RWTH
Institut für
Physikalische Chemie
Lehr- und Forschungsgebiet
Molekülspektroskopie

Prof. Dr. Wolfgang Stahl
Institut für
Physikalische Chemie
RWTH Aachen
Landoltweg 2
52056 Aachen

Prof. Dr. Wolfgang Stahl - Publikationsliste
Zurück / Back


[98]
L.W. SUTIKDJA, D. JELISAVAC, W. STAHL and I. KLEINER
Structural Studies on Banana Oil, Isoamyl Acetate, by Means of Microwave Spectroscopy and Quantum Chemical Calculations
Mol. Phys. 00, 0-0 (2012).
DOI: 10.1080/00268976.2012.679630

[97]
Y. ZOU, H. MOUHIB, W. STAHL, A. GOEKE, Q. WANG and P. KRAFT
Efficient Macrocyclization by a Novel Oxy-Oxonia-Cope Reaction: Synthesis and Olfactory Properties of New Macrocyclic Musks
Chem. Eur. J. 00, 0-0 (2012).
DOI: 10.1002/chem.201200882

[96]
H.V.L. NGUYEN, W. STAHL and I. KLEINER
Structure and rotational dynamics of methyl propionate studied by microwave spectroscopy
Mol. Phys. 00, 0-0 (2012).
DOI: 10.1080/00268976.2012.683884

[95]
H. MOUHIB and W. STAHL
Conformational Analysis of Green Apple Flavour: The Gas-Phase Structure of Ethyl Valerate Validated by Microwave Spectroscopy
ChemPhysChem 13, 1297-1301 (2012).
DOI: 10.1002/cphc.201100932

[94]
M. TUDORIE, I. KLEINER, J.T. HOUGEN, S. MELANDRI, L.W. SUTIKDJA and W. STAHL
A fitting program for molecules with two inequivalent methyl tops and a plane of symmetry at equilibrium: Application to new microwave and millimeter-wave measurements of methyl acetate
J. Mol. Spectrosc. 269, 211-225 (2011).
DOI: 10.1016/j.jms.2011.07.005

[93]
H.V.L. NGUYEN and W. STAHL
The effects of nitrogen inversion tunneling, methyl internal rotation, and 14N quadrupole coupling observed in the rotational spectrum of diethyl amine
J. Chem. Phys. 135, 024310 (2011).
DOI: 10.1063/1.3607992

[92]
H. MOUHIB, W. STAHL, M. LÜTHY, M. BÜCHEL and P. KRAFT
Cassis Odor through Microwave Eyes: Olfactory Properties and Gasphase Structures of all the Cassyrane Stereoisomers and its Dihydro Derivatives
Angew. Chem. Int. Ed. 50, 5576-5580 (2011).
DOI: 10.1002/anie.201100937

[91]
H.V.L. NGUYEN and W. STAHL
The Rotational Spectrum of Diethyl Ketone
ChemPhysChem 12, 1900-1905 (2011).
DOI: 10.1002/cphc.201001021

[90]
H. MOUHIB, D. JELISAVAC, W. STAHL, R. WANG, I. KALF, U. ENGLERT
The Conformation of Odorants in Different States of Aggregation: A Joint Venture in Microwave Spectroscopy and X-ray Diffraction
ChemPhysChem 12, 761-764 (2011).
DOI: 10.1002/cphc.201000986

[89]
H. MOUHIB, D. JELISAVAC, L.W. SUTIKDJA, E. ISAAK, W. STAHL
Structural Studies on Ethyl Isovalerate by Microwave Spectroscopy and Quantum Chemical Calculations
J. Phys. Chem. A 115, 118-122 (2011).

[88]
H. MOUHIB, Y. ZHAO, W. STAHL
Two conformers of ethyl pivalate studied by microwave spectroscopy
J. Mol. Spectrosc. 261, 59-62 (2010).

[87]
H.V.L. NGUYEN, H. MOUHIB, W. STAHL, I. KLEINER
The microwave spectrum of allyl acetate
Mol. Phys. 108, 763-770(2010).

[86]
H.V.L. NGUYEN, W. STAHL
The microwave spectrum of isopropenyl acetate
J. Mol. Spectrosc. 264, 120-124 (2010).

