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#1
Jim Baggott. - Oxford : Oxford University Press, 2020
• Novel presentation of equations as recipes aids comprehension • Demystifies the most iconic equations of quantum mechanics • Clear presentation, suitable for all courses covering quantum mechanics • Provides philosophical context typically absent in other textbooks
Signatur: 51938
u:search: https://ubdata.univie.ac.at/AC15656287
#2
Jeffrey A. Barrett. - Oxford, United Kingdom : Oxford University Press, 2019
• Conceptually clear and accessible, helping readers to understand a difficult and counterintuitive subject • Builds the conceptual tools for a clear understanding while explaining the subject; every major approach so far to understanding quantum mechanics is discussed • Allows for complete understanding by integrating technical, historical, and conceptual material • Covers recent debates, which provides an entry for the reader into current literature
Signatur: 51937
u:search: https://ubdata.univie.ac.at/AC16057699
#3
Yury M. Belousov, Serguei N. Burmistrov, Alexei I. Ternov. - Weinheim : Wiley-VCH, [2020]
"Problem Solving in Theoretical Physics" helps students mastering their theoretical physics courses by posing advanced problems and providing their solutions - along with discussions of their physical significance and possibilities for generalization and transfer to other fields.
Signatur: 51928
u:search: https://ubdata.univie.ac.at/AC16054130
#4
Alexander A. Bortsov, Yuri B. Il’in, Sergey M. Smolskiy. - Cham : Springer, [2020]. - (Springer series in optical sciences 232)
• Focuses on non-traditional optoelectronic oscillators (OEO) featuring a laser or quantum well laser diode • Considers in depth the sources of phase noises and their minimization • Employs a semi-classical model for the laser description for a simpler yet still insightful treatment of phase noise
Signatur: 31089/232
u:search: https://ubdata.univie.ac.at/AC15761966
#5
Piotr T. Chruściel. - Oxford, United Kingdom : Oxford University Press, [2020]. - (International series of monographs on physics 169)
• A broad, up to date presentation of all mathematical aspects of the geometry of black hole spacetimes • Detailed analysis of the geometry of several key black hole metrics • A thorough introduction to the key facts and notions needed for a mathematical treatment of the problem of classification of stationary black holes
Signatur: 2999/169
u:search: https://ubdata.univie.ac.at/AC15754073
#6
Osvaldo Civitarese, Manuel Gadella. - Cham : Springer, [2020]. - (Lecture notes in physics 974)
• Covers a broad range of methods applicable to both classical and quantum systems • Helps readers to grasp various representations, from the standard probabilistic approach to more elaborated frameworks • Provides a solid basis for addressing the statistical mechanics of a broad range of problems common to solid-state, nuclear and particle physics
Signatur: 23643/974
u:search: https://ubdata.univie.ac.at/AC15761833
#7
Mikhail I. Dyakonov. - Cham, Switzerland : Springer, [2020]. - (SpringerBriefs in physics)
• Briefly presents the 25-year history of ideas and research in this area • Expresses and justifies serious doubts about the possibility of ever building a quantum computer • Is accessible to a broad readership of students, academics, and engineers, as well as the general public
Signatur: 48438/[31]
u:search: https://ubdata.univie.ac.at/AC15656659
#8
Peter William Egolf, Kolumban Hutter. - Cham, Switzerland : Springer, [2020]
• Written by experts in the field, it provides analytical and numerical solutions of nonlocal turbulent flow problems based on the authors’ scientific research work • Gives recipes for generalizing local into nonlocal turbulence models • Contains novel approaches based on the nonextensive thermodynamics of turbulence • Outlines analogies between turbulence and other physical fields
Signatur: 51901
u:search: https://ubdata.univie.ac.at/AC15747027
#9
Daniel A. Fleisch. - Cambridge, United Kingdom : Cambridge University Press, 2020
• Fully worked examples illustrate the key concepts • A clear and plain language approach illuminates a complex topic for students • The supporting website hosts a range of resources including videos, quizzes and a glossary
Signatur: 51809
u:search: https://ubdata.univie.ac.at/AC16055379
#10
Jens Freudenberger und Martin Heilmaier. - Weinheim : Wiley-VCH Verlag GmbH & Co. KGaA, [2020]
Das erste Lehrbuch zur Metallkunde der Nichteisenmetalle, didaktisch hervorragend aufbereitet und mit mehr als 400 farbigen Abbildungen, gibt den Leserinnen und Lesern eine Einführung in Darstellung, Konstitution, Gefüge und physikalische Eigenschaften der Nichteisenmetalle.
