LEADER 08771nam  2200625 a 450 
001 9910972860403321
005 20251116181722.0
010   $a1-62417-266-0
035   $a(CKB)2550000001042507
035   $a(EBL)3020295
035   $a(SSID)ssj0000860546
035   $a(PQKBManifestationID)12430791
035   $a(PQKBTitleCode)TC0000860546
035   $a(PQKBWorkID)10917072
035   $a(PQKB)10737058
035   $a(MiAaPQ)EBC3020295
035   $a(Au-PeEL)EBL3020295
035   $a(CaPaEBR)ebr10676512
035   $a(OCoLC)923663531
035   $a(BIP)42956913
035   $a(BIP)41657835
035   $a(EXLCZ)992550000001042507
100   $a20130207d2013      uy         0
101 0 $aeng
135   $aur|n|---|||||
181   $ctxt
182   $cc
183   $acr
200 00$aNew developments in quartz research $evarieties, crystal chemistry and uses in technology /$fBruno Novak and Pavla Marek, editors
205   $a1st ed.
210   $aNew York $cNova Publishers$dc2013
215   $a1 online resource (287 p.)
225 0 $aGeology and mineralogy research development
300   $aDescription based upon print version of record.
311 08$a1-62417-265-2 
320   $aIncludes bibliographical references and index.
327   $aIntro -- NEW DEVELOPMENTS  IN QUARTZ RESEARCH -- NEW DEVELOPMENTS  IN QUARTZ RESEARCH -- CONTENTS -- PREFACE -- QCM IN THE ACTIVE MODE:  THEORY AND EXPERIMENT -- ABSTRACT -- ABBREVIATIONS (GLOBAL) -- 1. MEASUREMENT OF BOND RUPTURE FORCE WITH THE HELP OF A QUARTZ CRYSTAL MICROBALANCE -- 1.1. Introduction -- 1.2. Experimental, Theory, Results -- 2. A MATHEMATICAL MODEL -- 2.1. Introduction -- 2.2. One-Dimensional Resonator Model Based on Longitudinal Oscillatory Motions in Thin Plates -- 2.3. The Effect of a Point Load on a Quartz Crystal Microbalance -- 2.4. Oscillatory Motion in a Viscous Liquid -- 2.5. One-Dimensional Model of the QCM in Application to the Rupture Bond Strength Measurement -- 3. APPLICATION OF THE METHOD -- 3.1. Quantitative Detection and Separation of Bacteria Using Rupture Event Scanning -- 3.1.1. Introduction -- 3.1.2. Materials and Methods -- Preparation of Bacterial Samples -- Preparation of Antibody Coated Surfaces -- Detection of E. Coli and S. Aureus -- Scanning Electron Microscopy Imaging -- Data Processing -- 3.1.3. Results and Discussion -- Formation of Antibody Monolayers on the QCM -- Infectivity of REVS Recovered Bacteria -- Scanning Electron Microscopy Images -- Nature of the Acoustic Signal. Modeling -- 3.1.4. Effect of Temperature -- 3.2. Bacteriophage Identification  QCM in t -- 3.3. Virus Detection -- 3.4. Quartz Crystal Microbalance as a Sensing Active Element for Rupture Scanning Within Frequency Band -- 3.4.1. Experimental Section -- Materials -- Measuring Circuit -- Measurement Procedure -- Mathematical Processing of Experimental Data -- 3.4.2. Results -- 3.4.3. Discussion -- 3.5. QCM Operating in Threshold Mode as Gas Sensor -- 3.5.1. Materials and Methods -- The Physical Picture of the Generation of Acoustic Signal -- 3.5.2. Results and Discussion.
