SAR_Task22_Japan_Oct.. - Hydrogen Implementing Agreement
SAR_Task22_Japan_Oct.. - Hydrogen Implementing Agreement SAR_Task22_Japan_Oct.. - Hydrogen Implementing Agreement
• Development of nanocrystalline metal hydrides using vapour deposition technologies (D. Milcius, Lithuania) • Synthesis, structural characterization and stability of complex hydrides (B. C. Hauback, Norway) • Analysis of interface effects in light-weight metal hydride thin films using hydrogenography (B. Dam, Netherlands) • Metastable lightweight hydrides (D. Noréus, Sweden) • Syntheses and characterization of hydrogen absorbing compounds based on magnesium, aluminium and 3d transition metals (Y. Andersson, Sweden) • Stability and reversibility of borohydrides for hydrogen storage (A. Züttel, Switzerland) • Hydrogen storage in borohydrides and light-metal hydrides (D. Book, UK) • Synthesis, structure, stability and simulation of novel complex hydrides (B. David, UK) • Tailoring reaction routes for metal and complex metal hydrides (Z. X. Guo, UK) • Neutron scattering and ab initio investigations of hydrogen storage materials (D. K. Ross, UK) • Porous materials IEA collaboration (G. Walker, UK) • Multicomponent hydride systems (G. Walker, UK) • High pressure ambient temperature hydrogen storage adsorption (C. Ahn, USA) • Controlled synthesis of metal hydride nanoclusters (M. Allendorf, USA) • Chemical hydrogen storage (T. Autrey, USA) • Structure and dynamics of hydrogen in physisorbent systems (C. Brown, USA) • Metal amidotrihydroborates (A. Burrell, USA) • Novel theoretical and experimental approaches for understanding and optimizing molecule-sorbent interactions in metal organic framework materials (Y. Chabal, USA) • Amorphous alloy membranes prepared by melt-spin methods for long-term use in hydrogen separation applications (D. Chandra, USA) • Regeneration of kinetically stabilized hydrides (J. Graetz, USA) • International standardized practices and materials development for hydrogen storage (K. J. Gross, USA) • Novel borohydrides for hydrogen storage (C. M. Jensen, USA) • Hydrogen storage by novel CBN heterocycle materials (S.-Y. Liu, USA) • Neutron metrology of hydrogen in bulk and nanoconfined metal-hydride and complexhydride systems (T. Udovic, USA) • Exploration of lightweight borohydrides for hydrogen storage (J.-C. Zhao, USA) • Development and characterization of novel hydrogen storage materials (R. Zidan, USA) • Engineering/Applied hydrogen storage, project leader: D. Anton, USA. Subprojects: Definition of a materials acceptability envelope for metal hydrides to be used in hydrogen storage systems (D. Anton, USA); Hydrogen Storage Solutions for Stationary and Mobile Applications: From Materials to Systems (V. Yartys, Norway); From basic structure to system modelling (R. Chahine, Canada); Development of Combined Heat and Hydrogen Storage Systems Based on Low-Cost Metal Hydrides (Y.-W. Cho, Korea); Engineering progress in materials based H2 storage for light-duty vehicles (D. Mosher, USA); Off-Grid and Remote-Area Electricity Supply With Integrated Hydrogen Storage (E. Gray, Australia); Hydrogen Storage Systems Based On Complex Hydrides (M. Fichtner, Germany); Design and Testing of High Capacity 4
Alane and Chemical Hydride Based Hydrogen Storage Systems (C.M. Jensen, USA); Research, Development and Safety Assessment on Metal Hydride Tanks (S. Tsunokake, Japan); Adiabatic hydrogen storage system using changing phase materials (P. de Rango, France); Materials aspects in complex hydride based hydrogen storage tanks (J. Bellosta von Colbe, Germany) Activities during the previous six months Meeting number nine of Task 22 was held in Copenhagen, Denmark 4-8 September 2011. The program for the meeting is attached. A photo with the participants is shown in Fig. 1. Dr. Torben R. Jensen, Aarhus University, prof. Fleming Besenbacher, head of the iNANO center at Aarhus University, and other staff-members hosted the meeting in an excellent way. The meeting was partly in The Royal Danish Academy for Science and Letters and one day at the Carlsberg Academy (in the house where Niels Bohr lived for 31 years). There was in total 63 participants present at meeting, and thus it is the Task 22 meeting with most attendance so far. Table 2 below summarizes the Task 22 meetings. Table 2. Task 22 meetings. Location Dates No. of participants Monterey, California, USA 28.1-1.2. 2007 51 Egmond aan Zee, Netherlands 3-7.9. 