Signatur: 51921
u:search: https://ubdata.univie.ac.at/AC15347722
#11
Rodolfo Gambini, Jorge Pullin. - New Jersey ; London ; Singapore : World Scientific, [2020]
This book describes loops quantum gravity and its applications to cosmology, black holes and spin foams without using formulas. It is concise and has a light style that makes for easy reading yet covering many of the cutting-edge developments in the field. It also addresses some of the controversies that surround these topics as they are incomplete science.
Signatur: 51463
u:search: https://ubdata.univie.ac.at/AC15733207
#12
Robert T. Hanlon ; illustrations by Robert Hanlon and Carly Sanker. - Oxford, United Kingdom : Oxford University Press, 2020
• Explores from three perspectives: practicing engineer, academic, and historian • Range of foundational topics such as the atomic theory, energy, entropy, and the laws of thermodynamics • With a conversational writing approach making it accessible for students from many different technical backgrounds • Features informative and intricate original illustrations throughout
Signatur: 51935
u:search: https://ubdata.univie.ac.at/AC16057745
#13
J.L. Heilbron. - Oxford : Oxford University Press, 2020. - (Very short introductions 627)
• Covers the life and work of one of the most creative physicists of the 20th century, Niels Bohr, who pioneered the quantum theory of the atom • Considers how Bohr’s work was influenced by his philosophy and humanist concerns • Alongside Bohr as a scientist, discusses his role as a statesman, institution builder, and Danish cultural icon • Offers the first overview in English that draws on all the available sources, which the author has had a hand in uncovering
Signatur: 45108/627
u:search: https://ubdata.univie.ac.at/AC16057725
#14
Paul Horowitz, Winfield Hill. - Cambridge : Cambridge University Press, 2020
• An important addition to The Art of Electronics literature, this book provides the space to explore key topics in detail, in a way that wasn’t possible in the main volume • Covers topics ranging from specialized tables, such as high-speed VFB and CFB op-amps to JFETs, fast LED pulsers and transient voltage protection • Can be used separately as an advanced standalone book or as an addition to the main volume
Signatur: 51571
u:search: https://ubdata.univie.ac.at/AC15518088
#15
Kazuchika Ohta. - New Jersey ; London ; Singapore : World Scientific, [2020]
For pursuing the functionality of materials, it may be indispensable to understand the molecular aggregation states of crystals, liquid crystals, glass, colloids, etc. In this book, the author will focus on the basis of polymorphic phenomena of crystals and liquid crystals and their physical properties. After reading this book, you will be able to change your viewpoint of matter from traditional limited "three states of matter" to novel "numerous states of matter".
Signatur: 51795
u:search: https://ubdata.univie.ac.at/AC15737251
#16
editor Valia Allori. - New Jersey ; London ; Singapore : World Scientific, [2020]
The book explores several open questions in the philosophy and the foundations of statistical mechanics. Each chapter is written by a leading expert in philosophy of physics and/or mathematical physics.
Signatur: 51792
u:search: https://ubdata.univie.ac.at/AC15737680
#17
organized by Antonio A.P. Videira and Carlos F. Puig. - Rio de Janeiro ; São Paulo : LF Editorial, 2020
Antonio Augusto Passos Videira selected a set of letters that show the development of physics in various parts of the world between the 1920s and 1980s. These documents will contribute significantly to a better understanding of the processes by which physics has become a reality in places as different as Cordoba, Rio de Janeiro, Odessa, Leipzig, and Lyon.
Signatur: 51811
u:search: https://ubdata.univie.ac.at/AC15754820
#18
Claude Cohen-Tannoudji, Bernard Diu, Franck Laloe. - Berlin De Gruyter, [2020]
Ihr zwei-bändiges Standardlehrbuch haben Cohen-Tannoudji und seine Co-Autoren nun ergänzt mit Band 3 zu fortgeschrittenen Themen der Quantenmechanik, in dem sie die bewährte Kapitelstruktur von Theorie und Anwendungsbeispielen mit nachfolgendem Vertiefungsteil beibehalten.
