literature.bib

@book{Yariv1989,
isbn={0471609978},
isbn={0471617717},
author={Yariv, Amnon},
title={Quantum electronics},
edition={3. ed.},
address={New York},
publisher={Wiley},
year={1989},
}

@Book{Parson,
author = {William W. Parson},
title = {Modern optical spectroscopy},
publisher = {Springer},
year = {2015},
doi = {10.1007/978-3-662-46777-0}
}

@book{SalehTeich1991,
isbn={0471839655},
author={Saleh, Bahaa E. A. and Teich, Malvin C.},
title={Fundamentals of photonics},
address={New York, NY [u.a.]},
publisher={Wiley},
year={1991},
doi = {10.1002/0471213748}
}



@Book{Fox,
author = {Mark Fox},
title = {Quantum optics},
publisher = {Oxford University Press},
year = {2007},
}


@Book{Haken_wolf_II,
author = { H. Haken and H.C. Wolf},
title = {Molekülphysik und Quantenchemie},
publisher = {Springer},
year = {2003}
}


@Book{Haken_wolf_I,
author = { H. Haken and H.C. Wolf},
title = {Atom- und Quantenphysik},
publisher = {Springer},
year = {2001}
}


@Book{bransden_joachain,
author = { B. H. Bransden and C. J. Joachain},
title = {Physics of atoms and molecules},
publisher = {Longman},
year = {1996}
}


@Book{Loudon,
author = { Rodney Loudon},
title = {The quantum theory of light},
publisher = {Oxford University Press},
year = {2001}
}

@Book{CT,
author = { Claude Cohen-Tannoudji and Bernard Diu and Franck Laloë },
title = {Quantum Mechanics},
publisher = {Wiley},
year = {1977}
}

@book{Kuzmany,
author={Kuzmany, Hans},
title={Solid-state spectroscopy},
subtitle={An introduction},
edition={Second edition},
address={Heidelberg},
publisher={Springer},
year={2009},
}

@book{Nolting-ED,
author = {Nolting, Wolfgang},
title = {{Theoretical Physics 3 Electrodynamics}},
publisher = {Springer},
year = {2016},
isbn = {9783319401676},
doi = {10.1007/978-3-319-40168-3}
}

@book{Jackson-ED,
isbn={9780471427643},
author={Jackson, John David},
title={Classical electrodynamics},
edition={3. ed.},
address={New York [u.a.]},
publisher={Wiley},
year={1999}
}

@inproceedings{knoester-book,
title = "Optical properties of molecular aggregates",
author = "J. Knoester",
year = "2002",
pages = "149 -- 186",
booktitle = "Proceedings of the International School of Physics 'Enrico Fermi' ",
series ="Volume 149: Organic Nanostructures: Science and Applications",
publisher = "IOS Press",
doi = {10.3254/978-1-61499-005-5-149}
}

@book{Rand2016,
isbn={9780191817830},
author={Rand, Stephen C.},
title={Lectures on light},
subtitle={nonlinear and quantum optics using the density matrix},
edition={Second edition},
publisher={Oxford University Press},
year={2016},
doi={10.1093/acprof:oso/9780198757450.001.0001},
}

@book{KoehlerBaessler2015,
author={Köhler, Anna and Bässler, Heinz},
title={Electronic processes in organic semiconductors},
address={Weinheim},
publisher={Wiley-VCH},
year={2015},
doi={10.1002/9783527685172},
}

@book{Lakowicz2010,
author={Lakowicz, Joseph R.},
title={Principles of fluorescence spectroscopy},
address={New York, NY},
publisher={Springer},
year={2010},
doi = {10.1007/978-0-387-46312-4}
}


@book{Demtroeder_laser,
author={Demtröder, Wolfgang},
title={Laser spectroscopy 1},
address={Berlin [u.a.]},
publisher={Springer},
year = {2014},
doi = {10.1007/978-3-642-53859-9}
}


@book{Hopf86,
author={Hopf, Frederic A. and Stegeman, George I.},
title={Applied classical electrodynamics: Nonlinear optics},
address={New York},
publisher={Wiley},
year={1986},
}


@book{Rulliere2005,
title={Femtosecond laser pulses},
subtitle={principles and experiments},
edition={2. ed.},
address={New York, NY},
publisher={Springer},
year={2005},
pages={XVI, 426 S.},
editor={Rullière, Claude},
doi = {10.1007/b137908}
}

@book{DielsRudolph1996,
isbn={0122154924},
author={Diels, Jean-Claude and Rudolph, Wolfgang},
title={Ultrashort laser pulse phenomena},
subtitle={fundamentals, techniques, and applications on a femtosecond time scale},
address={San Diego [u.a.]},
publisher={Academic Press},
year={1996},
doi = {10.1016/B978-0-12-215493-5.X5000-9}
}


@book{Demtröder_AMP,
isbn={9783662555217},
isbn={3662555212},
author={Demtröder, Wolfgang},
title={Atoms, molecules and photons},
subtitle={an introduction to atomic-, molecular- and quantum physics},
edition={Third edition},
address={Berlin},
publisher={Springer},
year={2018},
doi = {10.1007/978-3-662-55523-1}
}