2007 58 Hotel Sacocomie, Québec, Canada 2-5.3 2008 49 Villa Mondragone, Italy 7-10.10 2008 52 Jeju Island, Korea 19-23.4 2009 50 Paris, France 11-15.10 2009 59 Death Valley, USA 11-15.4 2010 56 Fremantle, Australia 16-20.1 2011 43 Copenhagen, Denmark 4-8.9 2011 63 Prof. Ping Chen from Dalian Institute of Chemical Physics, China and Prof. Isaac Jacob from Ben-Gurion University of the Negev, Israel participated in the meeting. It is a hope that they can contribute to participation from China and Israel in the IEA HIA. Major Accomplishments In the first morning session of the Task 22 meeting in Copenhagen the local hosts Dr. Torben R. Jensen and Prof. Fleming Besenbacher welcomed the Experts. This was followed by a presentation from DONG Energy, one of the major sponsors of the meeting, a presentation about hydrogen research activities in Denmark by Torben R. Jensen and the Task 22 introduction by the OA. Furthermore the invited observers, Isaac Jacob from Israel and Ping Chen from China presented new research results from their activities. In the following sessions 38 out of 48 projects were presented and discussed. As usual the meeting was organized in sessions addressing the different types of materials and each session was followed by a discussion led by a moderator. The sessions were: (i) (i) Methods; (ii) Nanoporous materials and “nano-hydrides”; (iii) Mg-based, composites, AlH 3 and chemical hydrides; (iv) Borohydrides; and (v) Engineering/Applied hydrogen storage. Every presentation showed new unpublished results and with a significant international collaboration in particular with other Task 22 Experts. To present new results 5
- Page 1 and 2: Summary IEA Hydrogen Implementation
- Page 3: USA D. Chandra Univ. of Nevada dcha
- Page 7 and 8: Fig. 1: Participants at the Task 22
- Page 9 and 10: LIMITED MEETING This meeting is lim
- Page 11: B.C. Hauback, Norway: Synthesis, st
• Development of nanocrystalline metal hydrides using vapour deposition technologies<br />
(D. Milcius, Lithuania)<br />
• Synthesis, structural characterization and stability of complex hydrides (B. C.<br />
Hauback, Norway)<br />
• Analysis of interface effects in light-weight metal hydride thin films using<br />
hydrogenography (B. Dam, Netherlands)<br />
• Metastable lightweight hydrides (D. Noréus, Sweden)<br />
• Syntheses and characterization of hydrogen absorbing compounds based on<br />
magnesium, aluminium and 3d transition metals (Y. Andersson, Sweden)<br />
• Stability and reversibility of borohydrides for hydrogen storage (A. Züttel,<br />
Switzerland)<br />
• <strong>Hydrogen</strong> storage in borohydrides and light-metal hydrides (D. Book, UK)<br />
• Synthesis, structure, stability and simulation of novel complex hydrides (B. David,<br />
UK)<br />
• Tailoring reaction routes for metal and complex metal hydrides (Z. X. Guo, UK)<br />
• Neutron scattering and ab initio investigations of hydrogen storage materials (D. K.<br />
Ross, UK)<br />
• Porous materials IEA collaboration (G. Walker, UK)<br />
• Multicomponent hydride systems (G. Walker, UK)<br />
• High pressure ambient temperature hydrogen storage adsorption (C. Ahn, USA)<br />
• Controlled synthesis of metal hydride nanoclusters (M. Allendorf, USA)<br />
• Chemical hydrogen storage (T. Autrey, USA)<br />
• Structure and dynamics of hydrogen in physisorbent systems (C. Brown, USA)<br />
• Metal amidotrihydroborates (A. Burrell, USA)<br />
• Novel theoretical and experimental approaches for understanding and optimizing<br />
molecule-sorbent interactions in metal organic framework materials (Y. Chabal, USA)<br />
• Amorphous alloy membranes prepared by melt-spin methods for long-term use in<br />
hydrogen separation applications (D. Chandra, USA)<br />
• Regeneration of kinetically stabilized hydrides (J. Graetz, USA)<br />
• International standardized practices and materials development for hydrogen storage<br />
(K. J. Gross, USA)<br />
• Novel borohydrides for hydrogen storage (C. M. Jensen, USA)<br />
• <strong>Hydrogen</strong> storage by novel CBN heterocycle materials (S.-Y. Liu, USA)<br />
• Neutron metrology of hydrogen in bulk and nanoconfined metal-hydride and complexhydride<br />
systems (T. Udovic, USA)<br />
• Exploration of lightweight borohydrides for hydrogen storage (J.-C. Zhao, USA)<br />
• Development and characterization of novel hydrogen storage materials (R. Zidan,<br />
USA)<br />
• Engineering/Applied hydrogen storage, project leader: D. Anton, USA. Subprojects:<br />
Definition of a materials acceptability envelope for metal hydrides to be used in<br />
hydrogen storage systems (D. Anton, USA); <strong>Hydrogen</strong> Storage Solutions for<br />
Stationary and Mobile Applications: From Materials to Systems (V. Yartys, Norway);<br />
From basic structure to system modelling (R. Chahine, Canada); Development of<br />
Combined Heat and <strong>Hydrogen</strong> Storage Systems Based on Low-Cost Metal Hydrides<br />
(Y.-W. Cho, Korea); Engineering progress in materials based H2 storage for light-duty<br />
vehicles (D. Mosher, USA); Off-Grid and Remote-Area Electricity Supply With<br />
Integrated <strong>Hydrogen</strong> Storage (E. Gray, Australia); <strong>Hydrogen</strong> Storage Systems Based<br />
On Complex Hydrides (M. Fichtner, Germany); Design and Testing of High Capacity<br />
4
Change language