Your search keyword '"Yang, Zhen-Ni"' showing total 4 results

1. Insights into palladium nanoparticles produced by Shewanella oneidensis MR-1: Roles of NADH dehydrogenases and hydrogenases.

Author

Yang, Zhen-Ni, Hou, Ya-Nan, Zhang, Bo, Cheng, Hao-Yi, Yong, Yang-Chun, Liu, Wen-Zong, Han, Jing-Long, Liu, Shuang-Jiang, and Wang, Ai-Jie

Subjects

*SHEWANELLA oneidensis, *DEHYDROGENASES, *PALLADIUM, *NANOPARTICLES, *NADH dehydrogenase, *METAL nanoparticles, *COFACTORS (Biochemistry)

Abstract

Biologically synthesized palladium nanoparticles (bio-Pd) have attracted considerable interest as promising green catalysts for environmental remediation. However, the mechanisms by which microorganisms produce bio-Pd remain unclear. In the present study, we investigated the roles of Shewanella oneidensis MR-1 and its NADH dehydrogenases and hydrogenases (HydA and HyaB) in bio-Pd production using formate as the electron donor. The roles of NADH dehydrogenases and hydrogenases were studied by inhibiting NADH dehydrogenases and using hydrogenase mutants (Δ hydA , Δ hyaB , and Δ hydA Δ hyaB), respectively. The results showed ~97% reduction of palladium by S. oneidensis MR-1 after 24 h using 250 μM palladium and 500 μM formate. Electron microscopy images showed the presence of bio-Pd on both the outer and cytoplasmic membranes of S. oneidensis MR-1. However, the inhibition of NADH dehydrogenases in S. oneidensis MR-1 resulted in only ~61% reduction of palladium after 24 h, and bio-Pd were not found on the outer membrane. The mutants lacking one or two hydrogenases removed 91–96% of palladium ions after 24 h and showed more cytoplasmic bio-Pd but less periplasmic bio-Pd. To the best of our knowledge, this is the first study to demonstrate the role of NADH dehydrogenases of S. oneidensis MR-1 in the formation of bio-Pd on the outer membrane. It also demonstrates that the hydrogenases (especially HyaB) of S. oneidensis MR-1 contribute to the formation of bio-Pd in the periplasmic space. This study provides mechanistic insights into the production of biogenic metal nanoparticles towards their possible use in industrial and environmental applications. • S. oneidensis MR-1 deposited bio-Pd on both the outer and cytoplasmic membranes. • The inhibition of NADH dehydrogenases in S. oneidensis MR-1 significantly slowed down the Pd(II) reduction. • The NADH dehydrogenases in S. oneidensis MR-1 participated in the formation of bio-Pd on the outer membrane. • The hydrogenase mutants of S. oneidensis MR-1 produced less periplasmic bio-Pd and more cytoplasmic bio-Pd. • The hydrogenases in S. oneidensis MR-1 promoted the formation of bio-Pd in the periplasmic space. [ABSTRACT FROM AUTHOR]

Published

2020

2. Insight into the electrocatalytic performance of in-situ fabricated electroactive biofilm-Pd: The role of biofilm thickness, initial Pd(II) concentration and the exposure time to Pd precursor.

Author

Hou, Ya-Nan, Ma, Jin-Feng, Yang, Zhen-Ni, Sun, Su-Yun, Wang, Ai-Jie, and Cheng, Hao-Yi

Abstract

Biogenic palladium (bio-Pd) nanoparticles have been considered as promising biocatalyst for energy generation and contaminants remediation in water and sediment. Recently, an electroactive biofilm-Pd (EAB-Pd) network, which can be used directly as electrocatalyst and show enhanced electrocatalytic performance, has exhibited tremendous application potential. However, the information regarding to the controllable biosynthetic process and corresponding catalytic properties is scarce. This study demonstrated that the catalytic performance of EAB-Pd could be influenced by Pd loading on bacteria cells (Pd/cells), which was crucial to determine the final distribution characteristic of Pd nanocrystal on EAB skeleton. For instance, the high Pd/cells (over 0.18 pg cell−1) exhibited almost 6-fold and 1.5-fold enhancement over EAB-Pds with Pd/cells below 0.03 in catalytic current toward hydrogen evolution reaction and nitrobenzene reduction, respectively. In addition, the Pd/cells was found to be affected by the synthesis factors, such as the ratio of biomass to initial Pd(II) concentration (cells/Pd II) and the exposure time of EAB to Pd(II) precursor solution. The Pd/cells increased significantly as the cell/Pd II ratio decreased from ~5.5 × 107 to ~1.3 × 107 cells L mg−1 or the prolongation of exposure time from 3 h to 24 h. The findings developed in this work extensively expand our knowledge for the in-situ designing biogenic electrocatalyst and provide important information for the development of its catalytic property. Unlabelled Image • Key parameters used to indicate the performance of EAB-Pd are proposed. • Optimum thickness of biofilm is essential to fabricate conductive Pd network. • The ratio of biomass to Pd(II) concentration affected the morphology of EAB-Pd. • The distribution of nano-Pd on EAB is crucial to determine the catalytic activity. [ABSTRACT FROM AUTHOR]

