Weakly
bound
intermolecular
complexes
|
- (H2O)2...HCl:
Z.Kisiel, E.Bialkowska-Jaworska,
L.Pszczolkowski, A.Milet, C.Struniewicz, R.Moszynski, and J.Sadlej,
"Structure and properties of the weakly bound trimer (H2O)2...HCl observed by rotational spectroscopy", J.Chem.Phys.
112, 5767-5776 (2000).
Z.Kisiel, J.Kosarzewski,
B.A.Pietrewicz, and L.Pszczolkowski, "Electric dipole moments of the
cyclic trimers (H2O)2...HCl and (H2O)2...HBr
from
Stark
effects in their rotational spectra", Chem.Phys.Lett. 325,
523-530
(2000).
- (H2O)2...HBr:
Z.Kisiel, B.A.Pietrewicz,
O.Desyatnyk, L.Pszczolkowski, I.Struniewicz, and J.Sadlej, "Structure
and properties of the weakly bound cyclic trimer (H2O)2...HBr observed by rotational spectroscopy", J.Chem.Phys.
119, 5907-5917 (2003).
Z.Kisiel, J.Kosarzewski,
B.A.Pietrewicz, and L.Pszczolkowski, "Electric dipole moments of the
cyclic trimers (H2O)2...HCl and (H2O)2...HBr
from
Stark
effects in their rotational spectra", Chem.Phys.Lett. 325,
523-530
(2000).
- H2O...HCl:
Z.Kisiel,
B.A.Pietrewicz, P.W.Fowler, A.C.Legon, and E.Steiner, "Rotational
spectra of the less common isotopomers, electric dipole moment and the
double minimum inversion potential of H2O...HCl", J.Phys.Chem.A
104, 6970-6978 (2000).
see also: Z.Kisiel, "Least-squares
mass-dependence molecular structures for selected weakly-bound
intermolecular complexes", J.Mol.Spectrosc.
218, 58-67 (2003).
- H2O...(HCl)2: Z.Kisiel, A.Lesarri, J.L.Neill, M.T.Muckle, and B.H.Pate, "Structure and properties of the (HCl)2H2O cluster observed by chirped-pulse Fourier transform microwave spectroscopy", Phys.Chem.Chem.Phys. 13, 13912-13919 (2011).
- (H2O)n, n=6-10: Water clusters in the size range from the hexamer to the decamer
J. O. Richardson, C. Perez, S.
Lobsiger, A. A. Reid, B. Temelso, G. C. Shields, Z. Kisiel, D. J. Wales,
B. H. Pate, S. C. Althorpe, ”Concerted hydrogen-bond breaking by
quantum tunneling in the water hexamer prism", Science 351, 1310-1313 (2016); https://www.youtube.com/watch?v=PKPB6pasxGU
C. Perez, D. P.
Zaleski, N. A. Seifert, B. Temelso, G. C. Shields,
Z. Kisiel, B. H. Pate, ”Hydrogen bond cooperativity and the
three-dimensional structures of water nonamers and decamers”, Angew. Chem. Int. Ed. 53, 14368-14372 (2015).
C. Perez, S. Lobsiger, N. A. Seifert, D. P.
Zaleski, B. Temelso, G. C. Shields, Z. Kisiel, B. H. Pate, ”Broadband
Fourier transform rotational spectroscopy for structure determination: The water heptamer”, Chem. Phys. Lett. 571, 1-15 (2013).
C. Perez, M. T. Muckle, D. P. Zaleski, N. A.
Seifert, B. Temelso, G. C. Shields, Z. Kisiel, B. H. Pate, ”Structures
of the Cage, Prism, and Book Isomers of Water Hexamer from Broadband Rotational Spectroscopy”, Science 336, 897-901 (2012).
- Ar...HCl: Z.Kisiel and L.Pszczolkowski, "Rotational spectrum and
spectroscopic constants of 36Ar...H35Cl and 40Ar...HCl",
Chem.Phys.Lett. 291,190-196 (1998).
- Arn...HX,
n=2,3, X=F, Cl, Br: Z.Kisiel, E.Bialkowska-Jaworska, and
L.Pszczolkowski, "The experimental electric dipole moments of the ArnHX
van
der
Waals clusters", Chem.Phys.Lett. 333,381-386
(2001).
