9 research outputs found
An Efficient Method for the One-pot, Four-component Benzaldehyde based Synthesis of 3-methyl-1,4-diphenyl-7,8-dihydro-1H-furo[3,4-e]pyrazolo[3,4-b]pyridin-5(4H)-ones Catalyzed by Alum in Environment-friendly Media
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- 'Oriental Scientific Publishing Company'
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- Field of study
No full textFreezing Imine Exchange in Dynamic Combinatorial Libraries with Ugi Reactions: Versatile Access to Templated Macrocycles
- Author
- Publication venue
- 'American Chemical Society (ACS)'
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- Field of study
No full textConjugate Addition of Allyl Stannanes with Concomitant Triflation
- Author
- Publication venue
- 'American Chemical Society (ACS)'
- Publication date
- Field of study
No full textDesign and Synthesis of New Classes of Heterocyclic C
- Author
- Adams D. J.
- Andraos J
- Asymmetric Organocatalysis
- Bertozzi C. R.
- Breinbauer R.
- Cheng R. P.
- Dondoni A
- Dondoni A.
- Dondoni A.
- Dondoni A.
- Dondoni A.
- Dondoni A.
- Dondoni A.
- Dondoni A.
- Dondoni A.
- Dondoni A.
- Enantiocontrolled Synthesis
- For
- Garner P.
- Guignard B.
- Izawa K
- Jas G.
- Kappe C. O.
- Kuwahara M.
- List B
- Lockhoff O
- Lundquist J. J.
- Marcus A. I.
- Mayer T. U.
- McGarvey G. J.
- Multicomponent Reactions
- Palomo C.
- Palomo C.
- Perspectives
- RamĂłn D. J.
- Reagents
- Rosenthal G. A.
- Wu Q.
- Yoshida J.
- Publication venue
- 'American Chemical Society (ACS)'
- Publication date
- Field of study
No full textTechnical Program
- Author
- 11:45 Corp. (1085) An FT-IR Spectrometry Method for Quantitative Analysis of Ethylene-Propylene Copolymer. X. Su Res. Inst
- 2:50 Institute for Med. Res. T. Raglione (188) Chiral Self-Recognition in Bulk Liquids versus Liquid Surfaces
- 4:25 (1224) Studies of the Stabilization State University
- 9:10 Environmental Protection Agency (662) EPA Methods for Organics in Water
- Academic Approaches
- Address Award
- Advances Recent
- Analysis Multicomponent Chemical
- Chemical Sciences Women
- Chemical Sciences Women
- Chemical Scientist The Making
- Chemical Scientists The Professional
- Chemical Target Factor
- Chemist's Logbook The Analytical
- Consolidated Environmental The Impact
- Design Experimental
- Detection Extending
- Detection On-Line
- Detector System A Multifacet AF
- Drug Metabolism LIMS
- Electrochemistry The
- Electrodes Composite
- Element Photodiode Array Spectrometer Design
- Enzyme-Catalyzed Reactions A Simplified
- Extended Kalman Use
- Fluorescence Lifetime Distributions
- Fluorescence Organized Media
- Gel Capillary SDS
- Guard Column Evaluation
- Henry R. A.
- Innovative Spectral Application
- Island Rhode
- Metal Capillary Application
- Micro-Electrospray Direct
- Microscopy-Imaging Scanning Probe
- Miniaturized A New Approach
- Optimal Peak
- P.O. BOX
- Pesticide Residue Research Program FDA
- Photoisomerization Provitamin D
- Polyethylene Terephthalate Morphology
- Precision Improvement
- Radcliffe N. C.