@book{Demtröder_ep3,
isbn={9783662490945},
author={Demtröder, Wolfgang},
title={Experimentalphysik},
subtitle={Atome, Moleküle und Festkörper},
volume={3},
edition={5., neu bearbeitete und aktualisierte Auflage},
address={Berlin [u.a.]},
publisher={Springer},
year={2016},
doi={10.1007/978-3-662-49094-5},
}

@book{Demtröder_molekuelphysik,
isbn={9783486706789},
isbn={9783486714890},
author={Demtröder, Wolfgang},
title={Molekülphysik},
subtitle={theoretische Grundlagen und experimentelle Methoden},
edition={2., überarb. und erw. Aufl.},
address={München},
publisher={Oldenbourg},
year={2013},
pages={XVI, 487 S.},
doi={10.1524/9783486714890}
}

@book{Atkins,
isbn={9780198769866},
author={Atkins, Peter W.},
title={Atkins' physical chemistry},
edition={Eleventh edition},
address={Oxford},
publisher={Oxford University Press},
year={2018},
}

@book{McQuarrie2008,
isbn={9781891389504},
author={McQuarrie, Donald A.},
title={Quantum chemistry},
edition={2. ed.},
address={Sausalito, Calif.},
publisher={Univ. Science Books},
year={2008},
pages={XIII, 690 S.},
}


@article{Li_2011_hcl,
title = "Direct fit of experimental ro-vibrational intensities to the dipole moment function: Application to HCl",
journal = "Journal of Quantitative Spectroscopy and Radiative Transfer",
volume = "112",
number = "10",
pages = "1543 - 1550",
year = "2011",
issn = "0022-4073",
doi = "10.1016/j.jqsrt.2011.03.014",
author = "G. Li and I.E. Gordon and P.F. Bernath and L.S Rothman",
}


@MastersThesis{Segelstein_water,
author = {Segelstein, David J.},
title = {The complex refractive index of water},
school = {University of Missouri--Kansas City},
year = {1981},
url = {http://hdl.handle.net/10355/11599}
}

@article{Maki_1995_HCN,
title = "Intensities of Hot-Band Transitions: HCN Hot Bands",
journal = "Journal of Molecular Spectroscopy",
volume = "171",
number = "2",
pages = "420 - 434",
year = "1995",
issn = "0022-2852",
doi = "10.1006/jmsp.1995.1130",
author = "A. Maki and W. Quapp and S. Klee"
}

@article{Liu14_OE_N2,
author = {Fuchao Liu and Fan Yi},
journal = {Opt. Express},
keywords = {Atmospheric and oceanic optics ; Remote sensing and sensors ; Temperature; Lidar; Elastic scattering; Laser light; Lidar; Nd:YAG lasers; Raman spectroscopy; Resonance fluorescence},
number = {23},
pages = {27833--27844},
publisher = {OSA},
title = {Lidar-measured atmospheric N2 vibrational-rotational Raman spectra and consequent temperature retrieval},
volume = {22},
year = {2014},
doi = {10.1364/OE.22.027833}
}

@book{HertelSchulz-2,
author={Hertel, Ingolf V. and Schulz, Claus-Peter},
title={Atome, Moleküle und optische Physik},
volume={2},
address={Berlin [u.a.]},
publisher={Springer},
year={2010},
doi={10.1007/978-3-642-11973-6},
}


@article{ParticleDataGroup20,
    author = {{Particle Data Group} },
    title = "{Review of Particle Physics}",
    journal = {Progress of Theoretical and Experimental Physics},
    volume = {2020},
    number = {8},
    year = {2020},
    month = {08},
    issn = {2050-3911},
    doi = {10.1093/ptep/ptaa104},
}



@book{Nolting-QM,
isbn={978-3-540-26035-6},
isbn={9783540260356},
issn={0937-7433},
issn={09377433},
author={Nolting, Wolfgang},
title={Grundkurs Theoretische Physik 5/2: Quantenmechanik - Methoden und Anwendungen},
address={Berlin, Heidelberg},
publisher={Springer Berlin Heidelberg},
year={2006},
series={Springer-Lehrbuch},
doi = {10.1007/978-3-540-47616-0}
}


@book{Hunklinger2014,
isbn={9783486858501},
author={Hunklinger, Siegfried},
title={Festkörperphysik},
edition={4. aktualisierte Auflage},
address={München},
publisher={De Gruyter},
year={2014},
doi={10.1524/9783486858501},
}


@book{AshcroftMermin2013,
isbn={9783486713015},
author={Ashcroft, Neil W. and Mermin, N. David},
title={Festkörperphysik},
address={München},
publisher={Oldenbourg},
year={2013}
}

@book{Kittel2013,
isbn={9783486597554},
author={Kittel, Charles},
title={Einführung in die Festkörperphysik},
edition={15., unveränd. Aufl.},
address={München},
publisher={Oldenbourg},
year={2013}
}