[85]
D. JELISAVAC, D.C. CORTÉS GÓMEZ, H.V.L. NGUYEN, L.W. SUTIKDJA, W. STAHL, I. KLEINER
The microwave spectrum of the trans conformer of ethyl acetate
J. Mol. Spectrosc. 257, 111-115 (2009).

[84]
A. HELLWEG, C. HÄTTIG, I. MERKE, and W. STAHL
Microwave and Theoretical Investigation of the Internal Rotation in m-Cresol
J. Chem. Phys. 124, 204305 (2006) (available online).

[83]
I. MERKE, A. LÜCHOW, and W. STAHL
Internal Rotation, Quadrupole Coupling and Structure of (CH3)3SiI studied by Microwave Spectroscopy and Ab-initio Calculations
J. Mol. Struct., 780-781, 295-299 (2006).

[82]
K. KLATTE, D. CHRISTEN, I. MERKE, W. STAHL, and H. OBERHAMMER
Gas Phase Structure of Ruppert’s Reagenz, CH3SiMe3
J. Phys. Chem. A 109, 8438-8442 (2005).

[81]
D. GERHARD, A. HELLWEG, I. MERKE, W. STAHL, M. BAUDELET, D. PETITPREZ, and G. WLODARCZAK
Internal Rotation and Chlorine Nuclear Quadrupole Coupling of o-Chlorotoluene Studied by Microwave Spectroscopy and Ab Initio Calculations
J. Mol. Spectrosc. 220, 234-241 (2003).

[80]
I. MERKE, W. STAHL, S. KASSI, D. PETITPREZ, and G. WLODARCZAK
Internal Rotation, Quadrupole Coupling, and Structure of (CH3)3SiCl Studied by Microwave Spectroscopy and Ab Initio Calculations
J. Mol. Spectrosc. 216, 437-446 (2002).

[79]
A. WELZEL, A. HELLWEG, I. MERKE, and W. STAHL
Structural and Torsional Properties of o-Cresol and o-Cresol-OD as Obtained from Microwave Spectroscopy and Ab Initio Calculations
J. Mol. Spectrosc. 215, 58-65 (2002).

[78]
T. GOLY, U. SPOEREL, and W. STAHL
The microwave spectrum of the 1,2-difluorobenzene dimer
Chem. Phys. 283 (2002), 289-296.

[77]
J.-U. GRABOW, H. HARTWIG, N. HEINEKING, W. JÄGER, H. MÄDER, H.W. NICOLAISEN, and W. STAHL
The microwave spectrum of 2-methylthiazole: methyl internal rotation and 14N nuclear quadrupole coupling
Mol. Struct. 612 (2002), 349-356.

[76]
A.C. FANTONI, W. CAMINATI, H. HARTWIG, and W. STAHL
The very low methyl group V3 barrier of cis N-methylformamide: A-E doubling from the free jet rotational spectrum
Mol. Struct. 612 (2002), 305-307.

[75]
O. INDRIS and W. STAHL
The Microwave Spectrum and Quadrupole Coupling in tricarbonyl(methylcyclopentadienyl)manganese
Mol. Phys. 2000, 98, 1495-1504.

[74]
O. INDRIS and W. STAHL
The Rotational Spectrum of Tricarbonyl(trans,trans-2,4-hexadiene)Iron
J. Mol. Spectrosc. 199, 259-264 (2000).

[73]
T. BRUHN and W. STAHL
The microwave spectrum of 1-chloro-2-methylpropene
J. Mol. Spectrosc. 202, 272-280 (2000).

[72]
O. INDRIS and W. STAHL
Rotational Spectrum and Internal Rotation of Tricarbonyl(isoprene) Iron
J. Phys. Chem. A 1999, 103, 11310-11314.

[71]
O. INDRIS and W. STAHL
Microwave spectrum and methyl internal rotation of tricarbonyl(trans-pentadiene-1,3)iron
Phys. Chem. Chem. Phys. 2000, 2, 319-322.

[70]
J. GRIPP, A. GUARNIERI, W. STAHL, and D. LENTZ
The rotational spectrum of propynyl isocyanide
J. Mol. Struct. 526, 81-96 (2000).

[69]
M. HAECKEL and W. STAHL
The microwave spectrum and molecular structure of the hydrogen bonded aniline-methanol complex
J. Mol. Spectrosc. 198, 263-277 (1999).