- Raman Near-Visible
- Rapid Microscopy
- Regression Recursive PLS
- Road W. Hurley Pond
- Sample Introduction
- Selective Quenching Agents Examination
- Separations Rapid Drug
- Solids Analysis Multielement High
- Spectroscopy A New CCD
- Step-Scan Interferometry Practical Aspects
- Supercritical Fluid Development
- Supercritical Time-Resolved Fluorescence Reverse Micelles
- Tangential-Flow Torches Linear-Flow
- The Infrastructure
- Triglyceride New Developments
- Ultrasonic Nebulizer Measurements Using ICP-AES
- Various Bile Salts Solubilization
- Versatility
- Volatile Organic Solid-Phase
- Warfarin Analysis
- Water Spectrophotometric Determination
- Weinberger Thermal Gradient MECC. S. W.
- Women Increasing
- Publication venue
- 'American Chemical Society (ACS)'
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No full textCatalytic Asymmetric Synthesis of α-Amino Acids
- Author
- Abdallah R.
- Abe H.
- Achard T.
- Adams B.
- Adams L. A.
- Aghmiz M.
- Aguado G. P.
- Akiyama T.
- Akiyama T.
- Akiyama T.
- Alemparte C.
- AlmodĂłvar I.
- Anderson J. C.
- Andrus M. B.
- Arai S.
- Arend M.
- Avenoza A.
- Avenoza A.
- Bachi M. D.
- Banphavichit V.
- Banti D.
- Bappert E.
- Barbaro P.
- Barnard C. F. J.
- Basra S.
- Bayer
- Becker C.
- Belokon' Y. N.
- Belokon' Y. N.
- Belokon' Y. N.
- Belokon' Y. N.
- Belokon' Y. N.
- Benincori T.
- Bentley D. J.
- Bernardi L.
- Bernsmann H.
- Boaz N. W.
- Boaz N. W.
- Bodkin J. A.
- Bolm C.
- Botman P. N. M.
- Brauer D. J.
- Braun W.
- Breit B.
- Bromidge S.
- Bunlaksananusorn T.
- Bunlaksananusorn T.
- Buonora P.
- Burk M.
- Burk M. J.
- Burkhart D. J.
- Bøgevig A.
- Cabrera S.
- Caplan N. A.
- Castle S. L.
- Catalytic Asymmetric Synthesis
- Celatka C. A.
- Chapman C. J.
- Chen C.
- Chen X.
- Chinchilla R.
- Chinchilla R.
- Chinchilla R.
- Chowdari N. S.
- Chowdari N. S.
- Chowdari N. S.
- Christensen C. A.
- Clochard M.
- Co T. T.
- Cobb A. J. A.
- Collot J.
- Collot J.
- Colston N. J.
- Comprehensive Asymmetric Catalysis
- Corey E.
- Corey E. J.
- Corey E. J.
- Coulon E.
- Crosman A.
- Cycloaddition Reactions
- CĂłrdova A.
- CĂłrdova A.
- CĂłrdova A.
- CĂłrdova A.
- Dahlin N.
- Dang T. P.
- Danjo H.
- Danner P.
- Davies J. R.
- de Bellefon C.
- Diéguez M.
- Dobrota C.
- Doi T.
- DomĂnguez B.
- Dorta R.
- Doyle M.
- Druri W. J.
- Dubrovina N. V.
- Duprat de Paule S.
- Eames J.
- Elango S.
- Englert U.
- Evans D. A.
- Evans D. A.
- Evans D. A.
- Evans D. A.
- Fang X.
- Faucher A.-M.
- Ferraris D.
- Ferraris D.
- Ferraris D.
- Ferraris D.
- Ferraris D.
- Fini F.
- Foltz C.
- For
- For
- For
- For
- For
- For
- For
- For
- For PTC
- Franzén J.
- Fries G.
- Fu G. C.
- Fu Y.
- Fu Y.
- Fuhrmann H.
- Fujii A.
- Fujii A.
- Gao W.
- Gennari C.
- Gergely I.
- Gladiali S.
- Gorla F.
- Gorobets E.
- Gosiewska S.
- Gothelf A. S.
- Greck C.
- Grover G. N.
- Guillarme S.
- Guillena G.
- Guimet E.
- Hagiwara E.
- Halfen J. A.
- Hamada T.
- Hamada T.
- Hamashima Y.
