The negative shift of the Co0 2p3/2 binding energy and positive shift of the Fe0 2p3/2 binding energy might be ascribed to the electron charge transfer occurring between Fe and Co atoms [23,24,26,50,51]. To further confirm the electron transfer effect, DFT calculations were employed to investigate the electronic states of each atom in the Co6Fe49 alloy nanoparticles [52]. As shown in Figure 8a, the Co atoms are negatively charged (−0.091 eV), while the Fe atoms are positively charged (0.029 or 0.021 eV), which is matched well with the above XPS result. Based on above discussions and the related literature [23,27], a plausible mechanism for the high catalytic performance of Co/Fe colloidal catalysts could be proposed. Due to the charge transfer between Fe atoms and Co atoms (Figure 8b), the negatively charged Co atoms are conducive to the fracture of H−O bonds in H2O molecules, and the positively charged Fe atoms could promote the B−H bond breaking in KBH4 molecules. As a result, the catalytic activity of Co/Fe colloidal catalysts for KBH4 hydrolysis could be markedly enhanced under the synergistic effect of Fe and Co atoms.

4. Conclusions

In summary, the ISOBAM-104 stabilized Co/Fe colloidal catalysts are successfully synthesized for hydrogen generation by a simple co-reduction method via using ISOBAM-104 as a protective agent, and Co(NO3)2·6H2O, Fe(NO3)3·9H2O, and KBH4 as starting materials. The catalytic activities of the obtained Co/Fe colloidal catalysts could reach up to 37,900 mL-H2 min−1 g-Co−1 at the chemical composition of Co10Fe90, RISO = 50, and ion concentrations of 1.2 mM, which is superior to their corresponding monometallic nanoparticles. The excellent catalytic activity of Co10Fe90 colloidal catalysts is mainly attributed to their lower activation energy towards KBH4 hydrolysis, and the charge transfer effect between Fe and Co atoms. This finding could provide a deeper insight for developing the economic, highly active, and recyclable bimetallic catalysts.

Supplementary Materials

The following supporting information can be downloaded at: https://0-www-mdpi-com.brum.beds.ac.uk/article/10.3390/nano12172998/s1, Figure S1: The chemical structure of ISOBAM-104; Figure S2: The schematic diagram of experimental device for KBH4 hydrolysis reaction; Figure S3: Particles size distribution histograms of Co50Fe50 colloidal catalysts with various RISO ([Co2+ + Fe3+] = 0.9 mM; RISO = 10 (a), 30 (b), 50 (c), and 80 (d)); Figure S4: Particles size distribution histograms of Co50Fe50 colloidal catalysts synthesized with various ion concentrations (RISO = 50; [Co2+ + Fe3+] = 0.6 (a), 0.9 (b), 1.2 (c), and 1.5 (d) mM); Figure S5: UV–vis spectra of Co/Fe BNPs, Co and Fe nanoparticles; Figure S6: Particles size distribution histograms of Co/Fe colloidal catalysts synthesized with various chemical compositions (RISO = 50, [Co2+ + Fe3+] = 1.2 mM); Figure S7: FTIR spectra of ISOBAM-104, Co(NO3)2, Fe(NO3)3, and Co10Fe90 colloidal catalysts; Figure S8: Effect of temperature on the catalytic performance of Co10Fe90 colloidal catalysts; Figure S9: XPS spectra of Co30/Fe70 colloidal catalysts: (a) total spectra, (b) Co 2p, and (c) Fe 2p; Table S1: Batch compositions and processing conditions for the preparation of ISOBAM-104 stabilized Co/Fe colloidal catalysts; Table S2: Lattice spacing and indexed reflection planes of Co and Fe; Table S3: Lattice spacing and indexed reflection planes of Co/Fe colloidal catalysts determined by HRTEM.

Author Contributions

K.G.: investigation, formal analysis, and writing—original draft preparation; Q.Z.: investigation and writing—original draft preparation; Z.H. (Zhong Huang): supervision, writing—review and editing; Z.H. (Zhenxia Huang): methodology and investigation. H.Z.: methodology, writing—review and editing, project administration and funding acquisition; J.W.: investigation and software. Q.J.: project administration; S.Z.: project administration and funding acquisition. All authors have read and agreed to the published version of the manuscript.

Funding

This research was funded by National Natural Science Foundation of China (Grant No. 52072274, 51872210, and 52102017), Program of Hubei Province, China (Contract No. 2017CFA004 and T201602).

Institutional Review Board Statement

Not applicable.

Informed Consent Statement

Not applicable.

Acknowledgments

This work was financially supported by National Natural Science Foundation of China, Program of Hubei Province, China.

Conflicts of Interest

The authors declare no conflict of interest.

