Nano-confined magnesium for hydrogen storage from reactive milling with anthracite carbon as milling aid
The structure and properties of magnesium nanoparticles for hydrogen storage from reactive milling under hydrogen atmosphere with the carbon from anthracite coal carbonization as milling aid were investigated. Experiment showed that after 3 h of milling under 1 MPa of hydrogen with 30 wt.% of carbon...
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| Published in | International journal of hydrogen energy Vol. 39; no. 25; pp. 13628 - 13633 |
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| Main Authors | , , , , , , , , |
| Format | Journal Article Conference Proceeding |
| Language | English |
| Published |
Kidlington
Elsevier Ltd
22.08.2014
Elsevier |
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| Abstract | The structure and properties of magnesium nanoparticles for hydrogen storage from reactive milling under hydrogen atmosphere with the carbon from anthracite coal carbonization as milling aid were investigated. Experiment showed that after 3 h of milling under 1 MPa of hydrogen with 30 wt.% of carbon additive, the magnesium particles were milled to 20–60 nm and hydrided into β-MgH2 with a crystallite size of 29.7 nm. For the hydrogen desorption of the material, the onset temperature was determined to be 270 °C. In 270–390 °C, the enthalpy and entropy changes were calculated to be 44.5 kJ/mol and 83.8 J/(mol K), respectively, and the activation energy as pseudo first-order reaction was 127.1 kJ/mol. The carbon still played a role of nano-confinement for magnesium to prevent particles from coalescing in the process of repeatedly heating for hydrogen storage.
•Carbon from anthracite coal is an effective milling aid to prepare Mg nanoparticles.•Carbon plays a role of nano-confinement to Mg during heating for H2 sorption.•With extension of milling time, more β phase of MgH2 can convert into γ phase.•Crystal defects and γ phase of MgH2 results in decrease of thermodynamic stability.•Particle size and crystal defects of MgH2 influence H2 sorption kinetics. |
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| AbstractList | The structure and properties of magnesium nanoparticles for hydrogen storage from reactive milling under hydrogen atmosphere with the carbon from anthracite coal carbonization as milling aid were investigated. Experiment showed that after 3 h of milling under 1 MPa of hydrogen with 30 wt.% of carbon additive, the magnesium particles were milled to 20–60 nm and hydrided into β-MgH2 with a crystallite size of 29.7 nm. For the hydrogen desorption of the material, the onset temperature was determined to be 270 °C. In 270–390 °C, the enthalpy and entropy changes were calculated to be 44.5 kJ/mol and 83.8 J/(mol K), respectively, and the activation energy as pseudo first-order reaction was 127.1 kJ/mol. The carbon still played a role of nano-confinement for magnesium to prevent particles from coalescing in the process of repeatedly heating for hydrogen storage.
•Carbon from anthracite coal is an effective milling aid to prepare Mg nanoparticles.•Carbon plays a role of nano-confinement to Mg during heating for H2 sorption.•With extension of milling time, more β phase of MgH2 can convert into γ phase.•Crystal defects and γ phase of MgH2 results in decrease of thermodynamic stability.•Particle size and crystal defects of MgH2 influence H2 sorption kinetics. The structure and properties of magnesium nanoparticles for hydrogen storage from reactive milling under hydrogen atmosphere with the carbon from anthracite coal carbonization as milling aid were investigated. Experiment showed that after 3 h of milling under 1 MPa of hydrogen with 30 wt.% of carbon additive, the magnesium particles were milled to 20-60 nm and hydrided into beta -MgH sub(2) with a crystallite size of 29.7 nm. For the hydrogen desorption of the material, the onset temperature was determined to be 270 degree C. In 270-390 degree C, the enthalpy and entropy changes were calculated to be 44.5 kJ/mol and 83.8 J/(mol K), respectively, and the activation energy as pseudo first-order reaction was 127.1 kJ/mol. The carbon still played a role of nano-confinement for magnesium to prevent particles from coalescing in the process of repeatedly heating for hydrogen storage. |
| Author | Wang, Naifei Niu, Haili Li, Tao Chen, Haipeng Zhang, Xiaoli Liu, Di Yu, Hao Zhou, Shixue Zhang, Tonghuan |
| Author_xml | – sequence: 1 givenname: Shixue orcidid: 0000-0002-8153-3348 surname: Zhou fullname: Zhou, Shixue email: zhoushixue66@163.com – sequence: 2 givenname: Xiaoli surname: Zhang fullname: Zhang, Xiaoli – sequence: 3 givenname: Tao surname: Li fullname: Li, Tao – sequence: 4 givenname: Naifei surname: Wang fullname: Wang, Naifei – sequence: 5 givenname: Haipeng surname: Chen fullname: Chen, Haipeng – sequence: 6 givenname: Tonghuan surname: Zhang fullname: Zhang, Tonghuan – sequence: 7 givenname: Hao surname: Yu fullname: Yu, Hao – sequence: 8 givenname: Haili surname: Niu fullname: Niu, Haili – sequence: 9 givenname: Di surname: Liu fullname: Liu, Di |
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| Keywords | Hydrogen storage Magnesium Reactive milling Nanoparticle Carbon Hydrogen |
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| SubjectTerms | Alternative fuels. Production and utilization Anthracite Applied sciences Carbon Coal Crystallites Energy Entropy Exact sciences and technology Fuels Hydrogen Hydrogen storage Magnesium Nanoparticle Nanostructure Reactive milling |
| Title | Nano-confined magnesium for hydrogen storage from reactive milling with anthracite carbon as milling aid |
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