327   $a4. FEATURES OF MASS LOAD MEASUREMENTS IN SENSORS BASED ON QUARTZ CRYSTAL MICROBALANCE -- CONCLUSION -- REFERENCES -- NATURE OF PARAMAGNETIC DEFECTS  IN  -QUARTZ: PROGRESSES IN THE FIRSTDECADE OF THE 21ST CENTURY -- ABSTRACT -- I. INTRODUCTION -- II. QUARTZ CRYSTAL STRUCTURE -- III. IMPURITY CENTERS -- Al Hole Centers -- Ge Centers -- Fe Centers -- IV. PARAMAGNETIC DEFECTS RELATED TO OXYGEN OR SILICON VACANCY -- The E' Centers -- The E'' Centers -- The Silicon-Vacancy Hole Centers -- APPENDIX. SPIN HAMILTONIAN PARAMETERS OF PARAMAGNETIC DEFECTS IN QUARTZ -- ACKNOWLEDGMENT -- REFERENCES -- VEINED QUARTZ OF THE URALS: STRUCTURE, MINERALOGY, AND TECHNOLOGICAL PROPERTIES -- ABSTRACT -- INTRODUCTION -- SUBPOLAR URALS -- CENTRAL URALS -- SOUTH URALS -- Structural Position of Water in the Urals Quartz -- ?RACE ELEMENTS IN THE URALS QUARTZAND CONCENTRATION TECHNOLOGIES -- REFERENCES -- DENSIFICATION OF QUARTZ PARTICLE BEDS BY TAPPING -- ABSTRACT -- 1 QUARTZ AS THE MAJOR FILLER IN ENGINEERED STONE -- 2 DENSIFICATION OF MONOMODAL QUARTZ PARTICLE BEDS BY TAPPING -- 2.1. Proposed Kinetic Model -- 2.2. Verification of the Model 2 -- 3 DENSIFICATION OF BIMODAL QUARTZ PARTICLE BEDS BY TAPPING -- 3.1. Curves: Specific Volume of the Mixture,  , Versus Mixture Composition, X. Mixture Efficiency Factor -- 3.1.1. Initial Bed Fractional Bulk Density,   The -- 3.1.2. Final Bed Fractional Bulk Density Resulting from Tapping, -- 3.2. Kinetics of Densification by Tapping -- CONCLUSION -- REFERENCES -- RAPID DETECTION FOR POLLUTANTS  AND BACTERIA BASED ON QUARTZ CRYSTAL MICROBALANCE BIOSENSOR -- ABSTRACT -- 1. INTRODUCTION -- 2. SENSITIVE RECOGNITION ELEMENTS -- 2.1. MIP Film -- 2.2. Aptamer Coated Film -- 2.3. Micro/Nanomaterials Coated on QCM Chip -- 2.4. Carbon Nanotubes Coated Electrode -- 3. QCM BASED ON MOLECULARLY IMPRINTED TECHNOLOGY.
327   $a4. QCM BASED ON IMMUNOLOGICAL METHOD -- 5. DNA QCM BIOSENSOR -- 6. QCM WITH DISSIPATION BIOSENSOR -- CONCLUSION -- REFERENCES -- NOVEL QUARTZ OSCILLATOR MEASUREMENT FOR GAS COMPOSITION CHANGES -- ABSTRACT -- INTRODUCTION -- PRINCIPLE OF MEASUREMENT -- GAS COMPOSITION MEASUREMENT USING QUARTZ OSCILLATOR -- 1. Hydrogen Sensing and Concentration Measurement -- 2. Air-Helium Gas Mixtures -- 3. Humidity Measurement -- 4. Silane-Hydrogen Gas Mixtures -- 5. Nitrogen-Hydrogen Gas Mixtures -- 6. Multi (More Than Three)-Component Gas Mixtures -- CONCLUSION -- ACKNOWLEDGMENT -- REFERENCES -- DETECTION/ADSORPTION OF CHEMICAL AND BIOLOGICAL MOLECULES BASED ON QUARTZ CRYSTAL MICROBALANCE (QCM) AS SENSOR -- ABSTRACT -- 1. INTRODUCTION -- 2. BASIC PRINCIPLES OF QCM -- 3. QCM MEASUREMENTS -- 4. ADSORPTION ROUTS ON THE QCM SURFACE -- 4.1. In-situ Route for Adsorption Process -- 4.2. Indirect Route for