[68]
A. WELZEL and W. STAHL
The FT microwave spectrum of benzo[b]thiophene: first application of a new heatable beam nozzle
PCCP 1999, 22, 5109-5112.

[67]
J. MÜLLER, U. RUSCHEWITZ, O. INDRIS, H. HARTWIG, and W. STAHL
Structure of Ammonia Trimethylalane (Me3Al-NH3): Microwave Spectroscopy, X-ray Powder Diffraction, and ab Initio Calculations
J. Am. Chem. Soc. 121, 4647-4652 (1999).

[66]
D. PRIEM, J. COSLEOU, J. DEMAISON, I. MERKE, W. STAHL, W. JERZEMBECK, and H. BÜRGER
Analysis of the rotational spectra of SiH3CN and its isotopomers: Experimental and ab-initio determinations of the dipole moment and the structure
J. Mol. Spectrosc. 191, 183-198 (1998).

[65]
H. BÜRGER, J. DEMAISON, P. DRÉAN, W. JERZEMBECK, I. MERKE, and W. STAHL
High Resolution Infrared, Microwave, and Millimeter Wave Spectra of SeCF2. Structure Determination assisted by ab initio Calculations
Ber. Bunsenges. Phys. Chem. 102, 872-881 (1998).

[64]
U. SPOEREL, W. STAHL, W. CAMINATI, and P.G. FAVERO
Jet Cooled Rotational Spectra and ab initio investigations of the Tetrahydropyran-Water System
Chem.-Eur. J. 4, 1974-1981 (1998).

[63]
U. SPOEREL and W. STAHL
Equatorial Piperidine and the Piperidine-Water-Complex - Rotational Spectra and Molecular Structures
Chem. Phys. 239, 97-108 (1998).

[62]
O. INDRIS, W. STAHL, and U. KRETSCHMER
The Molecular Structure of Morpholine and the Morpholine-H2O Complex determined by FT Microwave Spectroscopy
J. Mol. Spectrosc. 190, 372-378 (1998).

[61]
U. SPOEREL and W. STAHL
The Aniline-Water Complex: Rotational Spectrum and Molecular Structure
J. Mol. Spectrosc. 190, 278-289 (1998).

[60]
D. CONSALVO and W. STAHL
The structure of quinuclidine determined by high resolution microwave spectroscopy
J. Mol. Struct. 447, 119-126 (1998).

[59]
D. EWERT, H. GRÖNIG, H. OLIVIER, W. STAHL, and D. ZIMMERMANN,
Microwave Detection of Molecules formed by Shock Wave Induced Reactions
Shock Waves 8, 385-388 (1998).

[58]
G. COLUMBERG, A. BAUDER, N. HEINEKING, W. STAHL, and J. MAKAREWICZ
Internal rotation effects and hyperfine structure in the rotational spectrum of a water-carbon dioxide complex
Mol. Phys. 93, 215-228 (1998).

[57]
U. WÖTZEL, W. STAHL, and H. MÄDER,
The Influence of an Off-resonant Pump Radiation in Fourier transform microwave spectroscopy
Can. J. Phys. 75, 821-830 (1997).

[56]
L-H. XU, A.M. ANDREWS, R.R. CAVANAGH, G.T. FRASER, K.K. IRIKURA, F.J. LOVAS, J.-U. GRABOW, W. STAHL, M.K CRAWFORD, and R.J. SMALLEY,
Rotational and Vibrational Spectroscopy and Ideal Gas Heat Capacity of HFC 134a (CF3CFH2)
J. Phys. Chem. A 101, 2288-2297 (1997).

[55]
E. JOCHIMS, H. MÄDER, and W. STAHL,
The Molecular Structure of 1,2,4-Trifluorobenzene and of the 1,2,4-Trifluorobenzene-Argon Complex Determined by FT Microwave Spectroscopy
J. Mol. Spectrosc. 180, 116-120 (1996).

[54]
J.-U. GRABOW, W. STAHL, and H. DREIZLER,
A Multioctave Coaxially Oriented Beam Resonator Arrangement Fourier-Transform Microwave (COBRA-FTMW) Spectrometer
Rev. Sci. Instrum. 67, 4072 (1996).

[53]
U. SPOEREL, H. DREIZLER, W. STAHL, E. KRAKA, and D. CREMER,
Intermolecular Forces in Argon Van der Waals Complexes - Rotational Spectrum and Ab Initio Investigation of Isoxazole-Argon
J. Phys. Chem., 100, 14298-14309 (1996).

