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200 10$aGrowing and Forming of Semiconductor Layers
205   $a1st ed.
210  1$aZurich :$cTrans Tech Publications, Limited,$d2024.
210  4$dİ2024.
215   $a1 online resource (107 pages)
225 1 $aSolid State Phenomena,$x1662-9779 ;$vVolume 362
311 08$a9783036406312 
311 08$a303640631X 
327   $aIntro -- Growing and Forming of Semiconductor Layers -- Preface -- Table of Contents -- Polarity Effect on the Heteroepitaxial Growth of BxC on 4H-SiC by CVD -- Vertical Current Transport in Monolayer MoS2 Heterojunctions with 4H-SiC Fabricated by Sulfurization of Ultra-Thin MoOx Films -- Estimation of Influence on Carbon Vacancy Regarding 4H-SiC Substrate Grown by HTCVD Method -- Resistivity as a Witness of Local Crystal Growth Conditions -- GaN Cap UV Spectroscopy Assessment in AlGaN/GaN HEMT -- SNDM Study of the MOS Interface State Densities on the 3C-SiC / 4H-SiC Stacked Structure -- Development of 200mm SiC Technology - Epitaxial Thickness Uniformity Observation on Different 8 Inch 4H-SiC Substrates -- 4H-SiC Crystal Growth Using Recycled SiC Powder Source -- High-Quality SiC Crystal Growth by Temperature Gradient Control at Initial Growth Stage -- The Role of Air-Pocket in Crucible Structure for High Quality SiC Crystal Growth -- Influence of the Size Distribution of the SiC Powder Source on the Shape of the Crystal Growth Interface during PVT Growth of 4H-SiC Boules -- Confirmation of the Growth Mechanism of the Buffer Layer in Epitaxial Graphene on SiC -- Suppressing the Memory Effect in Al Doped 3C-SiC Grown Using Chlorinated Chemistry -- Investigations into the Impact of Deposition or Growth Techniques on the Field Oxide TID Response for 4H-SiC Space Applications -- Characterization of Growth Sectors in Gallium Nitride Substrate Wafers -- Doping Efficiency and Long-Term Stability of Various SiC Epitaxial Reactors and Process Chemistries -- Keyword Index -- Author Index.
330   $aSpecial topic volume with invited peer-reviewed papers only.
410  0$aDiffusion and defect data$nPt. B,$pSolid state phenomena ;$vVolume 362
606   $aSilicon carbide$7Generated by AI
606   $aGallium nitride$7Generated by AI
615  0$aSilicon carbide
615  0$aGallium nitride
700   $aRiccio$b Michele$01822804
701   $aIrace$b Andrea$0515880
701   $aBreglio$b Giovanni$01822805
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200 10$aKinematic-wave rainfall-runoff formulas /$fTommy S.W. Wong
205   $a1st ed.
210   $aNew York $cNova Science Publishers$dc2009
215   $a1 online resource (266 p.)
225 1 $aHydrological science and engineering series
300   $aDescription based upon print version of record.
311 08$a1-60692-705-1 
320   $aIncludes bibliographical references and index.
