Synthesis of multifunctional hybrid materials via layered double hydroxides mediated route
Hybrid materials in general could be classified into three categories : (i) mixed metal oxides (MMO), (ii) MMO with noble metal hybrid, and (iii) MMO with nanocarbon hybrid. Ln this research work, layered double hydroxides (LDH) mediated route is utilized to synthesize the three types of multifun...
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| Format: | Theses and Dissertations |
| Language: | English |
| Published: |
2017
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| Subjects: | |
| Online Access: | http://hdl.handle.net/10356/70602 |
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| Institution: | Nanyang Technological University |
| Language: | English |
| Summary: | Hybrid materials in general could be classified into three categories : (i) mixed
metal oxides (MMO), (ii) MMO with noble metal hybrid, and (iii) MMO with
nanocarbon hybrid. Ln this research work, layered double hydroxides (LDH)
mediated route is utilized to synthesize the three types of multifunctional hybrid
materials . Studies will focus on understanding how the LDH mediated route lead
to the intimately mixed morphology and strong interfacial interaction of the
hybrid materials . The impact of these features on the functional property
improvement is discussed thoroughly.
This research begins with a systematic investigation on the properties of ZnGaFe
ternary MMO prepared via LDH mediated route , and non-LDH route (solid state
reaction method) is used as a comparison. Detailed analysis reveals that the MMO
derived from LDH mediated approach not only has uniform and well mixed
morphology, but also possesses strong metal to metal interactions. All of these
characteristic properties are reflected in the study of photocatalytic reactions.
To synthesis MMO-noble metal hybrid material , the noble metal ion ([AuCI4D
intercalated ZnFe LDH is used as a solid state molecular precursor. Intimately
mixed ZnFe MMO with uniformly decorated Au nanoparticles is obtained after
low temperature calcination. In this work, the evolution of direct intercalated
LDH structure is discussed in details. The intra-layer merging mechanism is
proposed for the MMO growth during heat treatment. The morphology created is
intimately mixed as compared with that of MMO obtained from inter-layer
merging mechanism . The intimate interface could lead to favorable band
alignment and excellent synergistic interactions for photocatalytic reactions .
The LDH mediated route for synthesis of MMO-CNT hybrid material is also
attempted . NiFe LDH nano-plates were firstly deposited on CNT through
electrostatic force . With controlled calcination process , NiFe MMO and CNT
hybrid material is obtained. The nano sized NiFe MMO obtained from the LDH precursor is intimately mixed, which ensures the strong interaction between Ni
and Fe in MMO. More importantly, the hybrid is featured with a unique in-grown
structure which is formed due to the carbon reduction reaction during calcination.
Instead of coupling through organic ligand or electrostatic force, the in-grown
structure results to strong chemical bonding between MMO and CNT, The strong
coupling is very favorable for the charge transfer process, and hence significantly
improved the electrochemical property.
This thesis concludes the outcomes and findings from the three connected works.
Some extended works that could benefit from the concept of LDH mediated
synthesis route are proposed. |
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