Torino : G. Giappichelli, 2001c

88-348-0755-3

VII, 517 p. : ill. ; 24 cm

658.18

658-S/42

Italiano

Cambridge : , : Cambridge University Press, , 2013

1-139-88775-0

1-107-24080-8

1-107-25057-9

1-68015-988-7

1-107-24808-6

1-107-24974-0

0-511-97804-9

1-107-24725-X

1-107-24891-4

1 online resource (xii, 445 pages) : digital, PDF file(s)

621.36/6

Laser materials

Ceramic materials

Inglese

Title from publisher's bibliographic system (viewed on 05 Oct 2015).

Includes bibliographical references and index.

Machine generated contents note: 1.1. Research background -- 1.2. Technical problems of melt-growth single crystals -- 1.3. Technical problems of ceramics -- 1.4. Purpose of this research -- 1.5. Outline of the book -- References -- 2.1. Interaction of quantum systems with electromagnetic radiation (radiation absorption and emission processes in quantum systems) -- 2.2. Solid-state lasers -- 2.3. The flow of excitation inside the laser material -- 2.4. Laser emission processes -- 2.5. The spatial distribution of the de-excitation processes -- 2.6. Thermal field inside the pumped laser material and thermal effects -- 2.7. Performance scaling of solid-state lasers -- 2.8. The laser material -- References -- 3.1. Introduction -- 3.2. Microstructure and optical characteristics of Nd:YAG processed by HIP (hot isostatic pressing) -- References -- 4.1. Current status of single crystal technology -- 4.2. Requirements for sesquioxide ceramic lasers -- 4.3. Synthesis of optical grade sesquioxide ceramics -- 4.4. Optical quality and laser performance -- References -- 5.1. Production of heavily doped Nd:YAG and lasing characteristics -- 5.2. Effect of impurity (Si) on Nd solid-melt in YAG ceramics -- References -- 6.1. Introduction -- 6.2. Experimental procedure -- 6.3. Results -- 6.4. Discussion -- 6.5. Summary -- References -- 7.1.Composite technology -- 7.2. Ceramic fiber laser -- 7.3. Single crystal ceramics produced by sintering -- 7.4. Summary -- References -- 8.1. Garnet system materials -- 8.2. Perovskite system materials -- 8.3. Non-oxide system (II-VI compound) materials -- 8.4. Fluoride system materials -- 8.5. Applications in the fields of biotechnology and medical technology -- 8.6. High intensity lasers for engine ignition -- 8.7. Investigation of solid-state lasers as solar pump lasers -- References -- References -- 10.1. Structural characterization of doped ceramics by optical spectroscopy -- 10.2. The quantum states of the doping ions -- 10.3. Radiative and non-radiative de-excitation processes -- 10.4. Distribution of the doping ions in ceramics -- 10.5. Conversion of excitation in doped ceramics -- 10.6. Conclusions from high resolution optical spectroscopy of laser ceramics -- References -- 11.1. Pumping schemes -- 11.2. Radiative and non-radiative processes in ceramics -- 11.3. Ceramic laser materials and components -- 11.4. Ceramic lasers -- 11.5. Concluding remarks: the state of the art and directions of development of ceramic lasers -- References.

Until recently, ceramic materials were considered unsuitable for optics due to the numerous scattering sources, such as grain boundaries and residual pores. However, in the 1990s the technology to generate a coherent beam from ceramic materials was developed, and a highly efficient laser oscillation was realized. In the future, the technology derived from the development of the ceramic laser could be used to develop new functional passive and active optics. Co-authored by one of the pioneers of this field, the book describes the fabrication technology and theoretical characterization of ceramic material properties. It describes novel types of solid lasers and other optics using ceramic materials to demonstrate the application of ceramic gain media in the generation of coherent beams and light amplification. This is an invaluable guide for physicists, materials scientists and engineers working on laser ceramics.

Tübingen, : Tübingen University Press, 2020

1 electronic resource (320 p.)

RessourcenKulturen ; 09

Middle & Near Eastern archaeology

Inglese

The end of the Late Bronze Age ca. 1200 BC in the Eastern Mediterranean is traditionally viewed as an end point. Great empires collapsed, prominent cities were destroyed, interregional exchange disappeared, and writing systems were all but lost in most of the Eastern Mediterranean. The goal of this volume is to examine one key aspect of the transition from the Late Bronze Age to the Iron I in the Southern Levant, the development and changes in interregional exchange both over time and regionally. Twelve non-local types of material culture were collected into a database in order to track the development of interregional exchange over the course of the LBA to the Iron I. With this data, this volume explores what affect, if any, did changes in interregional exchange have on the ‘collapse’ of the LBA societies in the Southern Levant. Another key aspect of this work is an examination of the supposed wave of destruction which took the Southern Levant by storm to see if these events might have affected trade and contributed to the transitions during the end of the LBA into the Iron I. In all this work seeks to understand what changes took place in interregional exchange, how might destruction have affected this, and was this the cause for the transition to the Iron I.