β Scribed by Hoffmann F.
No coin nor oath required. For personal study only.
This book invites you on a tour through the most relevant topics of solid-state chemistry. It provides an up-to-date overview about fascinating structures of inorganic matter and new research developments. The reader will also gain crucial insights into many aspects of material science, from ceramics to superconductors. One chapter is specifically dedicated to the most rapidly evolving field of material science: metal-organic frameworks (MOFs). The book contains a chapter which is often neglected in others due to its complexity, the intermetallic phases. A concise but very didactic introduction to crystallographic specifications ensures that the reader will gain a deeper understanding of the crystal structures presented in the book.
The book places special emphasis on the graphical illustrations which were specifically designed to promote real insights into the structural features. Instead of having to decipher hard to distinguish graphics the reader has an eye-opening experience.
A further added value is that many references to the original research publications are given which enables easy follow-up for more detailed study.
Crystal structure and symmetry, space groups.
Metallic and Intermetallic Compounds, Ceramics.
Metal-organic frameworks.
Cover
Half Title
Also of interest
Solid-State Chemistry
Copyright
Preface
Contents
1. Introduction
2. Categorizing and description of crystal structures
2.1 Symmetry
2.2 Sphere (and rod) packings
2.3 Coordination polygons/polyhedra and the five Pauling rules
2.3.1 The five Pauling rules
2.3.2 Effective coordination numbers, linking coordination polyhedra, and Niggli notation
2.4 Prototypical compounds β structure types
2.5 Networks (nets)
3. Symmetry of crystals
3.1 The concept of the unit cell
3.1.1 The metric and the stoichiometry
3.1.2 Lattice points and motifs/bases
3.1.3 The seven crystal systems
3.2 The 14 Bravais lattices β centring of unit cells
3.3 Crystallographic point groups (crystal classes) β the morphology of crystals
3.3.1 Point symmetry elements
3.3.2 The 32 crystal classes
3.4 Further (micro-) translations β glide planes and screw axes
3.4.1 Glide planes
3.4.2 Screw axes
3.5 The 230 space groups
3.5.1 Nomenclature of space groups
3.5.2 Deriving point groups from space groups
3.5.3 International tables for crystallography
4. Densest sphere packings
4.1 The hexagonal closest packing
4.2 The cubic closest packing
4.3 Voids in the hcp and ccp packing
4.4 Locations of interstitial sites along the packing direction
4.5 Stacking variants/polytypes
5. Some important structure types
5.1 Metal structures β sphere packings in action
5.1.1 Cu (ccp or fcc) (Strukturbericht type A1)
5.1.2 Mg (hcp) (Strukturbericht type A3)
5.1.3 Lanthanoids and actinoids β stacking variants
5.1.4 W (bcc) (Strukturbericht type A2)
5.1.5 Ξ±-Polonium
5.1.6 Special metal structures
5.2 (Ionic) compounds based on densest sphere packings
5.3 Compounds based on a cubic closest packing
5.3.1 NaCl (Strukturbericht type B1)
5.3.2 CdCl2 (Strukturbericht type C19)
5.3.3 CrCl3, AlCl3, and RhBr3
5.3.4 CaF2 (Strukturbericht type C1)
5.3.5 MgAl2O4 (spinel) (Strukturbericht type H11)
5.3.6 CaTiO3 (perovskite, Strukturbericht type E21)
5.4 Compounds based on a hexagonal closest packing
5.4.1 NiAs (Strukturbericht type B8)
5.4.2 CdI2 (Strukturbericht type C6)
5.4.3 Ξ²-V2N (Strukturbericht type Lβ32)
5.4.4 CaCl2 (Strukturbericht type C35), TiO2 (rutile) (Strukturbericht type C4), and FeS2 (marcasite) (Strukturbericht type C18)
5.4.5 BiI3 (Strukturbericht type D05)
5.4.6 Ξ²-TiCl3 and MoBr3/ZrI3/RuBr3
5.4.7 Ξ±-Al2O3 (corundum, Strukturbericht type D51) and FeTiO3 (ilmenite, type E22)
5.4.8 ZnS (wurtzite) (Strukturbericht type B4)
5.4.9 Olivine (Mg,Mn,Fe)2SiO4 (Strukturbericht type S12)
5.5 Other important structure types not based on densest packings
5.5.1 CsCl (Strukturbericht type B2)
5.5.2 MoS2 (Strukturbericht type C7)
Further reading
6. Defects in solids
6.1 Point defects
6.1.1 Point defects in crystals of elements
6.1.2 Point defects in ionic compounds
6.1.3 KrΓΆger-Vink notation for point defects
6.1.4 Colour centres β a special kind of point defects
6.1.5 Swapping places β order-disorder phenomena and the relation between superstructures and sublattices
6.1.6 Non-stoichiometric compounds and defect clusters
6.1.7 Substitutional and interstitial solid solutions
6.2 Line defects β dislocations
6.2.1 Edge dislocations
6.2.2 Screw dislocations
6.2.3 Movement of dislocations β plastic deformation
6.2.4 Crystallographic shear planes
6.3 Planar defects
6.3.1 Stacking faults, turbostratification, and interstratification
6.3.2 Internal boundaries in single crystals β mosaicity
6.3.3 Grain boundaries
6.3.4 Twin boundaries