@book{Bergmann-Schaefer-FK,
isbn={9783110174854},
title={Bergmann/Schäfer: Lehrbuch der Experimentalphysik},
volume={6: Festkörper},
edition={2., überarb. Aufl.},
address={Berlin [u.a.]},
publisher={de Gruyter},
year={2005},
editor={Kassing, Reinhold},
editor={Blügel, Stefan},
doi= {10.1515/9783110198157}
}

@book{Butz2011,
isbn={9783834882950},
author={Butz, Tilman},
title={Fouriertransformation für Fußgänger},
publisher={Springer},
year={2011},
doi={10.1007/978-3-8348-8295-0},
}

@Article{Strauch_gaas,
author = {Strauch, D. and Dorner, B.}, 
title = {Phonon dispersion in GaAs}, 
journal = {Journal of Physics: Condensed Matter}, 
volume = {2}, 
number = {6}, 
pages = {1457}, 
year = {1990}, 
abstract = {The authors have determined the phonon dispersion curves in GaAs at 12 K for wavevectors along the six directions Gamma-(Delta)-X-(Sigma)-Gamma-(Lambda)-LX-(Z)-W-(Q)-L by high-precision inelastic neutron scattering. Various existing lattice-dynamical models are …}, 
doi = {10.1088/0953-8984/2/6/006}, 
location = {}, 
keywords = {}}




@Article{Svensson_cu,
author = {Svensson, E. C. and Brockhouse, B. N. and Rowe, J. M. }, 
title = {Crystal dynamics of copper}, 
journal = {Physical Review}, 
volume = {155}, 
number = {3}, 
pages = {619}, 
year = {1967}, 
abstract = {The frequency/wave-vector dispersion relation for the symmetry directions [00 ζ],[0 ζ ζ],[ζ ζ ζ], and [0 ζ 1] in copper at room temperature has been determined by inelastic neutron scattering. Interplanar and atomic force constants have been obtained. First-neighbor …}, 
doi = {10.1103/PhysRev.155.619}, 
keywords = {}}

@Book{Data_notebook,
title = {Selected Cryogenic Data Notebook},
publisher = {Brookhaven National Laboratory },
year = {1980},
url = {https://www.bnl.gov/magnets/Staff/Gupta/cryogenic-data-handbook/},
volume = {Section VIII},
}


@book{Okhotin72_si,
author = { A. S. Okhotin and  A. S. Pushkarskii and V. V. Gorbachev,},
title = {Thermophysical Properties of Semiconductors},
publisher = {'Atom' Publ. House, Moscow (in Russian)},
year = {1972},
url = {http://www.ioffe.ru/SVA/NSM/Semicond/Si/thermal.html}
}

@Article{dolling66_si,
author = {Dolling, G. and Cowley, R. A.}, 
title = {The thermodynamic and optical properties of germanium, silicon, diamond and gallium arsenide}, 
journal = {Proceedings of the Physical Society (1958-1967)}, 
volume = {88}, 
number = {2}, 
pages = {463}, 
year = {1966}, 
doi = {10.1088/0370-1328/88/2/318}, 
keywords = {}}

@Article{Flubacher59_si,
author = {Flubacher, P. and Leadbetter, A. J. and Morrison, J. A.}, 
title = {The heat capacity of pure silicon and germanium and properties of their vibrational frequency spectra}, 
journal = {Philosophical Magazine}, 
volume = {4}, 
number = {39}, 
pages = {273–294}, 
year = {1959}, 
abstract = {}, 
doi = {10.1080/14786435908233340}, 
keywords = {}}


@Article{RollinsJr1964,
author = {Rollins Jr, Fred R and Taylor, Lyle H and Todd Jr, Paul H}, 
title = {Ultrasonic study of three-phonon interactions. II. Experimental results}, 
journal = {Physical Review}, 
volume = {136}, 
number = {3A}, 
pages = {A597}, 
year = {1964}, 
doi = {10.1103/PhysRev.136.A597}
 }

@Article{Glassbrenner1964,
author = {Glassbrenner, C Jo and Slack, Glen A}, 
title = {Thermal conductivity of silicon and germanium from 3 K to the melting point}, 
journal = {Physical review}, 
volume = {134}, 
number = {4A}, 
pages = {A1058}, 
year = {1964}, 
doi = {10.1103/PhysRev.134.A1058 }
 }


@Article{Jackson1970,
author = {Jackson, Howard E and Walker, Charles T and McNelly, Thomas F}, 
title = {Second sound in NaF}, 
journal = {Phys. Rev. Lett.}, 
volume = {25}, 
number = {1}, 
pages = {26}, 
year = {1970}, 
 }

@misc{lippitz_epc1,
  author       = {Markus Lippitz},
  title        = {{Lecture notes 'Molekülphysik und Festkörperphysik 
                   I'}},
  year         = 2022,
  publisher    = {Zenodo},
  version      = {v22.2},
  doi          = {10.5281/zenodo.6124372},
  url          = {https://doi.org/10.5281/zenodo.6124372},
  note         = {CC-BY-SA 4.0}
}

@book{Fliessbach_statistik,
  author         = {Thorsten Fließbach},
  publisher      = {Springer},
  title          = {Statistische Physik},
  year           = {2018},
  doi = {10.1007/978-3-662-58033-2}
}

