Hydrogen storage measurement, synthesis and characterization of metal-organic frameworks via bridged spillover

Cheng-Yu Wang; Cheng Si Tsao; Ming Sheng Yu; Pin Yen Liao; Tsui Yun Chung; Hsiu Chu Wu; Michael A. Miller; Yi Ren Tzeng

doi:10.1016/j.jallcom.2009.11.203

Hydrogen storage measurement, synthesis and characterization of metal-organic frameworks via bridged spillover

Cheng-Yu Wang, Cheng Si Tsao^*, Ming Sheng Yu, Pin Yen Liao, Tsui Yun Chung, Hsiu Chu Wu, Michael A. Miller, Yi Ren Tzeng

^*Corresponding author for this work

Department of Materials Science and Engineering

Research output: Contribution to journal › Article › peer-review

49 Scopus citations

Abstract

The present study established a time-saving technique for hydrogen uptake measurements using a high-pressure thermo-gravimetric analyzer (HPTGA). The critical buoyancy effects were considered in the analysis model. The HPTGA technique developed here for metal-organic frameworks (MOFs) was validated through independent experiments. The room temperature (RT) hydrogen uptake of MOFs via spillover was significantly enhanced by use of a bridge-building treatment. MOF samples with different structural parameters and RT hydrogen uptake performance can be prepared and manipulated through various factors affecting their synthesis. The structural evolution of MOFs within various steps during the synthesis and bridge-building processes were investigated by electron microscopy, nitrogen sorption isotherm analysis, and powder X-ray diffraction.

Original language	English
Pages (from-to)	88-94
Number of pages	7
Journal	Journal of Alloys and Compounds
Volume	492
Issue number	1-2
DOIs	https://doi.org/10.1016/j.jallcom.2009.11.203
State	Published - 4 Mar 2010

Keywords

Characterization
Hydrogen absorbing materials
Metal-organic framework
Nanostructured materials

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10.1016/j.jallcom.2009.11.203

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title = "Hydrogen storage measurement, synthesis and characterization of metal-organic frameworks via bridged spillover",

abstract = "The present study established a time-saving technique for hydrogen uptake measurements using a high-pressure thermo-gravimetric analyzer (HPTGA). The critical buoyancy effects were considered in the analysis model. The HPTGA technique developed here for metal-organic frameworks (MOFs) was validated through independent experiments. The room temperature (RT) hydrogen uptake of MOFs via spillover was significantly enhanced by use of a bridge-building treatment. MOF samples with different structural parameters and RT hydrogen uptake performance can be prepared and manipulated through various factors affecting their synthesis. The structural evolution of MOFs within various steps during the synthesis and bridge-building processes were investigated by electron microscopy, nitrogen sorption isotherm analysis, and powder X-ray diffraction.",

keywords = "Characterization, Hydrogen absorbing materials, Metal-organic framework, Nanostructured materials",

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T1 - Hydrogen storage measurement, synthesis and characterization of metal-organic frameworks via bridged spillover

AU - Wang, Cheng-Yu

AU - Tsao, Cheng Si

AU - Yu, Ming Sheng

AU - Liao, Pin Yen

AU - Chung, Tsui Yun

AU - Wu, Hsiu Chu

AU - Miller, Michael A.

AU - Tzeng, Yi Ren

PY - 2010/3/4

Y1 - 2010/3/4

N2 - The present study established a time-saving technique for hydrogen uptake measurements using a high-pressure thermo-gravimetric analyzer (HPTGA). The critical buoyancy effects were considered in the analysis model. The HPTGA technique developed here for metal-organic frameworks (MOFs) was validated through independent experiments. The room temperature (RT) hydrogen uptake of MOFs via spillover was significantly enhanced by use of a bridge-building treatment. MOF samples with different structural parameters and RT hydrogen uptake performance can be prepared and manipulated through various factors affecting their synthesis. The structural evolution of MOFs within various steps during the synthesis and bridge-building processes were investigated by electron microscopy, nitrogen sorption isotherm analysis, and powder X-ray diffraction.

AB - The present study established a time-saving technique for hydrogen uptake measurements using a high-pressure thermo-gravimetric analyzer (HPTGA). The critical buoyancy effects were considered in the analysis model. The HPTGA technique developed here for metal-organic frameworks (MOFs) was validated through independent experiments. The room temperature (RT) hydrogen uptake of MOFs via spillover was significantly enhanced by use of a bridge-building treatment. MOF samples with different structural parameters and RT hydrogen uptake performance can be prepared and manipulated through various factors affecting their synthesis. The structural evolution of MOFs within various steps during the synthesis and bridge-building processes were investigated by electron microscopy, nitrogen sorption isotherm analysis, and powder X-ray diffraction.

KW - Characterization

KW - Hydrogen absorbing materials

KW - Metal-organic framework

KW - Nanostructured materials

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VL - 492

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JO - Journal of Alloys and Compounds

JF - Journal of Alloys and Compounds

IS - 1-2

ER -

Hydrogen storage measurement, synthesis and characterization of metal-organic frameworks via bridged spillover

Abstract

Keywords

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