[52]
M. GERHARDS, M. SCHMITT, K. KLEINERMANNS, and W. STAHL
The Structure of Phenol(H2O) obtained by Microwave Spectroscopy
J. Chem. Phys. 104, 967-971 (1996).

[51] U. KRETSCHMER, D. CONSALVO, A. KNAACK, W. SCHADE, W. STAHL, and H. DREIZLER
The 14N Quadrupole Hyperfine Structure in the Rotational Spectrum of Laser Vaporized Urea observed by molecular beam FT Microwave Spectroscopy
Mol. Phys. 87, 1159-1168 (1996).

[50]
H. MÄDER, N. HEINEKING, W. STAHL, W. JÄGER, and Y. XU,
Rotational Spectrum of the Isotopically Substituted van der Waals Complex Ar-CO2 investigated with a Molecular Beam FTMW Spectrometer
Faraday Trans. 92, 901-905 (1996).

[49]
D. CONSALVO and W. STAHL,
Rotational Spectrum and Structure of the Quinuclidine-Water Complex
J. Mol. Spectrosc. 174, 520 (1995).

[48]
U. KRETSCHMER, W. STAHL, and H. DREIZLER,
The Microwave Spectrum of the Thiazole-Argon van der Waals Complex
J. Mol. Struct. 352/353, 289 (1995).

[47]
U. DAHMEN, H. DREIZLER, and W. STAHL,
The Rotational Spectrum of the Benzene-Carbonyl Sulfide Complex. A Contribution to the Theory of Internal Rotation with Heavy Tops
Ber. Bunsenges. Phys. Chem. 99, 434 (1995).

[46]
E. KRAKA, D. CREMER, U. SPOEREL, I. MERKE, W. STAHL, and H. DREIZLER
Intermolecular Forces in Argon Van der Waals Complexes. Rotational Spectrum and Ab initio Investigations of Oxazole-Argon
J. Phys. Chem. 99, 12466 (1995).

[45]
N. HEINEKING, W. STAHL, E.H.T. OLTHOF, P.E.S.WORMER, A. VAN DER AVOIRD, and M. HAVENITH
The Nuclear Quadrupole Coupling Constants and the Structure of the para-para Ammonia Dimer
Chem. Phys. 102, 8693 (1995).

[44]
F.J. LOVAS, S.P. BELOV, M.YU. TRETYAKOV, W. STAHL, and R.D. SUENRAM
The a-Type K=0 Microwave Spectrum of the Methanol Dimer
J. Mol. Spectrosc. 170, 478 (1995).

[43]
J. KOPUT, W. STAHL, N. HEINEKING, G. PAWELKE, B. STEGER, and D. CHRISTEN
The Rotational Spectrum of Trifluoromethyl Isocyanate
J. Mol. Spectrosc. 168, 323 (1994).

[42]
U. SPOEREL, H. DREIZLER, and W. STAHL,
On the Sign of the Off-Diagonal Elements of the Nuclear Quadrupole Coupling Tensor
Z. Naturforsch. 49a, 645 (1994).

[41]
U. DAHMEN, W. STAHL, and H. DREIZLER,
The Rotational Spectrum of Benzonitrile and its Argon Van der Waals Complex
Ber. Bunsenges. Phys. Chem. 98, 970 (1994).

[40]
I. MERKE, W. STAHL, and H. DREIZLER,
A Molecular Beam Fourier Transform Microwave Spectrometer in the Range 26.5 to 40 GHz. Tests of Performance and Analysis of the D- and 14N-Hyperfine Structure of Methylcyanide-d1
Z. Naturforsch. 49a, 490 (1994).

[39]
U. ANDRESEN, H. DREIZLER, U. KRETSCHMER, W. STAHL, and C. THOMSEN,
A Molecular Beam Fourier Transform Microwave Spectrometer developed for Analytical Purposes
Fresenius J. Anal. Chem. 349, 272 (1994).

[38]
N. HEINEKING, J.-U. GRABOW, and W. STAHL,
The Microwave Spectrum and Molecular Structure of Ethylisocyanate
Mol. Phys. 81, 1177 (1994).

[37]
U. KRETSCHMER, W. STAHL, and H. DREIZLER,
The Microwave Spectrum of the Thiophene-Argon van der Waals Complex
Z. Naturforsch. 48a, 1107 (1993).