@book{Kittel_FK,
   author={Kittel, Charles},
   editor={Hunklinger, Siegfried},
   title={Einf{\"u}hrung in die Festk{\"o}rperphysik},
   publisher={Oldenbourg},
   year={2006},
   edition={14.},
   ISBN={9783486577235},
}


@book{Kopitzki_FK,
   author={Kopitzki, Konrad},
   editor={Herzog, Peter},
   title={Einf{\"u}hrung in die Festk{\"o}rperphysik},
   publisher={Springer},
   year={2017},
   edition={7.},
   ISBN={9783662535783},
   doi = {10.1007/978-3-662-53578-3}
}


@book{Gross_FK,
   author={Gross, Rudolf and Marx, Achim},
   title={Festk{\"o}rperphysik},
   publisher={De Gruyter},
   year={2023},
   edition={4.},
   ISBN={9783110782349},
   doi = {10.1515/9783110782394}
}

@misc{Polakovic_cmpm3,
   author = {Tomas Polakovic},
   title = {Computational Physics for the Masses. Part 3: Solid Stuff},
   url = {https://tpolakovic.github.io/posts/cmpm3/},
   year = {2022},
   note = {CC-BY-NC 4.0}
}

@book{Czycholl_theo_FK1,
   author={Czycholl, Gerd},
   title={Theoretische Festk{\"o}rperphysik, Band 1},
   publisher={Springer },
   year={2016},
   edition={4. Aufl.},
   ISBN={9783662471418},
   doi = {10.1007/978-3-662-47141-8}
}


@book{Czycholl_theo_FK2,
   author={Czycholl, Gerd},
   title={Theoretische Festk{\"o}rperphysik, Band 2},
   publisher={Springer },
   year={2017},
   edition={4. Aufl.},
   ISBN={9783662537008},
   doi = {10.1007/978-3-662-53701-5}
}


@Article{Rayne1956,
author = {Rayne, JA}, 
title = {The Heat Capacity of Copper Below 4.2 °K}, 
journal = {Aust. J. Phys.}, 
volume = {9}, 
number = {2}, 
pages = {189--197}, 
year = {1956}, 
abstract = {The heat capacity of copper has been measured below 4? 2° K with a calorimeter using a mechanical heat switch. The effects of changes in the chemical and physical state of the copper have been investigated with a view to understanding discrepancies between the results of previous workers.}, 
doi = {10.1071/PH560189},
}

@Article{Segall1961,
author = {Segall, Benjamin}, 
title = {Energy bands of aluminum}, 
journal = {Physical Review}, 
volume = {124}, 
number = {6}, 
pages = {1797}, 
year = {1961}, 
abstract = {… the band structure of solids was discussed in some detail. As … realistic problem of the band structure of aluminum. Ham’ has … addition to the energies of the aluminum energy bands at a …}, }


@Article{Hust1984,
author = {Hust, Jerome G and Lankford, Alan B}, 
title = {Thermal conductivity of aluminum, copper, iron, and tungsten for temperatures from 1 K to the melting point}, 
year = {1984}, 
publisher = {National Bureau of Standards, Boulder, CO },
journal = {NBSIR 84-3007},
url = {https://www.osti.gov/biblio/6225458}, 
}

@book{Singleton_band_theory,
   author={Singleton, John},
   title={Band Theory and Electronic Properties of Solids},
   publisher={Oxford Univ. Press},
   year={2001},
   ISBN={978-0-19-105746-5},
}

@book{Simon_solid_state_basics,
   author={Simon, Steven H.},
   title={The Oxford solid state basics},
   publisher={Oxford Univ. Press},
   year={2013},
   ISBN={9780199680764},
   url={https://podcasts.ox.ac.uk/series/oxford-solid-state-basics}
}


@book{yu_cardona,
   author={Yu, Peter Y. and Cardona, Manuel},
   title={Fundamentals of semiconductors},
   publisher={Springer},
   year={2010},
   ISBN={9783642007095},
   doi={10.1007/b137661}
}

@article{Choy00_fermi_surfaces,
  author          = { T.-S. Choy and J. Naset and J. Chen and S. Hershfield and  C. Stanton},
  journal         = {Bulletin of The American Physical Society},
  number          = {1},
  title           = { A database of fermi surface in virtual reality modeling language (vrml)},
  volume          = {45},
  year            = {2000},
  pages = {L36-42}, 
  url = {  http://www.phys.ufl.edu/fermisurface/}
}

@article{Sullivan68_beryllium,
  title = {Steady-State, ac-Temperature Calorimetry},
  author = {Sullivan, Paul F. and Seidel, G.},
  journal = {Phys. Rev.},
  volume = {173},
  issue = {3},
  pages = {679--685},
  year = {1968},
   doi = {10.1103/PhysRev.173.679},
  url = {https://link.aps.org/doi/10.1103/PhysRev.173.679}
}