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Nanomaterials 12 02998 g001 550
Figure 1. TEM images of Co50Fe50 colloidal catalysts with various RISO ([Co2+ + Fe3+] = 0.9 mM; RISO = 10 (a), 30 (b), 50 (c), and 80 (d)). (Dav: average particle size; S: standard deviation).
Figure 1. TEM images of Co50Fe50 colloidal catalysts with various RISO ([Co2+ + Fe3+] = 0.9 mM; RISO = 10 (a), 30 (b), 50 (c), and 80 (d)). (Dav: average particle size; S: standard deviation).
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Figure 2. Comparison of catalytic activity of Co50Fe50 colloidal catalysts with varied RISO ([Co2+ + Fe3+] = 0.9 mM).
Figure 2. Comparison of catalytic activity of Co50Fe50 colloidal catalysts with varied RISO ([Co2+ + Fe3+] = 0.9 mM).
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Nanomaterials 12 02998 g003 550
Figure 3. TEM images and size distribution histograms of Co50Fe50 colloidal catalysts synthesized with different ion concentrations ([Co2+ + Fe3+] = 0.6 (a), 0.9 (b), 1.2 (c), and 1.5 (d) mM). (Dav: average particle size; S: standard deviation).
Figure 3. TEM images and size distribution histograms of Co50Fe50 colloidal catalysts synthesized with different ion concentrations ([Co2+ + Fe3+] = 0.6 (a), 0.9 (b), 1.2 (c), and 1.5 (d) mM). (Dav: average particle size; S: standard deviation).
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Nanomaterials 12 02998 g004 550
Figure 4. TEM images of Co/Fe colloidal catalysts synthesized with various chemical compositions (RISO = 50, [Co2+ + Fe3+] = 1.2 mM). (Dav: average particle size; S: standard deviation).
Figure 4. TEM images of Co/Fe colloidal catalysts synthesized with various chemical compositions (RISO = 50, [Co2+ + Fe3+] = 1.2 mM). (Dav: average particle size; S: standard deviation).
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Figure 5. Comparison of catalytic activity of Co/Fe colloidal catalysts with various chemical compositions (RISO = 50, [Co2+ + Fe3+] = 1.2 mM).
Figure 5. Comparison of catalytic activity of Co/Fe colloidal catalysts with various chemical compositions (RISO = 50, [Co2+ + Fe3+] = 1.2 mM).
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Nanomaterials 12 02998 g006 550
Figure 6. HRTEM images (ad) of Co10Fe90 colloidal catalysts (RISO = 50, [Co2+ + Fe3+] = 1.2 mM). (HRTEM images of a–d correspond to four individual randomly-chosen Co/Fe bimetallic nanoparticles.).
Figure 6. HRTEM images (ad) of Co10Fe90 colloidal catalysts (RISO = 50, [Co2+ + Fe3+] = 1.2 mM). (HRTEM images of a–d correspond to four individual randomly-chosen Co/Fe bimetallic nanoparticles.).
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Figure 7. The apparent activation energy (Ea) of Co10Fe90 colloidal catalysts for KBH4 hydrolysis at 293−308 K.
Figure 7. The apparent activation energy (Ea) of Co10Fe90 colloidal catalysts for KBH4 hydrolysis at 293−308 K.
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Nanomaterials 12 02998 g008 550
Figure 8. Catalytic mechanism. (a) DFT calculations of the electronic structure of Co6Fe49 nanoparticles (red, Fe; and blue, Co). (b) Schematic illustration of the possible electron charge transfer effects between Co and Fe atoms in the Co6Fe49 nanoparticles.
Figure 8. Catalytic mechanism. (a) DFT calculations of the electronic structure of Co6Fe49 nanoparticles (red, Fe; and blue, Co). (b) Schematic illustration of the possible electron charge transfer effects between Co and Fe atoms in the Co6Fe49 nanoparticles.
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Table
Table 1. Comparison of the apparent activation energy between the Co10Fe90 colloidal catalysts and other catalysts in the previously reported literature.
Table 1. Comparison of the apparent activation energy between the Co10Fe90 colloidal catalysts and other catalysts in the previously reported literature.
CatalystReactantActivation Energy (kJ mol−1)Catalytic Activity
(mL-H2 min−1 g-cat.−1)		Reference
Co/FeKBH414.637,900Present work
NiKBH441.312,400[18]
Rh/NiKBH447.211,580[27]
Co-O-PNaBH4634850[44]
Ag/NiNaBH416.22333[45]
Co-Ni-PNaBH431.26681[46]
Co-BNaBH437.572649[47]
Co-BNaBH4305310[48]
CoO−Co2PNaBH427.43940[49]
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Guan, K.; Zhu, Q.; Huang, Z.; Huang, Z.; Zhang, H.; Wang, J.; Jia, Q.; Zhang, S. Excellent Catalytic Performance of ISOBAM Stabilized Co/Fe Colloidal Catalysts toward KBH4 Hydrolysis. Nanomaterials 2022, 12, 2998. https://0-doi-org.brum.beds.ac.uk/10.3390/nano12172998

AMA Style

Guan K, Zhu Q, Huang Z, Huang Z, Zhang H, Wang J, Jia Q, Zhang S. Excellent Catalytic Performance of ISOBAM Stabilized Co/Fe Colloidal Catalysts toward KBH4 Hydrolysis. Nanomaterials. 2022; 12(17):2998. https://0-doi-org.brum.beds.ac.uk/10.3390/nano12172998

Chicago/Turabian Style

Guan, Keke, Qing Zhu, Zhong Huang, Zhenxia Huang, Haijun Zhang, Junkai Wang, Quanli Jia, and Shaowei Zhang. 2022. "Excellent Catalytic Performance of ISOBAM Stabilized Co/Fe Colloidal Catalysts toward KBH4 Hydrolysis" Nanomaterials 12, no. 17: 2998. https://0-doi-org.brum.beds.ac.uk/10.3390/nano12172998

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