Signatur: PHY-400/3
u:search: https://ubdata.univie.ac.at/AC15763146
Auch online verfügbar: https://doi.org/10.1515/9783110649130
#19
Luc Thomas Ikelle. - Second edition. - New Jersey ; London ; Singapore : World Scientific, [2020]
The key focus of this book is to familiarize readers with the concepts of elastic and electromagnetic wave propagation, which are central to geophysical studies. Elastic waves and electromagnetic waves are two important ways that energy is transported in the world around us. These important concepts are presented through examples. Special focus is on earthquakes, volcanoes, energy resources, and climate which are the present and future challenges of our times.
Signatur: 51796
u:search: https://ubdata.univie.ac.at/AC15737324
#20
R. Shankar. - Expanded edition. - New Haven ; London : Yale University Press, 2019
Now in an expanded edition—complete with problem sets and answers for course use or self-study—this work provides an ideal introduction for college-level students of physics, chemistry, and engineering; for AP Physics students; and for general readers interested in advances in the sciences. The book begins at the simplest level, develops the basics, and reinforces fundamentals, ensuring a solid foundation in the principles and methods of physics.
Signatur: 51927/1
u:search: https://ubdata.univie.ac.at/AC16054388
#21
R. Shankar. - Expanded edition. - New Haven ; London : Yale University Press, 2020
R. Shankar is a well-known physicist and contagiously enthusiastic educator, whose popular online introductory-physics video lectures have been viewed over a million times. In this second book based on his online courses, Shankar explains electromagnetism, optics, and quantum mechanics, developing the basics and reinforcing the fundamentals. With the help of problem sets and answer keys, students learn about the most interesting findings of today’s research while gaining a firm foundation in the principles and methods of physics.
Signatur: 51927/2
u:search: https://ubdata.univie.ac.at/AC16054471
#22
Anthony Kelly and Kevin M. Knowles. - Third edition. - Hoboken, NJ : Wiley, 2020
This new edition of ’Crystallography and Crystal Defects’ explains the modern concepts of crystallography in a clear, succinct manner and shows how to apply these concepts in the analyses of point, line and planar defects in crystalline materials.
Signatur: 51799
u:search: https://ubdata.univie.ac.at/AC15746687
#23
Alexander Kokhanovsky, editor. - Cham : Springer International Publishing, [2019]. - (Springer series in light scattering volume 4)
• Offers tips on how to approach the solution of practical problems related to light scattering • Includes a chapter on atmospheric remote sensing • Provides numerous step-by-step tutorials
Signatur: 51111/4
u:search: https://ubdata.univie.ac.at/AC15746168
#24
Alexander Kokhanovsky, editor. - Cham : Springer, [2020]. - (Springer series in light scattering volume 5)
• Includes tip how to perform lidar remote sensing of clouds, both from space and the ground • Describes engineering approaches to polarimetry • Makes it possible to study snowpack albedo
Signatur: 51111/5
u:search: https://ubdata.univie.ac.at/AC15746171
#25
Vladimir M Kolomietz, Shalom Shlomo. - New Jersey ; London ; Singapore : World Scientific Publishing Company, [2020]
This book describes recent theoretical and experimental developments in the study of static and dynamic properties of atomic nuclei, many-body systems of strongly interacting neutrons and protons. The theoretical approach is based on the concept of the mean field, describing the motion of a nucleon in terms of a self-consistent single-particle potential well which approximates the interactions of a nucleon with all the other nucleons. The theoretical approaches also go beyond the mean-field approximation by including the effects of two-body collisions.
Signatur: 51793
u:search: https://ubdata.univie.ac.at/AC15737770
#26
Alexei A. Kornyshev, Dominic O’Lee. - New Jersey ; London ; Singapore Beijing ; Shanghai ; Hong Kong ; Taipei ; Chennai ; Tokyo : World Scientific, [2020]
This book is an attempt to engage learners, presenting mathematical methods in simple terms, with more of an emphasis on skills as opposed to technical knowledge. Based on intuition and common sense rather than mathematical rigor, it teaches students from scratch using pertinent examples, many taken across the physical sciences. This book provides an interesting new perspective of what a mathematics textbook could be, including historical facts and humour to complement the material.