@Article{Klitzing1980,
author = {Klitzing, K and Dorda, G and Pepper, M}, 
title = {New method for high-accuracy determination of the fine-structure constant based on quantized Hall resistance}, 
journal = {Phys. Rev. Lett.}, 
volume = {45}, 
number = {6}, 
pages = {494-497}, 
year = {1980},
doi = {10.1103/PhysRevLett.45.494} }

@Article{Dresselhaus1955,
author = {Dresselhaus, G and Kip, AF and Kittel, C}, 
title = {Cyclotron resonance of electrons and holes in silicon and germanium crystals}, 
journal = {Physical Review}, 
volume = {98}, 
number = {2}, 
pages = {368}, 
year = {1955}, 
doi = {10.1103/PhysRev.98.368},
abstract = {An experimental and theoretical discussion is given of the results of cyclotron resonance experiments on charge carriers in silicon and germanium single crystals near 4 K. A description is given of the light-modulation technique which gives good signal-to-noise ratios. Experiments with circularly polarized microwave radiation are described. A complete study of anisotropy effects is reported. The electron energy surfaces in germanium near the band edge are prolate spheroids oriented along< 111> axes with longitudinal mass …}, }

@article{Klitzing1984,
title = {The quantized hall effect},
journal = {Physica B+C},
volume = {126},
number = {1},
pages = {242-249},
year = {1984},
issn = {0378-4363},
doi = {10.1016/0378-4363(84)90170-0},
author = {Klaus v. Klitzing},
abstract = {The structures typical for the quantized Hall effect (plateaus in magneto-transport measurements) are only observable, if the thermal energy kT is smaller than the energy gaps in the spectrum of a two-dimensional electron gas in a strong magnetic field. This paper discuesses phenomena related to the quantized Hall effect which are influenced by the temperature, and the data demonstrate that more and more information is obtained with decreasing temperature even at temperatures below 0.1 K.}
}


@incollection{Johnson1967,
title = {Absorption near the Fundamental Edge},
editor = {R.K. Willardson and Albert C. Beer},
series = {Semiconductors and Semimetals},
publisher = {Elsevier},
volume = {3},
pages = {153-258},
year = {1967},
issn = {0080-8784},
doi = {https://doi.org/10.1016/S0080-8784(08)60318-X},
url = {https://www.sciencedirect.com/science/article/pii/S008087840860318X},
author = {Earnest J. Johnson},
abstract = {Publisher Summary
The most direct way of observing the fundamental edge is by determining the absorption from transmission measurements and this is generally the procedure used. Other less direct methods can yield supplementary information. The interpretation of the signal obtained in a photoconductivity measurement depends upon the thickness of the sample relative to the penetration depth. In the thin-sample limit, the signal is proportional to the part of the absorption that creates free carriers. An additional method of studying the fundamental edge is by observing reflection. For such measurements, one must be careful how one prepares the reflecting surface. Reflection can be used where transmission measurements are impossible due to excessive background absorption. This chapter reviews the results of optical studies on the absorption edges of the III-V compounds and reviews the implications of these results on the band structure of the compounds concerned. The chapter also also reviews the information about excitons, phonons, and impurities obtained by optical studies near the absorption edge.}
}

@Article{Macfarlane1955,
author = {Macfarlane, GG and Roberts, V}, 
title = {Infrared absorption of silicon near the lattice edge}, 
journal = {Physical Review}, 
volume = {98}, 
number = {6}, 
pages = {1865}, 
year = {1955}, 
doi = {https://doi.org/10.1103/PhysRev.98.1865},
abstract = {… crystalline specimen of 100 ohm-cm silicon in the neighborhood of the lattice edge at temperatures from 20'K to 3330'K. High resolution was obtained by the use of glass prisms, the method being to measure the transmitted radiation intensity with and without the specimen present, to deduce the reAection coefFicient from the constant value of the … From the known values of the elastic constants of silicon' and the theory of vibrations of the diamond lattice, ` we estimate that the conduction band minima occur at a momentum …}, }

@Article{Conwell1952,
author = {Conwell, Esther M}, 
title = {Properties of silicon and germanium}, 
journal = {Proceedings of the IRE}, 
volume = {40}, 
number = {11}, 
pages = {1327--1337}, 
year = {1952}, 
doi = {10.1109/JRPROC.1952.273956},
abstract = {… information on those fundamental properties of germanium and silicon which are of device interest, currently or potentially. Electrical properties, especially carrier density and mobility, …}, }



@Article{Meissner1933,
author = {Meissner, Walther and Ochsenfeld, Robert}, 
title = {{Ein neuer Effekt bei Eintritt der Supraleitfähigkeit}}, 
journal = {Naturwissenschaften}, 
volume = {21}, 
number = {44}, 
pages = {787--788}, 
year = {1933}, 
doi = {10.1007/bf01504252},
abstract = {Unter Mitwirkung Yon MAX HARTMANN,~/iAX V. LAUE, CARL NEUBERG, ARTHUR ROSENPIEIM und MAX VOLMER. Ffir die kurzen Originalmitteilungen ist ansschlieBlich der Verfasser verantwortlich. Der Herausgeber bitteL i. im Manuskript der/~ urzen Orig@~ alm;, tte@ er~ eer~ oder in einem Begteitschreiben die Notwendigkeit einer bMdigen Yer6ffent! ichung an dieser Stelle zu begriZnder~, 2. die Mitteilungen auf einen}, }