327   $aIntro -- KINEMATIC-WAVERAINFALL-RUNOFF FORMULAS -- DEDICATED TO -- CONTENTS -- PREFACE -- ACKNOWLEDGEMENTS -- LIST OF SYMBOLS -- 1. INTRODUCTION -- 1.1. HOW TO USE THIS BOOK -- 2. GENERAL FORMULAS FOR FLOWON OVERLAND PLANE -- 2.1. FLOW CONDITIONS -- 2.2. DYNAMIC WAVE EQUATIONS -- 2.3. KINEMATIC WAVE EQUATIONS -- 2.4. FLOW DEPTH -- 2.5. FLOW VELOCITY -- 2.6. AVERAGE FLOW VELOCITY -- 2.7. KINEMATIC WAVE CELERITY -- 2.8. AVERAGE WAVE CELERITY -- 2.9. TIME OF CONCENTRATION -- 2.10. DESIGN DISCHARGE -- 2.10.1. Rainfall Intensity-Duration Relationship -- 2.10.2. Design Discharge -- 2.11. HYDROGRAPH - RISING PHASE -- 2.12. FORWARD CHARACTERISTIC - RISING PHASE -- 2.13. WATER SURFACE PROFILE - RISING PHASE -- 2.14. DURATION OF PARTIAL EQUILIBRIUM DISCHARGE -- 2.15. HYDROGRAPH - EQUILIBRIUM PHASE -- 2.15.1. Partial Equilibrium Discharge -- 2.15.2. Equilibrium Discharge -- 2.16. WATER SURFACE PROFILE - EQUILIBRIUM PHASE -- 2.17. EQUILIBRIUM DETENTION STORAGE -- 2.17.1. Water Surface Profile Approach -- 2.17.2. Hydrograph Approach -- 2.18. WATER SURFACE PROFILE - FALLING PHASE -- 2.18.1. Inflection Line -- 2.19. HYDROGRAPH - FALLING PHASE -- 3. WORKING FORMULAS FOR FLOWON OVERLAND PLANE -- 3.1. KINEMATIC WAVE PARAMETERS -- 3.2. FLOW DEPTH -- 3.3. FLOW VELOCITY -- 3.4. AVERAGE FLOW VELOCITY -- 3.5. KINEMATIC WAVE CELERITY -- 3.6. AVERAGE WAVE CELERITY -- 3.7. TIME OF CONCENTRATION -- 3.8. DESIGN DISCHARGE -- 3.9. HYDROGRAPH - RISING PHASE -- 3.10. FORWARD CHARACTERISTIC - RISING PHASE -- 3.11. WATER SURFACE PROFILE - RISING PHASE -- 3.12. DURATION OF PARTIAL EQUILIBRIUM DISCHARGE -- 3.13. HYDROGRAPH - EQUILIBRIUM PHASE -- 3.13.1. Partial Equilibrium Discharge -- 3.13.2. Equilibrium Discharge -- 3.14. WATER SURFACE PROFILE - EQUILIBRIUM PHASE -- 3.15. EQUILIBRIUM DETENTION STORAGE -- 3.16. WATER SURFACE PROFILE - FALLING PHASE.
327   $a3.17. HYDROGRAPH - FALLING PHASE -- 4. GENERAL FORMULAS FORFLOW IN OPEN CHANNEL -- 4.1. FLOW CONDITIONS -- 4.2. DYNAMIC WAVE EQUATIONS -- 4.3. KINEMATIC WAVE EQUATIONS -- 4.4. FLOW AREA -- 4.5. FLOW VELOCITY -- 4.6. AVERAGE FLOW VELOCITY -- 4.7. KINEMATIC WAVE CELERITY -- 4.8. AVERAGE WAVE CELERITY -- 4.9. TIME OF TRAVEL -- 4.10. HYDROGRAPH - RISING PHASE -- 4.11. FORWARD CHARACTERISTIC - RISING PHASE -- 4.12. FLOW AREA PROFILE - RISING PHASE -- 4.13. DURATION OF PARTIAL EQUILIBRIUM DISCHARGE -- 4.14. HYDROGRAPH - EQUILIBRIUM PHASE -- 4.14.1. Partial Equilibrium Discharge -- 4.14.2. Equilibrium Discharge -- 4.15. FLOW AREA PROFILE - EQUILIBRIUM PHASE -- 4.16. EQUILIBRIUM DETENTION STORAGE -- 4.16.1. Flow Area Profile Approach -- 4.16.2. Hydrograph Approach -- 4.17. FLOW AREA PROFILE - FALLING PHASE -- 4.17.1. Inflection Line -- 4.18. HYDROGRAPH - FALLING PHASE -- 5. WORKING FORMULAS FOR FLOWIN CIRCULAR CHANNEL -- 