- Pyrimidine...H2O: S.Melandri, M.E.Sanz, W.Caminati, P.G.Favero, and Z.Kisiel,
"The hydrogen bond between water and aromatic bases of biological
interest: an experimental and theoretical study of the 1:1 complex of
pyrimidine with water", J.Amer.Chem.Soc. 120,
11504-11509 (1998).
- N2...HCl: Z.Kisiel and L.Pszczolkowski, P.W.Fowler, and A.C.Legon,
"Rotational spectrum of 14N2...H35Cl
and 14N2...H37Cl:
electric field gradients at the nitrogen nuclei", Chem.Phys.Lett.
276, 202-209 (1997).
- N2...HBr: Z.Kisiel, B.A.Pietrewicz, and L.Pszczolkowski, "Rotational
spectrum of the most abundant isotopomer of the van der Waals dimer N2...HBr", Acta
Physica
Polonica
A 101, 231-242 (2002).
- Ar2...HBr:
Z.Kisiel,
B.A.Pietrewicz, and L.Pszczolkowski, "The observation and
characterisation by rotational spectroscopy of the weakly bound trimer
Ar2HBr", J.Chem.Phys. 117,
8248-8255
(2002).
Z.Kisiel,
E.Bialkowska-Jaworska, and L.Pszczolkowski, Chem.Phys.Lett.
333,381-386 (2001) - dipole moment measurement only.
- (H2O...HCl)...Ar:
ms. in prep.
- Ar...HCCCN:
O.Desyatnyk,
J.Kosarzewski, Z.Kisiel, "Observation and properties of the van der
Waals dimer Ar...HCCCN produced in electrical discharge", Acta
Physica Polonica A 104, 415-424 (2003).
- CH2F2...CH2Cl2: Q. Gou, L. Spada, M. Vallejo-López, Z. Kisiel, W. Caminati, ”Interactions between
Freons: A Rotational Study of CH2F2...CH2Cl2”, Chem. Asian J. 9, 1032-1038 (2014).
Trichloroethylene,
Cl2C=CHCl (a well known solvent):
- Z.Kisiel, E.Bialkowska-Jaworska, and
L.Pszczolkowski, "Nuclear quadrupole coupling in Cl2C=CHCl
and Cl2C=CH2; "Evidence for systematic
differences in orientation between internuclear and field gradient axes
for terminal quadrupolar nuclei", J.Chem.Phys. 109,
10263-10272 (1998).
- Z.Kisiel and L.Pszczolkowski,
"Assignment and analysis of the mm-wave rotational spectrum of
trichloroethylene: observation of a new, extended b.R-band and
an overview of high-J, R-type bands", J.Mol.Spectrosc.
177, 125-137 (1996).
1,1,1-trichloroethane,
Cl3CCH3 (another popular industrial solvent):
- Z.Kisiel, L.Pszczolkowski, G.Cazzoli, L.Dore, "Strong
Coriolis coupling between v5
and v11
states
of
CH3CCl3
studied by millimeter-wave spectroscopy", J.Mol.Spectrosc.
251, 235-240 (2008).
- L.Dore and Z.Kisiel, "Nuclear
quadrupole coupling in 1,1,1-Trichloroethane: Inertial and principal
tensors for 35Cl and 37Cl", J.Mol.Spectrosc.
189, 228-234 (1998).
- Z.Kisiel and L.Pszczolkowski,
"Millimeter wave rotational spectra of the 37Cl species of
1,1,1,-trichloroethane" J.Mol.Spectrosc. 181, 48-55
(1997).
- G.Cazzoli, G.Cotti, L.Dore, and
Z.Kisiel, "The high frequency rotational spectrum of
1,1,1-trichloroethane and the observation of K=3 splitting", J.Mol.Spectrosc.
174, 425-432 (1995).
Chlorobromodifluoromethane,
CBrClF2 (the popular fillant for fire extinguishers, removed
from use following concerns over the well-being of the ozone layer):
- Z.Kisiel, E.Bialkowska-Jaworska, and
L.Pszczolkowski, "Nuclear quadrupole coupling in Cl2C=CHCl
and Cl2C=CH2; Evidence for systematic differences
in orientation between internuclear and field gradient axes for
terminal quadrupolar nuclei", J.Chem.Phys. 109,
10263-10272 (1998).