@Article{Phillips1959,
author = {Phillips, Norman E}, 
title = {Heat capacity of aluminum between 0.1 K and 4.0 K}, 
journal = {Physical Review}, 
volume = {114}, 
number = {3}, 
pages = {676}, 
year = {1959}, 
doi = {10.1103/PhysRev.114.676},
abstract = {… the aluminum sample thermally isolated from the salt pill and heat capacity measurements … The aluminum sample was returnedto its original temperature at the end of each series by …}, }


@Article{Doll1961,
author = {Doll, Robert and Näbauer, M}, 
title = {Experimental proof of magnetic flux quantization in a superconducting ring}, 
journal = {Phys. Rev. Lett.}, 
volume = {7}, 
number = {2}, 
pages = {51}, 
year = {1961}, 
doi = {10.1103/PhysRevLett.7.51 },
abstract = {COVID-19 has impacted many institutions and organizations around the world, disrupting the progress of research. Through this difficult time APS and the Physical Review editorial office are fully equipped and actively working to support researchers by continuing to carry out all editorial and peer-review functions and publish research in the journals as well as minimizing disruption to journal access.We appreciate your continued effort and commitment to helping advance science, and allowing us to publish the best physics journals in the …}, }

@Article{Langenberg1966,
author = {Langenberg, DN and Scalapino, DJ and Taylor, BN}, 
title = {Josephson-type superconducting tunnel junctions as generators of microwave and submillimeter wave radiation}, 
journal = {Proceedings of the IEEE}, 
volume = {54}, 
number = {4}, 
pages = {560--575}, 
year = {1966}, 
doi = {10.1109/PROC.1966.4776},
abstract = {The use of Josephson-type superconducting tunnel junctions (two superconductors separated by a very thin insulating layer) as generators of radiation in the range 5 GHz to 1000 GHz is discussed. To this end, the results of recent experiments on the observation of X-band radiation from such junctions are presented, along with a complete discussion of the theory of such junctions. Their potential use as detectors, voltage sources, and harmonic multipliers is also discussed.}, }


@Article{Giaever1960,
author = {Giaever, Ivar}, 
title = {Energy gap in superconductors measured by electron tunneling}, 
journal = {Phys. Rev. Lett.}, 
volume = {5}, 
number = {4}, 
pages = {147}, 
year = {1960}, 
doi = {10.1103/PhysRevLett.5.147},
abstract = {2008 marked PRL's 50th anniversary. As part of the celebrations a collection of milestone Letters was started. The collection contains Letters that have made long-lived contributions to physics, either by announcing significant discoveries, or by initiating new areas of research.}, }


@Article{London1935,
author = {London, Fritz and London, Heinz}, 
title = {The electromagnetic equations of the supraconductor}, 
journal = {Proceedings of the Royal Society of London. Series A-Mathematical and Physical Sciences}, 
volume = {149}, 
number = {866}, 
pages = {71--88}, 
year = {1935}, 
doi = {10.1098/rspa.1935.0048},
abstract = {Electric currents are commonly believed to persist in a supra-conductor without being maintained by an electromagnetic field. Thus the relation between the field strength E and the current density J in a supraconductor has sometimes been described by means of an'' acceleration equation,'' of the form∆ J= E; A= m/ne 2.(1) This equation, which might replace Ohm; s law for supraconductors, simply expresses the influence of the electric part of the Lorentz force on freely movable electrons of the mass m and charge e, the number per cm3 …}, }


@Article{Jaklevic1965,
author = {Jaklevic, RC and Lambe, J and Mercereau, JE and Silver, AH}, 
title = {Macroscopic quantum interference in superconductors}, 
journal = {Physical Review}, 
volume = {140}, 
number = {5A}, 
pages = {A1628}, 
year = {1965}, 
doi = {10.1103/PhysRev.140.A1628},
abstract = {The Josephson effect allows supercurrents to flow through thin tunnel barriers separating two super-conductors. The dc critical current depends directly on the quantum phase difference of the superconducting wave function on the two sides of the barrier. This paper is an experimental study of interference phenomena in multiply connected superconductors utilizing Josephson tunneling. The results are a striking confirmation of the extensive phase coherence of the superconducting state. London's theory is used in conjunction with …}, }


@Article{Vandelft2008,
author = {Van Delft, Dirk}, 
title = {Little cup of helium, big science}, 
journal = {Physics Today}, 
volume = {61}, 
number = {3}, 
pages = {36--42}, 
year = {2008}, 
doi = {10.1063/1.2897948},
abstract = {… While the hydrogen liquefier faithfully turned out its 4 liters per hour, a pump throbbed away, maintaining a vacuum in the helium apparatus and removing impurities from the helium …}, }