Signatur: 51800
u:search: https://ubdata.univie.ac.at/AC15736023
#27
Peter Kosso. - New Jersey ; London ; Singapore : World Scientific Publishing, [2020]
This book offers a historical account, from ancient Greek science to the theory of relativity and ultimately to videos taken from outer space. Using an accessible and entertaining narrative suitable for anyone interested in astronomy, physics, or the history of either, Kosso clarifies the use of evidence to prove that the Earth rotates, and deals with the tension between the claims that the Earth is absolutely in motion, yet all motion is relative. The book also explores the general nature of scientific evidence and method, and confronts challenges to science from outside the discipline.
Signatur: 51797
u:search: https://ubdata.univie.ac.at/AC15736021
#28
V.K.B. Kota. - Singapore : Springer, [2020]
• Discusses the technical aspects of SU(3) algebra in an easily understandable form • Describes a large number of nuclear models that admit SU(3) • Highlights the importance of group theoretical models in nuclei • Helps researchers in nuclear physics to interpret data on rotational nuclei using SU(3) symmetry
Signatur: 51902
u:search: https://ubdata.univie.ac.at/AC15747011
#29
Karl F. Kuhn, Frank Noschese. - Third edition. - Hoboken, NJ : Jossey-Bass, [2020]
Basic Physics: A Self-Teaching Guide, 3rd Edition’ is the most practical and reader-friendly guide to understanding all basic physics concepts and terms. The expert authors take a flexible and interactive approach to physics based on new research-based methods about how people most effectively comprehend new material. The book takes complex concepts and breaks them down into practical, easy to digest terms.
Signatur: 51945
u:search: https://ubdata.univie.ac.at/AC16054151
#30
Stefano Mancini, Andreas Winter. - New Jersey ; London ; Singapore : World Scientific, [2020]
Students with diverse backgrounds, in mathematics, physics and computer science, can use this book to become acquainted with the quantum theory of information. Its scope is deliberately chosen to be not too broad, while being self-consistent and usable for a semester-long course for beginners. The subject is presented using a balanced mix of intuitive arguments and rigorous formalism. The emphasis is not on the physical information but rather in the formal and mathematical features of quantum information theory.
Signatur: 51794
u:search: https://ubdata.univie.ac.at/AC15737662
#31
Michael Mansfield and Colm O’Sullivan. - Third Edition. - Chichester : Wiley, 2020
This revised and updated third edition presents a comprehensive introduction to college-level physics. Written with today’s students in mind, this compact text covers the core material required within an introductory course in a clear and engaging way.Worked examples and links to problems, designed to be both illustrative and challenging, are included throughout. With links to over 600 problems and their solutions, as well as to more advanced sections, interactive problems, simulations and videos.
Signatur: 49478
u:search: https://ubdata.univie.ac.at/AC15768362
#32
Joseph Mazur. - New Haven : Yale University Press, [2020]
Named one of Book Riot’s Six Great Nonfiction Books about Time: a tour of clocks throughout the centuries—from the sandglass to the telomere—that reveals the physical, biological, and social nature of time.
Signatur: 51930
u:search: https://ubdata.univie.ac.at/AC16054336
#33
Subhendra Mohanty. - Cham : Springer, [2020]. - (Lecture notes in physics 975)
• Collects in a single concise volume the fundamentals of astroparticle physics, particle physics and cosmology • Presents the current state of research in a pedagogical way • The topics covered are based on new but well established experimental results
Signatur: 23643/975
u:search: https://ubdata.univie.ac.at/AC16069424
#34
George A. Olah, Alain Goeppert, and G. K. Surya Prakash. - Third, updated and enlarged edition. - Weinheim : Wiley-VCH, [2018]
Completely revised and updated, the third edition of this bestseller discusses the concept and ongoing development of using methanol and derived dimethyl ether as a transportation fuel, energy storage medium, and as a chemical raw material to replace fossil fuels. The contents have been expanded by 35% with new and up to date coverage on energy storage, methanol from biomass and waste products, as well as on carbon dioxide capture and recycling.
Signatur: 51912
u:search: https://ubdata.univie.ac.at/AC15195059
#35
Matej Pavšič. - New Jersey ; London ; Singapore : World Scientific, [2020]
The history is full of misconceptions that opposed the progress of physics. After having pointed out that misconceptions have been common in the history of physics, it is argued that they must be present today as well. In fact, it is now commonly being realized that in the last forty years there has been no significant progress in the fundamental theoretical physics. A reason certainly lies in certain stumbling blocks on our way towards the unification of interaction and of gravity with quantum mechanics.