- Z.Kisiel and L.Pszczolkowski,
"Assignment and analysis of the mm-wave rotational spectrum of
trichloroethylene: observation of a new, extended b.R-band and
an overview of high-J, R-type bands", J.Mol.Spectrosc.
177, 125-137 (1996).
Chlorofluoromethane,
CHF2Cl (the freon CFC-22, widely used as an intermediate
replacement for the CFC-11 and CFC-12 refrigerants which were relegated
from use due to adverse effect on the ozone layer):
- Z.Kisiel, J.L.Alonso, S.Blanco,
G.Cazzoli, J.M.Colmont, G.Cotti, G.Graner, J.C.Lopez, I.Merke, and
L.Pszczolkowski, "Spectroscopic constants for HCFC-22 from rotational
and high-resolution vibration spectra: CHF237Cl
and 13CHF235Cl isotopomers", J.Mol.Spectrosc.
184, 150-155 (1997).
- Z.Kisiel, L.Pszczolkowski, G.Cazzoli,
and G.Cotti, "The millimeter-wave rotational spectrum and Coriolis
interaction in the two lowest excited vibrational states of CHClF2",
J.Mol.Spectrosc. 173, 477-487 (1995).
- G.Klatt, G.Graner, S.Klee, G.Mellau,
Z.Kisiel, L.Pszczolkowski, J.L.Alonso, and J.C.Lopez, "Analysis of the
high-resolution FT-IR and millimeter-wave spectra of the v5=1
state
of
CHF2Cl", J.Mol.Spectrosc. 178,
108-112 (1996).
Methylene
iodide, CH2I2 (a rather taxing problem for rotational
spectroscopy):
- Z.Kisiel, E.Bialkowska-Jaworska,
L.Pszczolkowski, "The <ICI bending satellites in the millimeter-wave
rotational spectra of CH2I2 and CD2I2",
J.Mol.Spectrosc. 199, 5-12 (2000).
- Z.Kisiel, L.Pszczolkowski, L.B.Favero,
and W.Caminati, "An isotopomer of the first molecule containing two
iodine nuclei investigated by microwave spectroscopy", J.Mol.Spectrosc.
189, 283-290 (1998).
- Z.Kisiel, L.Pszczolkowski, W.Caminati,
and P.G.Favero, "First assignment of the rotational spectrum of a
molecule containing two iodine nuclei: spectroscopic constants and
structure of CH2I2", J.Chem.Phys. 105,
1778-1785
(1996).
Bromoform,
CHBr3 (spectrum complicated by hyperfine structure and
multiple isotopic species, which was solved on the basis of a
broadband, supersonic expansion spectrum recorded with chirped-pulse microwave
techniques):
- Z.Kisiel, A.Krasnicki,
L.Pszczolkowski, S.T.Shipman, L.Alvarez-Valtierra, B.H.Pate,
"Assignment and analysis of the rotational spectrum of bromoform
enabled by broadband FTMW spectroscopy", J.Mol.Spectrosc.
257, 177-186 (2009).
Diethyl
ether, C2H5OC2H5 (the classical anaesthetic):
- Z.Kisiel, L.Pszczolkowski,
I.R.Medvedev, M.Winnewisser, F.C.De Lucia, E.Herbst, "Rotational
spectrum of trans-trans diethyl ether in the ground and three excited vibrational
states", J.Mol.Spectrosc. 233,
231-243 (2005).
- I.Medvedev, M.Winnewisser, F.C.De
Lucia, E.Herbst, E.Bialkowska-Jaworska, L.Pszczolkowski, Z.Kisiel, "The
millimeter- and submillimeter-wave spectrum of the trans-gauche
conformer of diethyl ether", J.Mol.Spectrosc. 228,
314-328 (2004).
- I.Medvedev, M.Winnewisser, F.C.De
Lucia, E.Herbst, E.Yi, L.P.Leong, R.P.A.Bettens, E.Bialkowska-Jaworska,
O.Desyatnyk, L.Pszczolkowski, Z.Kisiel, "The millimeter- and
submillimeter-wave spectrum of the trans-trans conformer of
diethyl ether C2H5OC2H5", Astrophys.J.Suppl.Series 148, 593-597
(2003).