@Article{Vandelft2010,
author = {Van Delft, Dirk and Kes, Peter}, 
title = {The discovery of superconductivity}, 
journal = {Physics today}, 
volume = {63}, 
number = {9}, 
pages = {38--43}, 
year = {2010}, 
doi = {10.1063/1.881517},
abstract = {… And that'sa pity because, the cover notwithstanding, notebook 56 does indeed announce the 1911 discovery of superconductivity (see figure 2). Translated, the entry reads, ``The …}, }

@Article{Kamerlingh_Onnes_1911,
 author = {Heike {Kamerling Onnes}},
 title = {Further experiments with Liquid Helium -- VI. On the Sudden Change in the Rate at which the Resistance
of Mercury Disappears.},
journal = {Leiden Communications},
volume = {124c},
pages = {267-271},
year = 1911
}

@book{Blundell_magnetism,
   author={Blundell, Stephen},
   title={Magnetism in condensed matter},
   publisher={Oxford Univ. Press},
   year={2006},
   ISBN={9780198505914},
}


@Article{Henry1952,
author = {Henry, Warren E}, 
title = {Spin paramagnetism of Cr$^{+++}$, Fe$^{+++}$, and Gd$^{+++}$ at liquid helium temperatures and in strong magnetic fields}, 
journal = {Physical Review}, 
volume = {88}, 
number = {3}, 
pages = {559}, 
year = {1952}, 
doi = {10.1103/PhysRev.88.559 },
abstract = {… a magnetic moment differential fiuxmeter as afunction of static magnetic fields for fixed values of temperatures in … The direction of observation was at an angle of 88 with respect to the …}, }


@Article{Shull1951,
author = {Shull, C Gi and Strauser, WA and Wollan, EO}, 
title = {Neutron diffraction by paramagnetic and antiferromagnetic substances}, 
journal = {Physical Review}, 
volume = {83}, 
number = {2}, 
pages = {333}, 
year = {1951}, 
doi = {10.1103/PhysRev.83.333},
abstract = {Neutron scattering and diffraction studies on a series of paramagnetic and antiferromagnetic substances are reported in the present paper. The paramagnetic diffuse scattering predicted by Halpern and Johnson has been studied, resulting in the determination of the magnetic form factor for Mn++ ions. From the form factor, the radial distribution of the electrons in the 3 d-shell of Mn++ has been determined, and this is compared with a theoretical distribution of Dancoff. Antiferromagnetic substances are shown to produce strong, coherent scattering …}, }

@Article{Spitzer1957,
author = {Spitzer, WG and Fan, HY}, 
title = {Determination of optical constants and carrier effective mass of semiconductors}, 
journal = {Physical Review}, 
volume = {106}, 
number = {5}, 
pages = {882}, 
year = {1957}, 
doi = {10.1103/PhysRev.106.882},
abstract = {By using reflectivity and absorption measurements in the region 5 to 35 micron, the effect of free carriers on the optical constants has been determined for n-and p-type germanium, silicon, and indium antimonide, and for n-type indium arsenide. The contribution of the free carriers to the electric susceptibility is obtained from the optical constants. A carrier effective mass, ms, is defined in terms of the susceptibility, and the significance of ms is considered for four different types of energy band structure. The experimental values of ms are …}, }


@Article{Powell1959,
author = {Powell, CJ and Swan, JB}, 
title = {Origin of the characteristic electron energy losses in aluminum}, 
journal = {Physical Review}, 
volume = {115}, 
number = {4}, 
pages = {869}, 
year = {1959}, 
doi = {10.1103/PhysRev.115.869},
abstract = {The characteristic electron energy loss spectrum of aluminum has been measured by analyzing the energy distribution of 760-, 1000-, 1520-, and 2020-ev electrons scattered by an evaporated specimen through 90. Twelve loss peaks were observed, made up of combinations of elementary 10.3-and 15.3-ev losses. The former, the low-lying loss, is identified with the lowered plasma loss proposed by Ritchie, and the latter with the plasma loss proposed by Bohm and Pines and previously observed by many other workers. In …}, }

@Article{Sturge1962,
author = {Sturge, M.D.}, 
title = {Optical absorption of gallium arsenide between 0.6 and 2.75 eV}, 
journal = {Physical Review}, 
volume = {127}, 
number = {3}, 
pages = {768}, 
year = {1962}, 
doi = {10.1103/PhysRev.127.768 },
abstract = {The optical absorption coefficient of high-resistivity gallium arsenide has been measured over the range of photon energy 0.6 to 2.75 eV, at temperatures from 10 to 294 K. The main absorption edge shows a sharp peak due to the formation of excitons. The energy gap and exciton binding energy are deduced from the shape of the absorption curve above the edge. Their values at 21 K are 1.521 and 0.0034 eV, respectively. Absorption from the split-off valence band is observed, the spin-orbit splitting being 0.35 eV at the center of the zone …}, }


@book{Maier_plasmonics,
   author={Maier, Stefan A.},
   title={Plasmonics},
   address={New York, NY},
   publisher={Springer},
   year={2007},
   ISBN={0387331506 },
   doi = {10.1007/0-387-37825-1}
}