Signatur: 51791
u:search: https://ubdata.univie.ac.at/AC15737283
#36
Tom Rother. - Cham, Switzerland : Springer, [2020]
• Provides a clear overview of currently available solution techniques for a variety of scattering problems of practical interest • Shows how the numerical effort can be dramatically reduced using iterative solutions, without anysignificant loss of accuracy • Provides Python programs which can be used as a starting point and adapted to fit readers’ own scattering problems • Offers an essential introduction to scattering problems, ideally suited for graduate-level university courses
Signatur: 51900
u:search: https://ubdata.univie.ac.at/AC15746108
#37
D.A. Rowlands. - Bellingham, Washington, USA : SPIE Press, [2020]. - (SPIE field guides volume FG46)
This ’Field Guide’ provides a concise summary of the photographic imaging chain and explains the connections between the science and photographic practice. It summarizes the fundamental optics required for understanding photographic formulae. The relationship between the photometric exposure distribution at the sensor plane and the resulting digital raw data produced by the camera is described, as are the steps required to convert raw data into an output color image for a display.
Signatur: 50120
u:search: https://ubdata.univie.ac.at/AC15684777
#38
Karl Svozil. - New Jersey ; Singapore ; London : World Scientific, 2020
This book contains very explicit proofs and demonstrations through examples for a comprehensive introduction to the mathematical methods of theoretical physics. It also combines and unifies many expositions of this subject, suitable for readers with interest in experimental and applied physics.
Signatur: 51564
u:search: https://ubdata.univie.ac.at/AC15736012
#39
Richard J.D. Tilley. - 2nd edition. - Hoboken John : Wiley & Sons, Inc., [2020]
Written in a friendly, non-mathematical style, the updated second edition of ’Crystals and Crystal Structures’ offers a comprehensive exploration of the key elements of crystals and crystal structures. Starting with the basics, it includes information on multiple areas of crystallography, including modulated structures, quasicrystals and protein crystallography, and interdisciplinary applications as diverse as the relationship between physical properties and symmetry. The book contains a variety of problems and exercises.
Signatur: 51570
u:search: https://ubdata.univie.ac.at/AC15702603
#40
Richard J.D. Tilley. - Third edition. - Hoboken, NJ : Wiley, 2020
The revised third edition of ’Colour and the Optical Properties of Materials’ focuses on the ways that colour is produced, both in the natural world and in a wide range of applications. The expert author offers an introduction to the science underlying colour and optics and explores many of the most recent applications. The text contains new or extended sections on photonic crystals, holograms, flat lenses, super-resolution optical microscopy and modern display technologies.
Signatur: 51798
u:search: https://ubdata.univie.ac.at/AC15745930
#41
Ivo van Vulpen. - New Haven ; London : Yale University Press, [2020]
Enjoy Van Vulpen’s accessible explanation of the history of particle physics and of concepts like quantum mechanics and relativity, and ponder his inquiries regarding the search for new particles (to explain dark matter), a new force (to combine the existing fundamental forces), and new phenomena (undiscovered dimensions of space). This is a lively account of work at the world’s highest-energy particle accelerator, with inspiring personal reflections on humanity’s discoveries deeper and deeper into the world of the very small.
Signatur: 51806
u:search: https://ubdata.univie.ac.at/AC16054228
#42
Argonne National Laboratory. - Chicago, Ill. : Office of Science, [2019]. - (ANL-19/27 Vol. 1)
The annual report – research and engineering highlights – of the advanced photon source at Argonne National Laboratory.
Signatur: 43498
u:search: https://ubdata.univie.ac.at/AC03815730
#43
verfasst von Mag. Dr. Nadia Abdelbary. - Wien : Universität Wien, 2019
Diplomarbeit, Universität Wien. Fakultät für Chemie.
Signatur: HS-1397
u:search: https://ubdata.univie.ac.at/AC16057873
Auch online verfügbar: https://othes.univie.ac.at/60619/
#44
verfasst von Adriano Bauer. - Wien : Universität Wien, 2020
Dissertation, Universität Wien. Fakultät für Chemie.