Chlorine
nitrate, ClONO2 (important stratospheric molecule):
- Z.Kisiel, E.Bialkowska-Jaworska,
R.A.H.Butler,
D.T.Petkie, P.Helminger, I.R.Medvedev, F.C.De Lucia, "The rotational
spectrum of chlorine nitrate (ClONO2) in four lowest
nv9 polyads", J.Mol.Spectrosc. 254,
78-86
(2009).
- R.A.H.Butler, D.T.Petkie, P.Helminger,
F.C.De Lucia, E.Bialkowska-Jaworska, Z.Kisiel, "The rotational spectrum
of chlorine nitrate (ClONO2): The v6
vibrational state", J.Mol.Spectrosc.
244, 113-116 (2007).
- R.A.H.Butler, D.T.Petkie, P.Helminger,
F.C.De Lucia, Z.Kisiel, "The rotational spectrum of chlorine nitrate
(ClONO2): The v5/v6v9 dyad", J.Mol.Spectrosc. 243,
1-9
(2007).
Acrylonitrile
= Vinyl cyanide, H2C=CHCN: This molecule has been classified as a significant astrophysical weed
molecule and thus requiring
detailed understanding of its rotational spectrum well into the THz
region. The A&A paper showed that even its rotational
transitions in relatively high vibrational states are astrophysically
relevant.
- Z. Kisiel, M.-A. Martin-Drumel, O. Pirali, ”Lowest
vibrational states of acrylonitrile from microwave and synchrotron
radiation spectra”, J. Mol. Spectrosc. 315, 83-91 (2015).
- A. Lopez, B. Tercero, Z. Kisiel, A. M. Daly, C. Bermdez, H. Calcutt,
N. Marcelino, S. Viti, B. J. Drouin, I. R. Medvedev, C. F. Neese, L.
Pszcz´ o lkowski, J. L. Alonso, J. Cernicharo, ”Laboratory
characterization and astrophysical detection of vibrationally excited states of vinyl cyanide in Orion-KL”, Astron. Astrophys. 572, A44:1-39 (2014).
- Z. Kisiel, L. Pszczolkowski, B. J. Drouin, C. S. Brauer, S. Yu, J.
C. Pearson, I. R.Medvedev, S. Fortman, C. Neese, ”Broadband rotational
spectroscopy of acrylonitrile: Vibrational energies from perturbations”, J. Mol. Spectrosc. 280, 134-144 (2012).
- A. Krasnicki, Z. Kisiel, B. J. Drouin, J. C. Pearson, ”Terahertz spectroscopy of isotopic acrylonitrile”, J. Mol. Struct. 1006, 20-27 (2011).
- A. Krasnicki, Z. Kisiel, ”Electric dipole moments of acrylonitrile and of propionitrile measured in supersonic expansion”, J. Mol. Spectrosc. 270, 83-87 (2011).
- Z.Kisiel, L.Pszczolkowski, B.J.Drouin,
C.S.Brauer, S.Yu, J.C.Pearson, "The rotational spectrum of
acrylonitrile up to 1.67 THz", J.Mol.Spectrosc.
258,
26-34 (2009).
- G.Cazzoli, Z.Kisiel, "The rotational spectrum of
acrylonitrile in excited states of the low frequency CCN bending
vibrational modes", J.Mol.Spectrosc.
130,
303-315 (1988).
Ethyl cyanide (propionitrile), C2H5CN
(another relevant astrophysical molecule, not only in the interstellar
medium but, as it turns out, also closer to Earth on Saturn's moon
Titan):
- M.A. Cordiner, M.Y. Palmer, C.A.
Nixon, P.G.J. Irwin, N.A. Teanby, S.B. Charnley, M.J. Mumma, Z.Kisiel,
J. Serigano, Y.-J. Kuan, Y.-L. Chuang, K.-S. Wang, ”Ethyl cyanide on Titan: Spectroscopic detection and mapping using ALMA”, Astrophys. J. Lett. 800, L14:1-7 (2015).