5.1. KINEMATIC WAVE PARAMETERS -- 5.2. FLOW DEPTH -- 5.3. FLOW VELOCITY -- 5.4. AVERAGE FLOW VELOCITY -- 5.5. KINEMATIC WAVE CELERITY -- 5.6. AVERAGE WAVE CELERITY -- 5.7. TIME OF TRAVEL -- 5.8. HYDROGRAPH - RISING PHASE -- 5.9. FORWARD CHARACTERISTIC - RISING PHASE -- 5.10. WATER SURFACE PROFILE - RISING PHASE -- 5.11. DURATION OF PARTIAL EQUILIBRIUM DISCHARGE -- 5.12. HYDROGRAPH - EQUILIBRIUM PHASE -- 5.12.1. Partial Equilibrium Discharge -- 5.12.2. Equilibrium Discharge -- 5.13. WATER SURFACE PROFILE - EQUILIBRIUM PHASE -- 5.14. EQUILIBRIUM DETENTION STORAGE -- 5.15. WATER SURFACE PROFILE - FALLING PHASE -- 5.16. HYDROGRAPH - FALLING PHASE -- 6. WORKING FORMULAS FOR FLOWIN PARABOLIC CHANNEL -- 6.1. KINEMATIC WAVE PARAMETERS -- 6.2. FLOW DEPTH -- 6.3. FLOW VELOCITY -- 6.4. AVERAGE FLOW VELOCITY -- 6.5. KINEMATIC WAVE CELERITY -- 6.6. AVERAGE WAVE CELERITY -- 6.7. TIME OF TRAVEL -- 6.8. HYDROGRAPH - RISING PHASE.
327   $a6.9. FORWARD CHARACTERISTIC - RISING PHASE -- 6.10. WATER SURFACE PROFILE - RISING PHASE -- 6.11. DURATION OF PARTIAL EQUILIBRIUM DISCHARGE -- 6.12. HYDROGRAPH - EQUILIBRIUM PHASE -- 6.12.1. Partial Equilibrium Discharge -- 6.12.2. Equilibrium Discharge -- 6.13. WATER SURFACE PROFILE - EQUILIBRIUM PHASE -- 6.14. EQUILIBRIUM DETENTION STORAGE -- 6.15. WATER SURFACE PROFILE - FALLING PHASE -- 6.16. HYDROGRAPH - FALLING PHASE -- 7. WORKING FORMULAS FOR FLOW INRECTANGULAR (DEEP) CHANNEL -- 7.1. KINEMATIC WAVE PARAMETERS -- 7.2. FLOW DEPTH -- 7.3. FLOW VELOCITY -- 7.4. AVERAGE FLOW VELOCITY -- 7.5. KINEMATIC WAVE CELERITY -- 7.6. AVERAGE WAVE CELERITY -- 7.7. TIME OF TRAVEL -- 7.8. HYDROGRAPH - RISING PHASE -- 7.9. FORWARD CHARACTERISTIC - RISING PHASE -- 7.10. WATER SURFACE PROFILE - RISING PHASE -- 7.11. DURATION OF PARTIAL EQUILIBRIUM DISCHARGE -- 7.12. HYDROGRAPH - EQUILIBRIUM PHASE -- 7.12.1. Partial Equilibrium Discharge -- 7.12.2. Equilibrium Discharge -- 7.13. WATER SURFACE PROFILE - EQUILIBRIUM PHASE -- 7.14. EQUILIBRIUM DETENTION STORAGE -- 7.15. WATER SURFACE PROFILE - FALLING PHASE -- 7.16. HYDROGRAPH - FALLING PHASE -- 8. WORKING FORMULAS FOR FLOW INRECTANGULAR (SQUARE) CHANNEL -- 8.1. KINEMATIC WAVE PARAMETERS -- 8.2. FLOW DEPTH -- 8.3. FLOW VELOCITY -- 8.4. AVERAGE FLOW VELOCITY -- 8.5. KINEMATIC WAVE CELERITY -- 8.6. AVERAGE WAVE CELERITY -- 8.7. TIME OF TRAVEL -- 8.8. HYDROGRAPH - RISING PHASE -- 8.9. FORWARD CHARACTERISTIC - RISING PHASE -- 8.10. WATER SURFACE PROFILE - RISING PHASE -- 8.11. DURATION OF PARTIAL EQUILIBRIUM DISCHARGE -- 8.12. HYDROGRAPH - EQUILIBRIUM PHASE -- 8.12.1. Partial Equilibrium Discharge -- 8.12.2. Equilibrium Discharge -- 8.13. WATER SURFACE PROFILE - EQUILIBRIUM PHASE -- 8.14. EQUILIBRIUM DETENTION STORAGE -- 8.15. WATER SURFACE PROFILE - FALLING PHASE -- 8.16. HYDROGRAPH - FALLING PHASE.