Adsorption Process -- 5. APPLICATIONS OF QCM -- 5.1. Environmental Applications -- 5.2. Gas Applications -- 5.3. Chemical Applications -- 5.4. Detection of Antigens and Antibodies -- 5.5. Detection of Enzymatic Proteins -- CONCLUSION -- REFERENCES -- USEFULNESS OF THE QUARTZ CRYSTAL MICROBALANCE TECHNIQUE TO ASSESS IN SITU DETERGENCY PROCESS EFFICIENCY -- ABSTRACT -- 1. INTRODUCTION -- 2. EXPERIMENTAL -- 2.1. Materials and Methods 2. -- 2.2. Sample Preparation -- 2.3. Stearic Acid Removal -- 3. RESULTS -- 3.1. Preliminary Tests -- Validation of the Method -- Preliminary Verifications -- 3.2. Detergent Concentration versus Cleaning Time cl -- 3.3. Initial Contamination versus Cleaning Time -- CONCLUSION -- REFERENCES -- VERY RECENT DEVELOPMENT AND SIGNIFICANT STEP IN ULTRA-STABLE QUARTZ OSCILLATORS -- ABOUT THE AUTHOR -- ABSTRACT -- INTRODUCTION -- 1. SEVERAL POSSIBLE CUTS FOR QUARTZ -- 1.1. The AT-Cut -- 1.2. The LD-Cut -- 1.3. The SC-Cut -- 2. NEW DESIGN OF OSCILLATORS.
327   $a3. NOISE OF THE RESONATOR -- 4. STABILITY MEASUREMENT OF OSCILLATORS -- 4.1. Determination of Frequency Stability for the Best Quartz Oscillators -- 4.2. State-of-the-Art -1 -- 5. DISTRIBUTION OF THE SIGNAL -- CONCLUSION -- REFERENCES -- GOLD ANALYSIS AFTER NANOPARTICLE ADSORPTION ON QUARTZ REFLECTORS  AND TOTAL REFLECTION X-RAY FLUORESCENCE (TXRF) ANALYSIS -- ABSTRACT -- 1. INTRODUCTION -- 2. EXPERIMENTAL -- 2.1. Chemicals and Solutions -- 2.2. Reduction of Gold and Adsorption on Quartz Reflector -- 2.3. TXRF Analysis -- 2.4. Cleaning Procedure -- 3. RESULTS -- CONCLUSION -- REFERENCES -- INDEX.
330   $aIn this book, the authors present new developments in quartz research. Topics discussed in this compilation include the nature of paramagnetic defects in a-Quartz; veined quartz of the Urals; QCM in the active mode; densification of quartz particle beds by tapping; rapid detection for pollutants and bacteria based on quartz crystal microbalance biosensors; novel quartz oscillator measurement for gas composition changes; detection/adsorption of chemical and biological molecules based on quartz crystal microbalance QCM as sensor; usefulness of quartz crystal microbalance techniques to assess in situ detergency process efficiency; ultra-stable quartz oscillators; and gold analysis after nanoparticle adsorption on quartz reflectors and total reflection x-ray fluorescence (TXRF) analysis.
606   $aQuartz crystals
606   $aQuartz$xIndustrial applications
615  0$aQuartz crystals.
615  0$aQuartz$xIndustrial applications.
676   $a549/.68
701   $aNovak$b Bruno$f1964-$01861765
701   $aMarek$b Pavla$f1973-$01861766
801  0$bMiAaPQ
801  1$bMiAaPQ
801  2$bMiAaPQ
906   $aBOOK
912   $a9910972860403321
996   $aNew developments in quartz research$94467964
997   $aUNINA