- A. Krasnicki, Z. Kisiel, ”Electric dipole moments of acrylonitrile and of propionitrile measured in supersonic expansion”, J. Mol. Spectrosc. 270, 83-87 (2011).
n-propanol, H3CCH2CH2OH (successful assignment of all five conformers by
combining information from spectra recorded in four different
laboratories using different
techniques of rotational spectroscopy):
- Z.Kisiel, O.Dorosh, A.Maeda,
I.R.Medvedev, F.C.De Lucia, E.Herbst, B.J.Drouin, J.C.Pearson,
S.T.Shipman, "Determination of precise relative energies of conformers
of n-propanol by rotational
spectroscopy", Phys.Chem.Chem.Phys. 12,
8329-8339
(2010).
Pyrimidine
(nucleic
acid
backbone molecule):
- Z.Kisiel, L.Pszczolkowski, J.C.Lopez,
J.L.Alonso, A.Maris, and W.Caminati, "Investigation of the rotational
spectrum of pyrimidine from 3 to 337 GHz: Molecular structure, nuclear
quadrupole coupling, and vibrational satellites", J.Mol.Spectrosc.
195,332-339(1999).
- Y-J.Kuan, C-H.Yan, S.B.Charnley,
Z.Kisiel, P.Ehrenfreund, H-C.Huang, "A search for interstellar
pyrimidine", Mon.Not.R.Astron.Soc. 345,650-656(2003).
- Z.Peeters, O.Botta, S.B.Charnley,
Z.Kisiel, Y.-J.Kuan, P.Ehrenfreund, "Formation and photostability of
N-heterocycles in space - I. The effect of nitrogen on the
photostability of small aromatic molecules", Astron. & Astrophys. 433, 583-590 (2005).
Various substituted
benzene derivatives:
- Toluene: V.V.Ilyushin, E.A.Alekseev, Z.Kisiel,
L.Pszczolkowski, "High-J rotational spectrum in |m|<=3 torsional states", J.Mol.Spectrosc. 339, 31-39 (2017).
- V.V.Ilyushin, Z.Kisiel,
L.Pszczolkowski, H.Mader, J.T.Hougen, "A new torsion-rotation fitting
program for molecules with a sixfold barrier: Application to the
microwave spectrum of toluene", J.Mol.Spectrosc.
259, 26-38 (2010).
- Z.Kisiel, E.Bialkowska-Jaworska,
L.Pszczolkowski, H.Mader,
"Ground state rotational spectrum of toluene", J.Mol.Spectrosc.
227, 109-113 (2004).
- Fluorobenzene: Z.Kisiel, E.Bialkowska-Jaworska,
L.Pszczolkowski, "The millimeter-wave rotational
spectrum of fluorobenzene", J.Mol.Spectrosc.
232, 47-54 (2005).
- Z.Kisiel, E.Bialkowska-Jaworska,"Sextic
centrifugal distortion in fluorobenzene and phenylacetylene from
cm-wave rotational spectroscopy", J.Mol.Spectrosc. 359, 16-21 (2019).
- Chlorobenzene,
Bromobenzene, Iodobenzene: O.Dorosh, E.Bialkowska-Jaworska, Z.Kisiel, L.Pszczolkowski, "New measurements and global analysis of rotational spectra
of Cl-, Br- , and I-benzene: Spectroscopic constants and electric
dipole moments", J.Mol.Spectrosc. 246,
228-232
(2007).
- Anisole and
Benzaldehyde: O.Desyatnyk,
L.Pszczolkowski, S.Thorwirth,
T.M.Krygowski, Z.Kisiel,
"The rotational spectra, electric dipole moments and molecular
structures of anisole and benzaldehyde", Phys.Chem.Chem.Phys. 7, 1708-1715 (2005); publisher's
correction Phys.Chem.Chem.Phys.
7, 2080 (2005).
- Phenylacetylene:
Z.Kisiel, A.Krasnicki, "The millimetre-wave rotational spectrum of
phenylacetylene", J.Mol.Spectrosc. 262,
82-88
(2010).
- Z.Kisiel, E.Bialkowska-Jaworska,"Sextic
centrifugal distortion in fluorobenzene and phenylacetylene from
cm-wave rotational spectroscopy", J.Mol.Spectrosc. 359, 16-21 (2019).