Signatur: HS-1375
u:search: https://ubdata.univie.ac.at/AC16085547
Auch online verfügbar: https://othes.univie.ac.at/61620/
#45
verfasst von Samira Chizzali, BSc. - Wien : Universität Wien, 2019
Masterarbeit, Universität Wien. Fakultät für Chemie.
Signatur: HS-1390
u:search: https://ubdata.univie.ac.at/AC16115012
#46
verfasst von Isabella Maria Fischer BSc. - Wien : Universität Wien, 2020
Masterarbeit, Universität Wien. Fakultät für Chemie.
Signatur: HS-1374
u:search: https://ubdata.univie.ac.at/AC16066012
Auch online verfügbar: https://othes.univie.ac.at/61272/
#47
verfasst von Mag. Dr. rer. nat. Cornelia Gänger. - Wien : Universität Wien, 2020
Diplomarbeit, Universität Wien. Fakultät für Chemie.
Signatur: HS-1376
u:search: https://ubdata.univie.ac.at/AC16082833
Auch online verfügbar: https://othes.univie.ac.at/61524/
#48
verfasst von Dipl.-Ing.in (FH) Susanne Hammerschmid. - Wien : Universität Wien, 2020
Diplomarbeit, Universität Wien. Fakultät für Chemie.
Signatur: HS-1379
u:search: https://ubdata.univie.ac.at/AC16069076
#49
verfasst von Jörg Heider BSc. - Wien : Universität Wien, 2020
Masterarbeit, Universität Wien. Fakultät für Chemie.
Signatur: HS-1380
u:search: https://ubdata.univie.ac.at/AC16107007
#50
verfasst von Katharina Hohenwallner BSc. - Wien : Universität Wien, 2020
Masterarbeit, Universität Wien. Fakultät für Chemie.
Signatur: HS-1398
u:search: https://ubdata.univie.ac.at/AC16126670
#51
verfasst von Gabriel Kiesenhofer BSc. - Wien : Universität Wien, 2020
Masterarbeit, Universität Wien. Fakultät für Chemie.
Signatur: HS-1388
u:search: https://ubdata.univie.ac.at/AC16126662
#52
verfasst von Michaela Maria Knapp BEd. - Wien : Universität Wien, 2020
Masterarbeit, Universität Wien. Fakultät für Chemie.
Signatur: HS-1386
u:search: https://ubdata.univie.ac.at/AC16122633
#53
verfasst von Anett Kovács, BSc. - Wien : Universität Wien, 2020
Masterarbeit, Universität Wien. Fakultät für Chemie.
Signatur: HS-1383
u:search: https://ubdata.univie.ac.at/AC16074109
#54
verfasst von Leo Johannes Krammer, BSc. - Wien : Universität Wien, 2020
Masterarbeit, Universität Wien. Fakultät für Chemie.
Signatur: HS-1387
u:search: https://ubdata.univie.ac.at/AC16122666
Auch online verfügbar: https://othes.univie.ac.at/62661/
#55
verfasst von Raphael Stefan Lampl, BSc. - Wien : Universität Wien, 2020
Masterarbeit, Universität Wien. Fakultät für Chemie.
Signatur: HS-1382
u:search: https://ubdata.univie.ac.at/AC16085336
Auch online verfügbar: https://othes.univie.ac.at/61580/
#56
verfasst von Fabian Laudenbach MSc BSc. - Wien : Universität Wien, 2018
Dissertation, Universität Wien. Fakultät für Physik.
Signatur: DissD.5383
u:search: https://ubdata.univie.ac.at/AC15277526
#57
verfasst von Dott.ssa.mag. Dott.ssa Francesca Nerattini. - Wien : Universität Wien, 2018
Dissertation, Universität Wien. Fakultät für Physik.
Signatur: DissD.5382
u:search: https://ubdata.univie.ac.at/AC15230646
#58
verfasst von Christof Andreas Reinold Plessl, MSc. - Wien : Universität Wien, 2018
Dissertation, Universität Wien. Fakultät für Chemie.
Signatur: HS-1370
u:search: https://ubdata.univie.ac.at/AC15207938
#59
verfasst von Martin Pree. - Wien : Universität Wien, 2020
Diplomarbeit, Universität Wien. Fakultät für Chemie.
Signatur: HS-1394
u:search: https://ubdata.univie.ac.at/AC16070590
#60
verfasst von Stefanie Maria Primisser. - Wien : Universität Wien, 2020
Diplomarbeit, Universität Wien. Fakultät für Chemie.