- Han Z.
- Handbook
- Hannen P.
- Harding M.
- Hashimoto T.
- Hayashi T.
- Hayashi T.
- Hems W. P.
- Highlights
- Hoen R.
- Hoge G.
- Hoge G.
- Holz J.
- Hopkins J. M.
- Horner L.
- Hu X. E.
- Hu X.-P.
- Huang H.
- Huang J.
- Hughes D.
- Hughes D.
- Hughes P. F.
- Ichikawa E.
- Imamoto T.
- Imamoto T.
- Ito Y.
- Ito Y.
- Ito Y.
- Ito Y.
- Iwamura H.
- Jacobsen E.
- Janey J. M.
- Jew S.
- Jew S.
- Jia X.
- Jo C. H.
- Johannsen M.
- Juhl K.
- Junge K.
- Jørgensen K. A.
- Kadyrov R.
- Kadyrov R.
- Kaiser J.
- Kanayama T.
- Kanayama T.
- Kato N.
- Kato N.
- Kato N.
- Katsuki
- Keith J. M.
- Khiar N.
- Kim D. Y.
- Kim S.
- Kitamura M.
- Kjaersgaard A.
- Knowles W. S.
- Knudsen K. R.
- Knöpfel T. F.
- Kobayashi S.
- Kobayashi S.
- Kobayashi S.
- Kobayashi S.
- Kobayashi S.
- Komarov I. V.
- Kotrusz P.
- Kowtoniuk W. E.
- Krumper J. R.
- Kumar S.
- Kumar S.
- Kumar S.
- Kuwano R.
- Kuwano R.
- Kuwano R.
- Kyung S.-H.
- Lebel H.
- Lee Y.-J.
- Lee Y.-J.
- Lefort L.
- Lei A.
- Lemaire C.
- Li G.
- Li H.
- Li L.
- Lin C. W.
- Lin Y.-S.
- Liptau P.
- List B.
- List B.
- Liu B.
- Liu D.
- Liu X.
- Liu Y.
- Liu Z.
- Llamas T.
- Loncaric C.
- Longmire J. M.
- Longmire J. M.
- Lowpetch K.
- Lygo B.
- Lygo B.
- Lygo B.
- Lygo B.
- LĂ©pine R.
- Ma S.
- Maeda K.
- Makino K.
- Makino K.
- Makoji M.
- Malkov A. V.
- Malkov A. V.
- Marigo M.
- Marigo M.
- Marigo M.
- Marinetti A.
- Mase N.
- Mase N.
- Matsubara R.
- Matsusita M.
- Mehrman S. J.
- Melville J. L.
- Mettah S.
- Miyazaki T.
- Mohar B.
- Molander G. A.
- Monti C.
- Monti C.
- Mordant C.
- Mordant C.
- Moreau B.
- Morgan A. J.
- Morimoto T.
- Morimoto T.
- Motoyama Y.
- Motoyama Y.
- Multicomponent Reactions
- Murahashi S.-I.
- Murugan E.
- Muñiz K.
- Muñiz K.
- Muñiz K.
- Muñiz K.
- MĂĽller P.
- Nakamura Y.
- Nanayakkara P.
- Navarre L.
- Nemoto T.
- Nguyen H. V.
- Nilov D.
- Nindakova L. O.
- Nitro Compounds
- Nolin K. A.
- Notz W.
- Notz W.
- Notz W.
- Noyori R.
- Noyori R.
- Nugent B. M.
- O'Donnell M. J.
- Oderaotoshi Y.
- Ogasawara M.
- Ogawa C.
- Ohshima T.
- Ohshima T.
- Okada A.
- Ooi T.
- Ooi T.
- Ooi T.
- Ooi T.
- Ooi T.
- Ooi T.
- Ooi T.
- Ooi T.
- Ooi T.
- Ooi T.
- Ooi T.
- Ooi T.
- Palomo C.
- Palomo C.
- Panel
- Park H.
- Park H.
- Patwardhan A. P.