- Salicyl aldehyde: O.Dorosh, E.Bialkowska-Jaworska,
Z.Kisiel, L.Pszczolkowski, M.Kanska, T.M.Krygowski, "The complete
molecular geometry and electric dipole moment of salicyl aldehyde from
rotational spectroscopy", J.Mol.Spectrosc. 335, 3-12
(2017).
- Benzonitrile:
M.A.Zdanovskaia, B.J.Esselman, H.S.Lau, D.M.Bates, R.C.Woods,
R.J.McMahon, Z.Kisiel, "The 103-360 GHz rotational spectrum of
benzonitrile, the first interstellar benzene derivative detected by
radioastronomy", J.Mol.Spectrosc. 351, 39-48
(2018).
Sulfur
dicyanide, S(CN)2 (a tutorial in the
study of complex broadband rotational and rotation-vibration spectra with analysis of multiple
Coriolis+Fermi interstate interactions):
- Z. Kisiel, M. Winnewisser, B. P. Winnewisser, F.
C. De Lucia, D. W. Tokaryk, B. E. Billinghurst, ”Far-Infrared Spectrum
of S(CN)2 Measured with Synchrotron Radiation: Global Analysis of the Available High-Resolution Spectroscopic Data”, J. Phys. Chem. A 117, 13815-13824 (2013).
- Z.Kisiel,
O.Dorosh, M.Winnewisser, M.Behnke, I.R.Medvedev, F.C.De
Lucia, "Comprehensive analysis of the FASSST rotational spectrum of
S(CN)2", J.Mol.Spectrosc. 246,
39-56
(2007).
Selected other molecules studied with either the MMW or FTMW (or
both) spectrometers in Warsaw:
- H2C=CClCN: Z.Kisiel and L.Pszczolkowski, "Nuclear quadrupole coupling
in 2-chloroacrylonitrile: inertial and principal quadrupole tensor
components for Cl and N", J.Mol.Spectrosc. 184, 215-220
(1997).
- CH2Cl2: Z.Kisiel, J.Kosarzewski, and L.Pszczolkowski, "Nuclear
quadrupole coupling tensor of CH2Cl2: Comparison
of quadrupolar and structural angles in methylene halides", Acta
Physica Polonica A. 92, 507-516 (1997).
- Chloroform,
HCCl3:
E.Bialkowska-Jaworska, Z.Kisiel and
L.Pszczolkowski, "Nuclear quadrupole coupling in
chloroform and calibration of ab
initio calculations", J.Mol.Spectrosc. 238,
72-78 (2006).
- CHF2I: C.T.Dewberry, Z.Kisiel,
S.A.Cooke, "The pure
rotational spectrum of Difluoroiodomethane, CHF2I", J.Mol.Spectrosc.
261,
82-86 (2010).
- CCl2=CH2:
Z.Kisiel, E.Bialkowska-Jaworska,
L.Pszczolkowski, "Nuclear quadrupole coupling in Cl2C=CHCl
and Cl2C=CH2; Evidence for systematic differences
in orientation between internuclear and field gradient axes for
terminal quadrupolar nuclei", J.Chem.Phys. 109,
10263-10272 (1998).
Z.Kisiel and L.Pszczolkowski, "The
high-frequency rotational spectrum of 1,1-dichloroethylene", Z.Naturforsch.
50A, 347-351 (1995).
- tBuX,
X=F,
Cl,
Br, I, CN, NC: Z.Kisiel,
E.Bialkowska-Jaworska, O.Desyatnyk, B.A.Pietrewicz, L.Pszczolkowski,
"The gas-phase electric dipole moments of the symmetric top tertiary
butyl molecules tBuX, X=F,Cl,Br,I,CN, and NC", J.Mol.Spectrosc.
208, 113-120 (2001).
- 1-F-adamantane: A.C.Legon, J.Tizard, and Z.Kisiel, "Bridgehead distortion at
the C1 position of 1-fluoroadamantane revealed by rotational
spectroscopy and ab initio calculations", J.Mol.Struct. 612,
83-91
(2002).
O. Pirali, Z. Kisiel, M. Goubet, S. Gruet,
M.A. Martin-Drumel, A. Cuisset, F. Hindle, G. Mouret,
”Rotation-vibration interactions in the spectra of polycyclic aromatic
hydrocarbons: Quinoline as a test-case species”, J. Chem. Phys. 142, 104310:1-11 (2015).