327   $a9. WORKING FORMULAS FOR FLOWIN RECTANGULAR (WIDE) CHANNEL -- 9.1. KINEMATIC WAVE PARAMETERS -- 9.2. FLOW DEPTH -- 9.3. FLOW VELOCITY -- 9.4. AVERAGE FLOW VELOCITY -- 9.5. KINEMATIC WAVE CELERITY -- 9.6. AVERAGE WAVE CELERITY -- 9.7. TIME OF TRAVEL -- 9.8. HYDROGRAPH - RISING PHASE -- 9.9. FORWARD CHARACTERISTIC - RISING PHASE -- 9.10. WATER SURFACE PROFILE - RISING PHASE -- 9.11. DURATION OF PARTIAL EQUILIBRIUM DISCHARGE -- 9.12. HYDROGRAPH - EQUILIBRIUM PHASE -- 9.12.1. Partial Equilibrium Discharge -- 9.12.2. Equilibrium Discharge -- 9.13. WATER SURFACE PROFILE - EQUILIBRIUM PHASE -- 9.14. EQUILIBRIUM DETENTION STORAGE -- 9.15. WATER SURFACE PROFILE - FALLING PHASE -- 9.16. HYDROGRAPH - FALLING PHASE -- 10. WORKING FORMULAS FOR FLOWIN TRAPEZOIDAL CHANNELWITH EQUAL SIDE SLOPES -- 10.1. KINEMATIC WAVE PARAMETERS -- 10.2. FLOW DEPTH -- 10.3. FLOW VELOCITY -- 10.4. AVERAGE FLOW VELOCITY -- 10.5. KINEMATIC WAVE CELERITY -- 10.6. AVERAGE WAVE CELERITY -- 10.7. TIME OF TRAVEL -- 10.8. HYDROGRAPH - RISING PHASE -- 10.9. FORWARD CHARACTERISTIC - RISING PHASE -- 10.10. WATER SURFACE PROFILE - RISING PHASE -- 10.11. DURATION OF PARTIAL EQUILIBRIUM DISCHARGE -- 10.12. HYDROGRAPH - EQUILIBRIUM PHASE -- 10.12.1. Partial Equilibrium Discharge -- 10.12.2. Equilibrium Discharge -- 10.13. WATER SURFACE PROFILE - EQUILIBRIUM PHASE -- 10.14. EQUILIBRIUM DETENTION STORAGE -- 10.15. WATER SURFACE PROFILE - FALLING PHASE -- 10.16. HYDROGRAPH - FALLING PHASE -- 11. WORKING FORMULAS FOR FLOWIN TRAPEZOIDAL CHANNELWITH ONE SIDE VERTICAL -- 11.1. KINEMATIC WAVE PARAMETERS -- 11.2. FLOW DEPTH -- 11.3. FLOW VELOCITY -- 11.4. AVERAGE FLOW VELOCITY -- 11.5. KINEMATIC WAVE CELERITY -- 11.6. AVERAGE WAVE CELERITY -- 11.7. TIME OF TRAVEL -- 11.8. HYDROGRAPH - RISING PHASE -- 11.9. FORWARD CHARACTERISTIC - RISING PHASE -- 11.10. WATER SURFACE PROFILE - RISING PHASE.
