Napoli : Ciolfi Editore, s. d.

28 p. : ill. ; 25 cm

626.7

DINED

08 CC 326

Italiano

Weinheim, : Wiley-VCH Verlag GmbH & Co., c2010

9786612549281

9783527629800

3527629807

9781282549289

1282549286

9783527629817

3527629815

1 online resource (375 p.)

540

ERG 770b

VE 9850

ZP 4150

HirscherMichael

665.81

665.81 22

Hydrogen - Storage - Materials

Energy storage

Inglese

Description based upon print version of record.

Includes bibliographical references and index.

Handbook of Hydrogen Storage: New Materials for Future Energy Storage; Foreword; Contents; Preface; List of Contributors; 1 Storage of Hydrogen in the Pure Form; 1.1 Introduction; 1.2 Thermodynamic State and Properties; 1.2.1 Variables of State; 1.2.2 T-s-Diagram; 1.2.2.1 Joule-Thomson Coefficient; 1.2.3 Properties; 1.3 Gaseous Storage; 1.3.1 Compression and Expansion; 1.3.2 Tank Systems; 1.3.3 High Pressure Infrastructure; 1.4 Liquid Storage; 1.4.1 Liquefaction; 1.4.2 Thermodynamic Analysis; 1.4.2.1 Pressure Build-Up; 1.4.2.2 Boil-Off; 1.4.2.3 Cooling and Filling; 1.4.2.4 Back-Gas

1.4.3 Tank Systems1.4.4 Distribution Facilities; 1.5 Hybrid Storage; 1.5.1 Supercritical Storage; 1.5.2 Hydrogen Slush; 1.6 Comparison of Energy Densities; 1.7 Conclusion; References; 2 Physisorption in Porous Materials; 2.1 Introduction; 2.2 Carbon Materials; 2.3 Organic Polymers; 2.4 Zeolites; 2.5 Coordination Polymers; 2.6 Conclusions; References; 3 Clathrate Hydrates; 3.1 Introduction; 3.2 Clathrate Hydrate Structures; 3.3 Hydrogen Clathrate Hydrate; 3.4 Kinetic Aspects of Hydrogen Clathrate Hydrate; 3.5 Modeling of Hydrogen Clathrate Hydrates; 3.6 Future of Hydrogen Storage; References

4 Metal Hydrides4.1 Introduction; 4.2 Elemental Hydrides; 4.2.1 Ionic or Saline Hydrides; 4.2.2 Covalent Hydrides; 4.2.3 Metallic Hydrides; 4.3 Thermodynamics of Metal Hydrides; 4.3.1 Introduction; 4.3.2 Low Concentration; 4.3.3 High Concentration; 4.4 Intermetallic Compounds; 4.4.1 Thermodynamics; 4.4.1.1 Miedema's Model; 4.4.1.2 Semi-Empirical Band Structure Model; 4.4.2 Crystal Structure; 4.4.3 Electronic Structure; 4.5 Practical Considerations; 4.5.1 Synthesis; 4.5.2 Activation; 4.5.3 Hysteresis; 4.5.4 Plateau Slope; 4.5.5 Reversible Capacity; 4.5.6 Hydrogenation Kinetics

4.5.7 Cycle Life4.5.8 Decrepitation; 4.6 Metal Hydrides Systems; 4.6.1 AB5; 4.6.2 TiFe; 4.6.3 AB2 Laves Phases; 4.6.4 BCC Solid Solution; 4.7 Nanocrystalline Mg and Mg-Based Alloys; 4.7.1 Hydrogen Sorption Kinetics; 4.7.2 Reduction of the Heat of Formation; 4.7.3 Severe Plastic Deformation Techniques; 4.8 Conclusion; 4.8.1 Alloys Development; 4.8.2 Synthesis; 4.8.3 System Engineering; References; 5 Complex Hydrides; 5.1 Introduction; 5.2 Complex Borohydrides; 5.2.1 Introduction; 5.2.2 Stability of Metal Borohydrides; 5.2.3 Decomposition of Complex Borohydrides

5.2.4 Lithium Borohydride, LiBH45.2.4.1 Synthesis and Crystal Structure; 5.2.4.2 Decomposition of LiBH4; 5.2.5 Sodium Borohydride, NaBH4; 5.2.5.1 Synthesis and Crystal Structure; 5.2.5.2 Decomposition of NaBH4; 5.2.6 Potassium Borohydride KBH4; 5.2.7 Beryllium Borohydride Be(BH4)2; 5.2.8 Magnesium Borohydride Mg(BH4)2; 5.2.8.1 Synthesis and Crystal Structure; 5.2.8.2 Decomposition; 5.2.9 Calcium Borohydride Ca(BH4)2; 5.2.9.1 Synthesis and Crystal Structure; 5.2.9.2 Decomposition; 5.2.10 Aluminum Borohydride Al(BH4)3; 5.2.10.1 Synthesis and Crystal Structure; 5.2.10.2 Decomposition

5.2.11 Zinc Borohydride Zn(BH4)2

Owing to the limited resources of fossil fuels, hydrogen is proposed as an alternative and environment-friendly energy carrier. However, its potential is limited by storage problems, especially for mobile applications. Current technologies, as compressed gas or liquefied hydrogen, comprise severe disadvantages and the storage of hydrogen

in lightweight solids could be the solution to this problem.Since the optimal storage mechanism and optimal material have yet to be identified, this first handbook on the topic provides an excellent overview of the most probable candidates, highlighting bo