Signatur: HS-1377
u:search: https://ubdata.univie.ac.at/AC16067158
Auch online verfügbar: https://othes.univie.ac.at/61317/
#61
verfasst von Matthias Riepl BSc. - Wien : Universität Wien, 2019
Masterarbeit, Universität Wien. Fakultät für Chemie.
Signatur: HS-1368
u:search: https://ubdata.univie.ac.at/AC15515755
#62
verfasst von Mag.ª Christine Ripper. - Wien : Universität Wien, 2020
Diplomarbeit, Universität Wien. Fakultät für Chemie.
Signatur: HS-1393
u:search: https://ubdata.univie.ac.at/AC16116240
#63
verfasst von Stefanie Rubenzucker, BSc. - Wien : Universität Wien, 2020
Masterarbeit, Universität Wien. Fakultät für Chemie.
Signatur: HS-1372
u:search: https://ubdata.univie.ac.at/AC16069942
#64
verfasst von Erwin Schaier, BSc. - Wien : Universität Wien, 2020
Masterarbeit, Universität Wien. Fakultät für Chemie.
Signatur: HS-1396
u:search: https://ubdata.univie.ac.at/AC16111328
Auch online verfügbar: https://othes.univie.ac.at/61950/
#65
verfasst von Margot Schiller. - Wien : Universität Wien, 2020
Diplomarbeit, Universität Wien. Fakultät für Chemie.
Signatur: HS-1384
u:search: https://ubdata.univie.ac.at/AC16074704
#66
verfasst von Daniela Unterleuthner, MSc. - Wien : Universität Wien, 2020
Dissertation, Universität Wien. Fakultät für Chemie.
Signatur: HS-1392
u:search: https://ubdata.univie.ac.at/AC16118590
Auch online verfügbar: https://othes.univie.ac.at/62328/
#67
verfasst von Ana Vidakovic BSc. - Wien : Universität Wien, 2020
Masterarbeit, Universität Wien. Fakultät für Chemie.
Signatur: HS-1389
u:search: https://ubdata.univie.ac.at/AC16122113
#68
verfasst von Christina Wagner BSc. - Wien : Universität Wien, 2020
Masterarbeit, Universität Wien. Fakultät für Chemie.
Signatur: HS-1395
u:search: https://ubdata.univie.ac.at/AC16126668
#69
verfasst von Christine Wannerer. - Wien : Universität Wien, 2020
Diplomarbeit, Universität Wien. Fakultät für Chemie.
Signatur: HS-1385
u:search: https://ubdata.univie.ac.at/AC16070596
#70
verfasst von Dipl.-Ing. Lisa Wiesinger, BSc. - Wien : Universität Wien, 2020
Dissertation, Universität Wien. Fakultät für Chemie.
Signatur: HS-1391
u:search: https://ubdata.univie.ac.at/AC16117355
#71
verfasst von Anja Wittig. - Wien : Universität Wien, 2020
Dissertation, Universität Wien. Fakultät für Chemie.
Signatur: HS-1371
u:search: https://ubdata.univie.ac.at/AC16068916
#72
von Victoria Anna Zabel BSc. - Wien : Universität Wien, 2020
Masterarbeit, Universität Wien. Fakultät für Chemie.
Signatur: HS-1373
u:search: https://ubdata.univie.ac.at/AC16066029
Auch online verfügbar: https://othes.univie.ac.at/61165/
#73
verfasst von Sarah Julia Zachl. - Wien : Universität Wien, 2020
Diplomarbeit, Universität Wien. Fakultät für Chemie.
Signatur: HS-1378
u:search: https://ubdata.univie.ac.at/AC16079744
Auch online verfügbar: https://othes.univie.ac.at/61525/
#74
verfasst von Mathias Zaunschirm, Bakk. rer. nat. MSc. - Wien : Universität Wien, 2018
Dissertation, Universität Wien. Fakultät für Chemie.
Signatur: HS-1369
u:search: https://ubdata.univie.ac.at/AC15215470
#75
verfasst von Hao Qi Zhang BSc. - Wien : Universität Wien, 2020
Masterarbeit, Universität Wien. Fakultät für Chemie.
Signatur: HS-1381
u:search: https://ubdata.univie.ac.at/AC16112282
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