Published

2020

3. Shewanella oneidensis MR-1 self-assembled Pd-cells-rGO conductive composite for enhancing electrocatalysis.

Author

Hou, Ya-Nan, Sun, Su-Yun, Yang, Zhen-Ni, Yun, Hui, Zhu, Ting-ting, Ma, Jin-Feng, Han, Jing-Long, Wang, Ai-Jie, and Cheng, Hao-Yi

Subjects

*SHEWANELLA oneidensis, *ELECTRON transport, *METAL nanoparticles, *PRECIOUS metals, *CHARGE exchange, *ELECTROCATALYSIS

Abstract

Biosynthesized noble metal nanoparticles (NPs) as promising green catalysts for electrochemical application has invited a lot of attention. However, effective electron transfer between biosynthesized NPs and electrode remains a challenge due to the uncontrollable and poor conductive property of cell substrates. In this study, graphene oxide (GO) was introduced into a bio-Pd synthesis process governed by Shewanella oneidensis MR-1, which was demonstrated to be simultaneously reduced with Pd(II) and transformed to reduced GO (rGO), resulting in the formation of a Pd-cells-rGO composite. Compared to the control without rGO (Pd-cells), the electrochemical conductivity of Pd-cells-rGO composite increased from almost zero to 196 μS cm−1, indicating the rGO facilities the electron transport across the composite. Electrochemical characterizations revealed the electrochemical active surface area (ECSA) of Pd in Pd-cells-rGO was enlarged by increasing the amount of rGO in the composite, clearly indicating that the conductive network created by rGO enable the Pd NPs receive electrons from electrode and become electrochemical active. A considerable enhancement of electrocatalytic activity was further confirmed for Pd-cells-rGO as indicated by 36.7- and 17.2-fold increase (Pd-cells-rGO with Pd/GO ratio of 5/1 vs Pd-cells) of steady state current density toward hydrogen evolution and nitrobenzene reduction at −0.7 V and −0.55 V vs Ag/AgCl, respectively. We also compared the electrocatalytic performance with MWCNTs hybrids Pd-cells-CNTs. It was found that the association of Pd, cells and rGO creates an interactive and synergistic environment to allow higher conductivity and catalytic activity under the same amount of carbon nanomaterial. The strategy developed in this work activates a highly reactive NPs and proposed a designable protocol for enhancing electrocatalytic activity of biocatalysts. • MR-1 self-assembly of Pd-cells-rGO by one-step reduction of Pd(II) and GO • Hybrid rGO improves the stability of Pd NPs to against agglomeration • Pd-cells-rGO can be used as valid electrocatalyst for HER and NB reduction • Synergistic effect of Pd and rGO increases conductivity and quantity of active Pd [ABSTRACT FROM AUTHOR]

Published

2020

4. Palladized cells as suspension catalyst and electrochemical catalyst for reductively degrading aromatics contaminants: Roles of Pd size and distribution.

Author

Hou, Ya-Nan, Zhang, Bo, Yun, Hui, Yang, Zhen-Ni, Han, Jing-Long, Zhou, Jizhong, Wang, Ai-Jie, and Cheng, Hao-Yi

Subjects

*PALLADIUM catalysts, *POLLUTANTS, *BIOMASS, *CHLOROPHENOLS, *PARTICLE size distribution

Abstract

The palladized cell (Pd-cell) could be used as an efficient catalyst in catalyzing the degradations of a wide variety of environmental contaminants. Nevertheless, when the Pd NPs associate with the bacteria, the catalytic activity likely significantly affected by the biomass. Quantitative indicators that characterize of Pd-cell are necessary and little attention has been paid to investigate how the catalytic efficiency of Pd-cell is affected by the size and distribution of Pd NPs. To fill this gap, we explored the roles of the above-mentioned key factors on the performance of Pd-cell in catalyzing the degradations of two aromatic contaminants (nitrobenzene and p -chlorophenol) in two commonly used scenarios: (1) using Pd-cell as suspended catalyst in solution and (2) using Pd-cell as electrocatalyst directly coated on electrode. In scenario (1), the relationship of exposing area to Pd particle size and distribution factors was established. Based on theoretical estimation and catalytic performance analysis, the results indicated that adjusting the exposing area to a large value (9.3 ± 0.1 × 10 5 nm 2 mg −1 Pd) was extremely effective for improving the catalytic activity of Pd-cell used as a suspension catalyst. In scenario (2), our results showed that the best electrocatalytic performances were achieved on the electrode decorated with Pd-cells with the largest NP size (54.3 ± 16.4 nm), which exerted maximum electrochemical active surface area (10.6 m 2 g −1 ) as well as favorable conductivity. The coverage of deposited Pd NPs (>95%) on the cell surface played a crucial role in boosting the conductivity of biocatalyst, thus determining the possibility of Pd-cell as an efficient electrocatalyst. The findings of this study provide a guidance for the synthesis and application of Pd-cell, which enables the design of Pd-cell to be suitable for different catalysis systems with high catalytic performance. [ABSTRACT FROM AUTHOR]

Published

2017