[36]
G. WLODARCZAK, J. GRIPP, and W. STAHL,
The Hyperfine Structure of OCSe
J. Mol. Spectrosc. 161, 297 (1993).

[35]
U. KRETSCHMER, W. STAHL, and H. DREIZLER,
The Rotational Spectra of the 32S-, 33S-, and 34S-Isotopomers of Thiophene
Z. Naturforsch. 48a, 733 (1993).

[34]
E. JOCHIMS, J.-U. GRABOW, and W.STAHL,
Microwave Spectrum and Structure of the 1,2-Difluorobenzene-Argon Van der Waals Complex
Mol. Spectrosc., 158, 278 (1992).

[33]
M. KRÜGER, W. STAHL, and H. DREIZLER,
Nuclear Quadrupole Coupling, Spin-Rotation, and Spin-Spin Interaction in the Rotational Spectrum of Ethinylisocyanide
J. Mol. Spectrosc., 158, 298 (1992).

[32]
W. STAHL and L.H. COUDERT,
The Hyperfine Structure of (D2O)2
J. Mol. Spectrosc., 157, 161 (1993).

[31]
M. KREGLEWSKI, W. STAHL, J.-U. GRABOW, and G. WLODARCZAK,
The Quadrupole Coupling Tensor of Methyl Amine
Chem. Phys. Lett. 196, 155 (1992).

[30]
M. MEYER and W. STAHL,
The Microwave Spectrum of N-Methylsulfinylamine
J. Mol. Spectrosc. 154, 443 (1992).

[29]
W. STAHL and J.-U. GRABOW,
The Rotational Spectrum of the Fluorobenzene-Argon Van der Waals Complex
Z. Naturforsch. 47a, 681 (1992).

[28]
J.-U. GRABOW, N. HEINEKING, and W. STAHL
Interdependence of Parameters in Multivariate Fits
J. Mol. Spectrosc. 152, 168 (1992).

[27]
N. HEINEKING, J.-U. GRABOW, and W. STAHL
The Microwave Spectrum of t-Butyl Isocyanate
J. Mol. Spectrosc. 154, 129 (1992).

[26]
I. MERKE, J.-U. GRABOW, N. HEINEKING, and W. STAHL
The Microwave Spectrum of 1,1-Dichloro-2,2,2-trifluoroethane
Z. Naturforsch. 46a, 799 (1991).

[25]
N. HEINEKING, J.-U. GRABOW, K. VORMANN, and W. STAHL
14N Nuclear Hyperfine Structure in the Rotational Spectrum of Thionyl Aniline
Z. Naturforsch. 46a, 989 (1991).

[24]
M. MEYER, W. STAHL, and H. DREIZLER
Methyl Internal Rotation, Dipole Moment and Nuclear Quadrupole Coupling of 2-Bromopropane
J. Mol. Spectrosc. 151, 243 (1992).

[23]
J.-U. GRABOW, N. HEINEKING, and W. STAHL
A Molecular Beam Microwave Fourier Transform (MB-MWFT) Spectrometer with an Electric Discharge Nozzle
Z. Naturforsch. 46a, 914 (1991).

[22]
W.H. NICOLAISEN, J.-U. GRABOW, N. HEINEKING, and W. STAHL
The Microwave Spectrum of 4-Methylisothiazole
Z. Naturforsch. 46a, 635 (1991).

[21]
J.-U. GRABOW, N. HEINEKING, and W. STAHL
The Microwave Spectrum and Dipole Moment of Hexafluoropropanone
Z. Naturforsch. 46a, 229 (1991).

[20]
N. HEINEKING, W. STAHL, and C. THOMSEN
The Rotational Spectrum and Dipole Moment of 1,1,1,2,3,3,3-Heptafluoropropane in its Vibrational Ground State as observed by Pulsed Molecular Beam Microwave Fourier Transform Spectroscopy
J. Mol. Spectrosc. 146, 402 (1991).

[19]
U. ANDRESEN, H. DREIZLER, J.-U. GRABOW, and W. STAHL
An Automatic Molecular Beam Microwave Fourier Transform Spectrometer
Rev. Sci. Instrum. 61, 3694 (1990).