- Patwardhan A. P.
- Peng H.-Y.
- Peña D.
- Pihko P. M.
- Pihko P. M.
- Pilkington C. J.
- Poulsen T. B.
- Pugin B.
- RajanBabu T. V.
- Ramachandran P. V.
- RamĂłn D. J.
- Redlich M.
- Reetz M. T.
- Reetz M. T.
- Reetz M. T.
- Reetz M. T.
- Reetz M. T.
- Reetz M. T.
- Riant O.
- Roesky P. W.
- Roff G. J.
- Rowland G. B.
- Rubble J. C.
- Rubinstein H.
- Rueping M.
- Saaby S.
- Saaby S.
- Saaby S.
- Saaby S.
- Sawamura M.
- Schmidt T.
- Schnell B.
- Scott-Shultz C.
- Seitzberg J. G.
- Sharpless K. B.
- Shaw N. M.
- Shaw S. A.
- Shaw S. A.
- Shibasaki M.
- Shimizu H.
- Shirakawa S.
- Shirakawa S.
- Siebum A. H. G.
- Siebum A. H. G.
- Sigman M. S.
- Simons C.
- Simons C.
- Siva A.
- Skander M.
- Skander M.
- Soloshonok V. A.
- Soloshonok V. A.
- Soro B.
- Srinivasan J. M.
- Steglich W.
- Stohler R.
- Sturm T.
- Suga H.
- Suga H.
- Suga H.
- Suga H.
- Sugiura M.
- Sundén H.
- Suri J. T.
- Suzuki A.
- Taggi A. E.
- Takamura M.
- Takamura M.
- Takamura M.
- Takemoto Y.
- Tang W.
- Tao B.
- Tararov V. I.
- Tararov V. I.
- Teoh E.
- Teoh E.
- The Diels-Alder Reaction
- Thierry B.
- Thomas C. M.
- Timen S.
- Tomioka
- Trost B. M.
- Trost B. M.
- Trost B. M.
- Trost B. M.
- Trost B. M.
- Trost B. M.
- Trost B. M.
- Tsogoeva S. B.
- Tsogoeva S. B.
- Tsuruta H.
- van den Berg M.
- van der Vlugt J. I.
- Versleigen J. P.
- Vilaivan T.
- Vogt H.
- Wang W.
- Wang X.
- Ward T. R.
- Watanabe S.
- Weinreb S. M.
- Weiss T. D.
- Weitbrecht N.
- Westermann B.
- Westermann B.
- Wiles J. A.
- Willans C. E.
- Williams B. S.
- Willis M. C.
- Wolfson A.
- Wolfson A.
- Wu J.
- Wu S.
- Wurz R. P.
- Xie Y.
- Xu X.
- Yamada K.
- Yamashita Y.
- Yan X.-X.
- Yao S.
- Yao S.
- Yi B.
- Yoo M.-S.
- Yoon M. S.
- Yoon T. P.
- You S.-L.
- Yu H.
- Yu Z.-X.
- Yu Z.-X.
- Yuasa Y.
- Yudin A. K.
- Zarka T. M.
- Zeng W.
- Zhang Y. J.
- Zhou X.-T.
- Zhuang W.
- Zsigmond A.
- Publication venue
- 'American Chemical Society (ACS)'
- Publication date
- Field of study
No full textInfrared spectrometry
- Author
- (A3) Determination of the Phenyl Group in Organosilicon Compounds Kreshkov, A. P., Ponomarev, V. S., Kirichenko, E. A., Damaeva, A. D., Shaplna, T. N„ Plast. Massy, 49-50
- (A39) JR Spectroscopic Method for Determining Nitro Group Impurities in Aromatic Diisocyanates Caraculacu, Adrian, Barba lata, Alla, Grigoriu, George E.