Z.Kisiel, O.Desyatnyk, L.Pszczolkowski, C.B.Charnley,
P.Ehrenfreund, "Rotational spectra of quinoline and of isoquinoline:
spectroscopic constants and electric dipole moments", J.Mol.Spectrosc.
217, 115-122 (2003).
- Camphor: Z.Kisiel, O.Desyatnyk, E.Bialkowska-Jaworska,
L.Pszczolkowski, "The structure and electric dipole moment of camphor
determined by rotational spectroscopy", Phys.Chem.Chem.Phys. 5,
1359-1364
(2003).
- Urethane
(ethyl
carbamate): M.Goubet, R.A.Motiyenko,
F.Real, L.Margules, T.R.Huet, P.Asselin, P.Soulard, A.Krasnicki,
Z.Kisiel, E.A.Alekseev, "Influence of the geometry of a hydrogen bond
on conformational stability: a theoretical and experimental study of
ethyl carbamate", Phys.Chem.Chem.Phys. 11,
1719-1728 (2009).
- 1,3-benzodioxole: Z.Kisiel, L.Pszczolkowski,
G.Pietraperzia, M.Becucci, W.Caminati, R.Meyer, "The
anomeric
effect
in 1,3-benzodioxole: additional evidence from the
rotational, vibration-rotation and rovibronic spectra", Phys.Chem.Chem.Phys.
6, 5469-5475 (2004).
- Cyclopropyl cyanide: L.Bizzocchi,
C.D.Esposti, L.Dore, Z.Kisiel, "Submillimetre-wave spectrum,
14N-hyperfine structure, and dipole moment of cyclopropyl cyanide", J.Mol.Spectrosc. 251, 138-144 (2008).
- Acetic
acid/Acetone: O.Dorosh, Z.Kisiel, "Electric
dipole moments of acetone and of acetic acid measured in supersonic
expansion", Acta Physica Polonica A 112,
S95-S104 (2007).
- Glycolic acid: Z.Kisiel, L.Pszczolkowski, E.Bialkowska-Jaworska, S.B.Charnley, "Millimetre wave rotational spectrum of glycolic acid", J.Mol.Spectrosc. 321, 12-32 (2016).
- Lactic
acid: L.Pszczolkowski, E.Bialkowska-Jaworska, Z.Kisiel, "The millimeter-wave rotational spectrum of lactic acid", J.Mol.Spectrosc. 234, 106-112 (2005).
- Pyruvic
acid: Z.Kisiel,
L.Pszczolkowski, E.Bialkowska-Jaworska,
S.B.Charnley, "The millimeter-wave rotational spectrum of pyruvic acid", J.Mol.Spectrosc. 241,
220-229 (2007).
- Pyruvonitrile
(acetyl
cyanide): A.Krasnicki, L.Pszczolkowski, Z.Kisiel,
"Analysis of the rotational spectrum of pyruvonitrile up to 324 GHz", J.Mol.Spectrosc. 260, 57-65 (2010).
- 2,2-dichloropropane, (CH3)2CCl2:
E. Bialkowska-Jaworska, L. Pszczolkowski, Z. Kisiel, ”Comprehensive
analysis of the rotational spectrum of 2,2-dichloropropane”, J. Mol. Spectrosc. 308-309, 20-27 (2015).
- CF3CH2Cl: I.Uriarte, Z.Kisiel, E.Bialkowska-Jaworska, L.Pszczolkowski, P.Ecija, F.J.Basterretxea, E.J.Cocinero, "Comprehensive rotational spectroscopy of the newly identified atmospheric ozone depleter CF3CH2Cl", J.Mol.Spectrosc. 337, 37-45 (2017).
- CF3CCl3: Z.Kisiel, L.Pszczolkowski, E.Bialkowska-Jaworska, I.Uriarte, F.J.Basterretxea, E.J.Cocinero, "Rotational spectroscopy update for the newly identified atmospheric ozone depleter CF3CCl3", J.Mol.Spectrosc. 352, 1-9 (2018).
- 2-chloropropene: Z.Kisiel, J.Kosarzewski, "Identification of trace 2-chloropropene with a new chirped pulse microwave spectrometer", Acta Physica Polonica A 131,
311-317 (2017).
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