[18]
J.-U. GRABOW and W. STAHL
A Pulsed Molecular Beam Microwave Fourier Transform Spectrometer with Parallel Molecular Beam and Resonator Axes
Z. Naturforsch. 45a, 1043 (1990).

[17]
H. HARDER, W. STAHL, and H. DREIZLER
Hyperfine Structure in the Rotational Spectrum of tert-Butyl Bromide
Z. Naturforsch. 45a, 807 (1990).

[16]
Jane K. RICE, L.H. COUDERT, K. MATSUMURA, R.D. SUENRAM, F.J. LOVAS, W. STAHL, D.J. PAULEY, and S.G. KUKOLICH
The rotational and tunneling spectrum of the H2S-CO2 van der Waals complex
J. Chem. Phys. 92, 6408 (1990).

[15]
J.S. GILLIES and C.W. GILLIES, R.D. SUENRAM and F. LOVAS, W. STAHL
The Microwave Spectrum and Molecular Structure of the Ethylene-Ozone van der Waals Complex
J. Am. Chem. Soc. 111, 3073 (1989).

[14]
P. WOLF and W. STAHL
The Determination of Spin-Rotation and Spin-Spin Interaction Constants from the Microwave Spectrum of Methane
Z. Naturforsch. 44a, 651 (1989).

[13]
N. HEINEKING, W. STAHL, and H. DREIZLER
Radiofrequency Microwave Double Resonance Experiments in Fourier Transform Technique
Z. Naturforsch. 43a, 280 (1988).

[12]
Wolfgang STAHL and Helmut DREIZLER
Determination of the Spin-Rotation and Spin-Spin Interaction Constants of Germane by Microwave Fouriertransform Measurements
Z. Naturforsch. 42a, 1402 (1987).

[11]
H. DREIZLER, U. ANDRESEN, J. GRIPP, I. MERKE, M. MEYER, W. STAHL, R. SCHWARZ, and K. VORMANN
A Microwave Fourier Transform Spectrometer in the Region between 26 and 36 GHz
Z. Naturforsch. 42a, 1279 (1987).

[10]
W. STAHL, J. GRIPP, N. HEINEKING, and H. DREIZLER
A Microwave Fourier Transform Technique using Double Resonance Modulation
Z. Naturforsch. 42a, 392 (1987).

[9]
W. STAHL and H. DREIZLER, L. JÖRISSEN and W.A. KREINER
The Microwave Q-branch Spectrum of Germane in the Vibrational Ground State
Z. Naturforsch. 41a, 747 (1986).

[8]
W. STAHL and H. DREIZLER
Polarization Inhomogeneity Effects in Microwave Fourier Transform Spectroscopy
Z. Naturforsch. 40a, 1096 (1985).

[7]
W. STAHL, G. BESTMANN, H. DREIZLER, U. ANDRESEN, and R. SCHWARZ
A Microwave Fourier Transform Spectrometer for the Entire K Band for the Investigation of Molecules in the Gas-Phase
Rev. Sci. Instrum. 56, 1759 (1985).

[6]
W. STAHL, E. FLIEGE, and H. DREIZLER
Two-Dimensional Microwave Fourier Transform Spectroscopy
Z. Naturforsch. 39a, 858 (1984).

[5]
W. KASTEN, W. STAHL, and H. DREIZLER
Stark Effect Measured by Microwave Fourier Transform Spectroscopy
Z. Naturforsch. 39a, 511 (1984).

[4]
W. STAHL, E. FLIEGE, H. DREIZLER, and R. SCHWARZ
A Microwave Fourier Transform Spectrometer for the Lower K-Band
Z. Naturforsch. 39a, 354 (1984).

[3]
W. STAHL, H. DREIZLER, and M. HAYASHI
Determination of a High Potential Barrier Hindering Internal Rotation from the Ground State Spectrum. The Methylbarrier of Ethylchloride
Z. Naturforsch. 38a, 1010 (1983).

[2]
G. BESTMANN, H. DREIZLER, E. FLIEGE, and W. STAHL
A Microwave Fourier Transform Spectrometer in the Range of 5.4 to 8 GHz
J. Mol. Struct. 97, 215 (1983).

[1] H. DREIZLER, E. FLIEGE, H. MÄDER, and W. STAHL
Microwave Fourier Transform Double Resonance Experiment and Theory
Z. Naturforsch. 37a, 1266 (1982).

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