- (A53) Determination of the Hydroxyl Number of Polyurethane Prepolymers with Terminal Hydroxyl Groups
- (A55) Quantitative Determination of Isocyanurate Groups in Polyurethane Foam Putnins, E., Putnina, V., Karlivans, V., Latv. PSR Zinat. Akad. VestĂs, Kim. Ser., 367-8
- (A64) Infrared and Ultraviolet Spectroscopic Determination of the Composition of Groups of Compounds in Lubricating Oils of High Sulfur Content Belafi-Rethy, Katalin
- (A67) Determination of Hydroxyl Group Content in Cottonseed Oil Yunusova, S. G., Kantsepol'skaya, F. M., Kristallovich, E. L, Glushenkova, A. I., Umarov, A. U., Khim. Prir. Soedin., 300-3
- (B19) Atlas of Long-Wave Infrared Absorption Spectra of Complex Group III-V Metal and Uranyl Fluorides Kharitonov, Yu. Ya„ Davidovich, R. L., Kostin, V. I., (Nauka
- (B29) The Coblentz Society Desk Book of Infrared Spectra Graver, Clara D.
- (B30) NATO Advanced Study Institute Series Vol.
- (B37) NATO Advanced Study Institutes Series C
- (B4) Proceedings of the Society of Photo-Optical Instrumentation Engineers Vol.
- (B6) International Center of Information on Antibiotics Inf, Bull. 16, Pt.
- (C37) Separation of the Raman or JR Lines of a Group Constituting Several Superimposed Lines Fahys, B., Rondot, D., Mignot, J
- (L9) Broadly Tunable Pulsed Laser for the Infrared Using Color Centers
- (M17) Infrared Studies of some Analgesic Group Commercial Tablet Samples Lai, B. B„ Varma
- (P80) State of Water in Cellulose Acetate Membranes Toprak, Chris, Agar, John N., Falk, Michael
- (R151) Some Wider Uses of Group Frequencies Bellamy, L. J.
- (R25) Fourier Transform Infrared: Applications to National Technical Problems Ferraro, John R., Basile, Louis J.
- (R28) Characteristic Vibrational Frequencies of Compounds Containing Main-Group Elements Gans, P.
- (T116) High Resolution Study of the Group V Impurities Absorption in Silicon Pajot, B., Kauppinen, J., Anttila, R.
- (T37) Infrared Group
- Absorption Effects Naylor
- Absorption Infrared Spectroscopy Pritchard
- Absorption Scanning Matare
- Absorption Spectra Lin
- Absorption Spectrum Chang
- Absorption System Using Topographic
- Actinides Goffart
- Activation
- Activation Analysis Hoffmann
- Adsorbed Species Dignam
- Air Dispersion Filters Vereshchagin
- Airplane Appel
- Alkali Metal Methacrylates III
- Alkyds Frazee
- Aluminum Single Crystals Mertens
- Ambient Temperature Griffiths
- Amorphous Semiconductors Brodsky
- An Audio-Visual Program Maas
- An Infrared Method Iyer
- An Iterative
- Analysis Dally
- Analytical Chemistry Geick
- Analytical Chemistry Hirschfeld
- Analytical Laboratory Manocha
- Analyzer Lang
- Analyzers Refine Process Control Jones
- Anesthetic Chemicals Zeller
- Anharmonic Vibrations Durig
- Anisotropic Branched Polyethylene
- Answer Box'Approach Obremski
- Application Chaney
- Applications
- Applications Carlsson
- Applied Infrared Spectroscopy
- Aragonite-Calcite Transformation Rao
- Aromatic Chlorocarbons Ballester
- Aromatic Polyamide Fibers King
- Aromatic Polyamides Shablygin
- Artifact Strassburger
- Atactic Polystyrene Enns
- Atactic Polystyrene Jasse
- Atmosphere
- Atmosphere Cappellani
- Atmosphere Lukshin
- Atmosphere Maker
- Atmospheric Formaldehyde Marche
- Atmospheric Halocarbon Monitoring Techniques Rasmussen
- Atmospheric Reactions Niki
- Atmospheric Sensing Restelli
- Atmospheric Trace Constituents I.