327   $a11.11. DURATION OF PARTIALEQUILIBRIUM DISCHARGE -- 11.12. HYDROGRAPH - EQUILIBRIUM PHASE -- 11.12.1. Partial Equilibrium Discharge -- 11.12.2. Equilibrium Discharge -- 11.13. WATER SURFACE PROFILE - EQUILIBRIUM PHASE -- 11.14. EQUILIBRIUM DETENTION STORAGE -- 11.15. WATER SURFACE PROFILE - FALLING PHASE -- 11.16. HYDROGRAPH - FALLING PHASE -- 12. WORKING FORMULAS FOR FLOWIN TRIANGULAR CHANNEL -- 12.1. KINEMATIC WAVE PARAMETERS -- 12.2. FLOW DEPTH -- 12.3. FLOW VELOCITY -- 12.4. AVERAGE FLOW VELOCITY -- 12.5. KINEMATIC WAVE CELERITY -- 12.6. AVERAGE WAVE CELERITY -- 12.7. TIME OF TRAVEL -- 12.8. HYDROGRAPH - RISING PHASE -- 12.9. FORWARD CHARACTERISTIC - RISING PHASE -- 12.10. WATER SURFACE PROFILE - RISING PHASE -- 12.11. DURATION OF PARTIALEQUILIBRIUM DISCHARGE -- 12.12. HYDROGRAPH - EQUILIBRIUM PHASE -- 12.12.1. Partial Equilibrium Discharge -- 12.12.2. Equilibrium Discharge -- 12.13. WATER SURFACE PROFILE - EQUILIBRIUM PHASE -- 12.14. EQUILIBRIUM DETENTION STORAGE -- 12.15. WATER SURFACE PROFILE - FALLING PHASE -- 12.16. HYDROGRAPH - FALLING PHASE -- 13. WORKING FORMULAS FOR FLOWIN VERTICAL CURB CHANNEL -- 13.1. KINEMATIC WAVE PARAMETERS -- 13.2. FLOW DEPTH -- 13.3. FLOW VELOCITY -- 13.4. AVERAGE FLOW VELOCITY -- 13.5. KINEMATIC WAVE CELERITY -- 13.6. AVERAGE WAVE CELERITY -- 13.7. TIME OF TRAVEL -- 13.8. HYDROGRAPH - RISING PHASE -- 13.9. FORWARD CHARACTERISTIC - RISING PHASE -- 13.10. WATER SURFACE PROFILE - RISING PHASE -- 13.11. DURATION OF PARTIAL EQUILIBRIUM DISCHARGE -- 13.12. HYDROGRAPH - EQUILIBRIUM PHASE -- 13.12.1. Partial Equilibrium Discharge -- 13.12.2. Equilibrium Discharge -- 13.13. WATER SURFACE PROFILE - EQUILIBRIUM PHASE -- 13.14. EQUILIBRIUM DETENTION STORAGE -- 13.15. WATER SURFACE PROFILE - FALLING PHASE -- 13.16. HYDROGRAPH - FALLING PHASE -- APPENDICES -- APPENDIX A. APPLICABILITYOF KINEMATIC WAVE THEORY.
327   $aA.1. Flow on Overland Plane.
330   $aMy name is Cally Louise Fisher and I haven't spoken for thirty-one days. Talking doesn't always make things happen, however much you want them to. Cally Fisher saw her mum bright and real and alive. But no one believes her, so Cally's stopped talking. A mysterious wolfhound always seems to be there when her mum appears and now he's started following her everywhere. But how can Cally convince anyone that Mum is still with them, or persuade Dad that the huge silver-grey dog is their last link with her? An outstandingly assured debut novel from a sparkling new talent.
410  0$aHydrological science and engineering series.
606   $aRunoff$xMathematical models
606   $aRain and rainfall$xMathematical models
606   $aHydrologic models
615  0$aRunoff$xMathematical models.
615  0$aRain and rainfall$xMathematical models.
615  0$aHydrologic models.
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700   $aWong$b Tommy S. W$01871046
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