@Article{Kojima2003,
author = {Kojima, Seiji and Tsumura, Naoki and Takeda, Mitsuo Wada and Nishizawa, Seizi}, 
title = {Far-infrared phonon-polariton dispersion probed by terahertz time-domain spectroscopy}, 
journal = {Physical Review B}, 
volume = {67}, 
number = {3}, 
year = {2003}, 
doi = {10.1103/PhysRevB.67.035102}
}

@Article{Sollner1983,
author = {Sollner, T. C. L. G. and Goodhue, W. D. and Tannenwald, P. E. and Parker, C. D. and Peck, D. D.}, 
title = {Resonant tunneling through quantum wells at frequencies up to 2.5 THz}, 
journal = {Appl. Phys. Lett.}, 
volume = {43}, 
number = {6}, 
pages = {588--590}, 
year = {1983}, 
doi = {10.1063/1.94434},
abstract = {Resonant tunneling through a single quantum well of GaAs has been observed. The current singularity and negative resistance region are dramatically improved over previous results, and detecting and mixing have been carried out at frequencies as high as 2.5 THz. Resonant tunneling features are visible in the conductance-voltage curve at room temperature and become quite pronounced in the I-V curves at low temperature. The high-frequency results, measured with far IR lasers, prove that the charge transport is faster than about 10−13 s. It may now be possible to construct practical nonlinear devices using quantum wells at millimeter and submillimeter wavelengths.}, }


@Article{Tsu1973,
author = {Tsu, R. and Esaki, L.}, 
title = {Tunneling in a finite superlattice}, 
journal = {Appl. Phys. Lett.}, 
volume = {22}, 
number = {11}, 
pages = {562--564}, 
year = {1973}, 
doi = {10.1063/1.1654509}}


@Article{Chang1974,
author = {Chang, L. L. and Esaki, L. and Tsu, R.}, 
title = {Resonant tunneling in semiconductor double barriers}, 
journal = {Appl. Phys. Lett.}, 
volume = {24}, 
number = {12}, 
pages = {593--595}, 
year = {1974}, 
doi = {10.1063/1.1655067}}


@Article{Van_Wees1988,
author = {Van Wees, BJ and Van Houten, H and Beenakker, CWJ and Williamson, J Gr and Kouwenhoven, LP and Van der Marel, D and Foxon, CT}, 
title = {Quantized conductance of point contacts in a two-dimensional electron gas}, 
journal = {Phys. Rev. Lett.}, 
volume = {60}, 
number = {9}, 
pages = {848}, 
year = {1988}, 
doi = {10.1103/PhysRevLett.60.848},
abstract = {… the first measurements of the conductance of single ballistic point contacts in a two-dimensional electron gas. A novel quantum effect is found: The conductance is quantized in units of e …}, }


@book{Gerry_Knight_QO,
   author={Gerry, Christopher C. and Knight, Peter L.},
   title={Introductory quantum optics},
   publisher={Cambridge Univ. Press},
   year={2005},
   edition={1. publ.},
   ISBN={052152735x},
   doi = {10.1017/CBO9780511791239}
}

@Article{BB84,
author = {Bennett, Charles H. and Brassard, Gilles}, 
title = {Quantum cryptography: Public key distribution and coin tossing [reprint]}, 
journal = {Theoretical Computer Science}, 
volume = {560}, 
pages = {7--11}, 
year = {2014}, 
doi = {10.1016/j.tcs.2014.05.025}}

@Article{Wu2017a,
author = {Wu, Xiaofei and Jiang, Ping and Razinskas, Gary and Huo, Yongheng and Zhang, Hongyi and Kamp, Martin and Rastelli, Armando and Schmidt, Oliver G and Hecht, Bert and Lindfors, Klas and Lippitz, Markus}, 
title = {On-Chip Single-Plasmon Nanocircuit Driven by a Self-Assembled Quantum Dot}, 
journal = {Nano Letters}, 
volume = {17}, 
number = {7}, 
pages = {4291--4296}, 
year = {2017},
doi = {10.1021/acs.nanolett.7b01284 }, 
}

@Article{Wolpert2012b,
author = {Wolpert, Christian and Dicken, Christian and Wang, Lijuan and Atkinson, Paola and Rastelli, Armando and Schmidt, Oliver G and Giessen, Harald and Lippitz, Markus}, 
title = {Ultrafast coherent spectroscopy of a single self-assembled quantum dot}, 
journal = {physica status solidi (b)}, 
volume = {249}, 
number = {4}, 
pages = {721--730}, 
year = {2012}, 
doi = {10.1002/pssb.201100776 }}

@Article{Pfeiffer2014,
author = {Pfeiffer, Markus and Lindfors, Klas and Zhang, Hongyi and Fenk, Bernhard and Phillipp, Fritz and Atkinson, Paola and Rastelli, Armando and Schmidt, Oliver G and Giessen, Harald and Lippitz, Markus}, 
title = {Eleven Nanometer Alignment Precision of a Plasmonic Nanoantenna with a Self-Assembled GaAs Quantum Dot}, 
journal = {Nano Letters}, 
volume = {14}, 
number = {1}, 
pages = {197--201}, 
year = {2014}, 
doi = {10.1021/nl403730q }}