- Atmospheric Trace Gases Sebacher
- Attenuated Total Internal Reflection Dorofeev
- Attenuated Total Reflection Crawford
- Attenuated Total Reflection Escolar
- Automated Interpretation Heite
- Avail
- Band Filters Chamberlain
- Band Resolution V.
- Bandpass Mesh Interference Filters Holah
- Barley Allison
- Based File Searching Powell
- Biological Interest Vergoten
- Biological Macromolecules D'Esposito
- Biological Membranes A
- Block Copolymers West
- Blown Polypropylene Films Bottin
- Boehm S.
- Buback Z. Naturforsch.
- Bulk Materials Hass
- Calcium Fluoride Surfaces Palik
- Calculating Molecular Vibrations Dement'ev
- Calibration Curves I.
- Carbon Dioxide Determination Paul
- Carbon Dioxide Huddleston
- Carbon Dioxide Measurements Bischof
- Carbon Dioxide Parkinson
- Carbon Painter
- Carbon Zawadzkl
- Cellulose Vakulyuk
- Cement De Luxan
- Cement Manufacture Ghosh
- Chain Structure Dobos
- Chemical Analysis Butler
- Chemistry Griffiths
- Chenery D. H.
- Chloramphenicol Namigohar
- Chloroform Halothane
- Chromatograms Hanna
- Chromatography
- Chromatography Versaud
- Chrtins Galat
- Coal A Novel
- Coal Bartle
- Coker Gasoline Distillate Hanna
- Column Eluates Vldrlne
- Commercial Dlvlnylbenzene Witt
- Compensational Spectra Baumgarten
- Complex Organic Mixtures Lynch
- Component Metals Mertens
- Composite Matrix Resins May
- Compound Identification System Hanna
- Compounds Von Eijk
- Computer Assisted Vibrational Spectroscopy Coleman
- Computer-Readable Form Penca
- Conservation I. General Principles
- Contaminants Using Grating Spectrometers Obremski
- Conventional Gas Chromatograph Shaps
- Copper Light Pipes Griffiths
- Correlation Functions Lester
- Correlation Infrared Process Analyzer Garfunkel
- Correlation Spectroscopy Wiens
- Cost Infrared Data Systems Coates
- Counter Imaging System Krasutsky
- Cryogenic Solutions Freund
- Crystalline Polymers Tadakoro
- Crystals Hexter
- Crystals Vakulenko
- Cyclic Loading Leksovskll
- Dairy Laboratory Hoffer
- Danielsson Bengt
- Data Collections A. Condensed Phases
- Defect Polymer Solids Loginov
- der Tensile Loads Gudim
- Desiccant Samish
- Detailed Intensity Information Rasmussen
- Detection Claspy
- Detection Kreuzer
- Detection Pao
- Detector Talmi
- Deuterated Lipids Smith
- Diameter Tungsten Wire Mok
- Diamond Anvil Cell Klaeboe
- Differential Infrared Spectrophotometry Naqvi
- Differential Infrared Spectroscopy Rousseaux
- Diketones Valiere
- Dimov N.
- Dioxide Hirano
- Dispersive Fourier Transform Spectrometry Birch
- Dispersive Fourier Transform Spectroscopy Birch
- Dye Laser Hartig
- Dynamic Infrared Studies I.