6.4 Volume defects
Conclusion and further reading
7. Phase diagrams
7.1 One-component systems
7.2 Two-component systems
7.2.1 Complete miscibility β solid solutions
7.2.2 Singly eutectic systems
7.2.3 Systems with compound formation that melt congruently
7.2.4 Systems with compound formation but incongruent melting
7.2.5 Systems with compound formation with an upper or lower limit of stability
Further reading
8. Electronic structure of solid-state compounds
8.1 Bloch functions, Blochβs theorem, the quantum number k, and crystal orbitals
8.2 Bandwidth, density of states, and the Fermi level
8.3 The Peierls distortion
8.4 Band structures in two- and three-dimensional systems
8.5 Examples of real band structures
8.5.1 ReO3 β a d1 compound with metallic properties
8.5.2 MoS2 β a d2 semiconductor with an indirect band gap
8.6 Direct and indirect band gaps
Further reading
9. Magnetic properties of solid-state compounds
9.1 Diamagnetism and paramagnetism
9.1.1 Quantifying the magnetic moments of paramagnetic substances
9.1.2 Pauli paramagnetism
9.2 Cooperative magnetic phenomena
9.2.1 Ferromagnetism
9.2.2 Antiferromagnetism and superexchange interactions
9.2.3 Ferrimagnetism and double exchange
9.3 Some magnetic materials
9.3.1 Cubic spinel ferrites
9.3.2 Garnets
9.3.3 Hexagonal ferrites β magnetoplumbites
Further reading
10. Phosphors, lamps, lasers, and LEDs
10.1 Phosphors
10.1.1 Fluorescent lamps
10.1.2 Phosphors for CRTs of TVs and computer screens
10.2 (Solid-state) lasers
10.2.1 Operation conditions
10.2.2 The ruby and the He-Ne laser
10.2.3 Classification of lasers
10.3 LEDs
Further reading
11. Superconductivity
11.1 From the metallic to the superconducting state
11.1.1 The Meissner-Ochsenfeld effect and type I and type II superconductors
11.1.2 The BCS theory
11.2 Superconducting materials
11.2.1 The elements
11.2.2 Binary compounds, alloys, and intermetallics
11.2.3 Oxo cuprates β the high-temperature superconducting revolution
11.2.4 Further superconducting compounds
Further reading
12. Ceramics
12.1 Definition and classification of ceramics and the ceramic method
12.2 (Alumo)silicate ceramics (traditional ceramics)
12.3 Binary oxide ceramics
12.3.1 Ξ±-Al2O3
12.3.2 ZrO2
12.3.3 TiO2, MgO, and BeO
12.4 Mixed oxide ceramics
12.4.1 Aluminium titanate
12.4.2 Barium titanate and lead zirconate titanate
12.5 Boride ceramics
12.6 Carbide ceramics
12.6.1 Boron carbide
12.6.2 Silicon carbide
12.7 Silicide ceramics
12.8 Nitride ceramics
12.8.1 Boron nitride
12.8.2 Aluminium nitride
12.8.3 Silicon nitride and SiALONs
12.8.4 Aluminium oxynitride
12.9 Glass-ceramics
Further reading
13. Intermetallic phases
13.1 Classification scheme
13.2 Ordered solid solutions β superstructures
13.2.1 Superstructures of the bcc packing
13.2.2 Superstructures derived from densest packings (ccp or hcp)
13.3 Hume-Rothery phases
13.3.1 The Ξ³-brass structure
13.4 Zintl phases
13.5 Packing-dominated phases (Frank-Kasper and Laves phases)
13.5.1 The geometrical principles in FK phases and the FK coordination polyhedra
13.5.2 Laves phases
13.5.3 Variants of Laves phases
13.5.4 Ο-, ΞΌ-, M, P, and R phases
13.5.5 The Cr3Si structure (Strukturbericht type A15)
14. Porous crystals, reticular chemistry, and the net approach
14.1 Zeolites and zeotypes
14.1.1 Structural chemistry and building units of zeolites
14.1.2 Technically important zeolites
14.2 Metal-organic frameworks
14.2.1 Carbon capture and sequestration
14.2.2 Hydrogen storage
14.2.3 Methane storage
14.2.4 Water harvesting from air
14.2.5 Other (potential) applications
14.3 Networks and topology
14.3.1 Graphs and nets
14.3.2 Turning crystal structures into their underlying nets
14.3.3 Topology and net descriptors
14.3.4 Characterizing and identifying nets
Further reading
Appendix A: Strukturbericht designations and Pearson symbols
References
Subject index
Formula index
π SIMILAR VOLUMES
Solid State Chemistry is a general textbook, composed for those with little background knowledge of the subject, but who wish to learn more about the various segments of solid state theory and technology. The information is presented in a form that can easily be understood and will be useful to read
Content: <br>Preface</span></a></h3>, <i>Page v</i><br>Chapter 1 - The Phase Chemistry of Solids</span></a></h3>, <i>Pages 1-29</i><br>Chapter 2 - Determining the Structure of Solids</span></a></h3>, <i>Pages 31-70</i><br>Chapter 3 - Defects in Solids</span></a></h3>, <i>Pages 71-127</i><br>Chapter
<p>This book invites you on a tour through the most relevant topics of solid-state chemistry. It provides an up-to-date overview about fascinating structures of inorganic matter and new research developments. The reader will also gain crucial insights into many aspects of material science, from cera