- Effects In Difference Spectra Aliara
- Effluents Curbelo
- Effluents Mattson
- Electric Field Courtois
- Electrical Insulating Materials Blahnlk
- Electrolytic Extraction-Infrared Spectrometry Yoshida
- Electron Energy Loss Spectroscopy Froitzheim
- Elevated Temperatures Terlemezyan
- Ellipsometric Method Batavin
- Emission Measurements Baumgarten
- Enamel C
- Environmental Analysis Griffiths
- Environmental Protection Schunck
- Epoxy Resin Formulations Hagnauer
- Ethylene Fukumi
- External Calibration Koenig
- Far Infrared Absorption Spectra Tateyama
- Far Infrared Astronomical Observations Houck
- Far Infrared Fourier Spectroscopy Kitade
- Far Infrared Kilp
- Far Infrared Radostitz
- Far Infrared Spectroscopy K'rtade
- Far Infrared Spectroscopy Otsuka
- Far-Infrared Interferometry Durig
- Farhat Shamim
- Fat Protein
- Fiber-Forming Polymers Marupov
- Fibers
- Fibrous Materials Aronson
- Films Stas'kov
- Filter Correlation Methods Gryvnak
- Flame-Retardant Fabrics McCall
- Fleming John
- Flip Raman Laser Smith
- Fluorescence Spectroscopy Gottardi
- Forensic Analysis Griffiths
- Forensic Science Grieve
- Formulation Quality Control Obremski
- Fourier Air Monitor Smith
- Fourier Spectroscopy Fonck
- Fourier Transform Infrared
- Fourier Transform Infrared Green
- Fourier Transform Infrared Griffiths
- Fourier Transform Infrared Spectra Antoon
- Fourier Transform Infrared Spectrometer Baumgarten
- Fourier Transform Infrared Spectrometer Kuehl
- Fourier Transform Infrared Spectrometer Kuehl
- Fourier Transform Infrared Spectrometer Mattson
- Fourier Transform Infrared Spectrometers Anderson
- Fourier Transform Infrared Spectrometry
- Fourier Transform Infrared Spectrometry Grieble
- Fourier Transform Infrared Spectrometry Hembree
- Fourier Transform Infrared Spectrometry Hirschfeld
- Fourier Transform Infrared Spectrometry Hirschfeld
- Fourier Transform Infrared Spectrometry Hirschfeld
- Fourier Transform Infrared Spectrometry Lowry
- Fourier Transform Infrared Spectrometry Matsul
- Fourier Transform Infrared Spectrometry Taylor
- Fourier Transform Infrared Spectroscopy
- Fourier Transform Infrared Spectroscopy
- Fourier Transform Infrared Spectroscopy D'Esposito
- Fourier Transform Infrared Spectroscopy Genzel
- Fourier Transform Infrared Spectroscopy Ishida
- Fourier Transform Infrared Spectroscopy Sprouse
- Fourier Transform Infrared Spectroscopy Wehry
- Fourier Transform Infrared System Krishnan
- Fourier Transform Spectrometer Scanlon
- Fourier Transform Spectroscopy Cooper
- Fourier Transform Spectroscopy Larson
- Fourier Transform Spectroscopy Ă‘afie
- Fractionated Coal Liquids Painter
- Free Carrier Infrared Absorption Schwartz
- Free Radicals Hester
- Fuels Spectroscopic
- Gain Ranging Hirschfeld
- Gas Chromatographic Peaks Delaney
- Gas Chromatographic Peaks Wall
- Gas Chromatography Delaney
- Gas Chromatography Delaney
- Gas Chromatography Effluents Clark
- Gas-Chromatographic Methods Sklyar
- Gaseous Pollutants Laurent
- Gel Permeation Chromatography Birley
- General Concepts Buechi
- Germanium Compounds Nauka
- Glass Fiber Ishida
- Glass Surfaces Fink
- Glycerides Using Infrared Detection Parris
- Gravimetric Study Careri
- Harmonic Generator Zuidberg
- Hemiellipsoidal Mirror Infrared Reflectometer Wood
- Hemocyanins Carbon
- Hemoglobin Alben
- Hemoglobin Alben
- Heterodyne Interferometer Kristal
- Heterodyne Spectrometers Betz
- High Grade Quartz Lipson
- High Magnetic Fields Kotthaus
- High Pressure Obriot
- High Pressures Ferraro
- High Sensitivity Huber-Waelchll
- High Spectral Resolution Spaenkuch
- High Temperatures Hattori
- High-Power CW
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No full textPhotochemical Reactions as Key Steps in Organic Synthesis
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- Abad S.
- Abdel-Wahab A.-M. A.
- Abe M.
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