Chemistry Reference
In-Depth Information
41. Segawa Y, Miyamoto S, Omachi H, Matsuura S,
ˇ
enel P, Sasamori T, Tokitoh N, Itami K
(2011) Concise synthesis and crystal structure of [12]cycloparaphenylene. Angew Chem Int
Ed 50(14):3244-3248
42. Segawa Y, Senel P, Matsuura S, Omachi H, Itami K (2011) [9]Cycloparaphenylene: nickel-
mediated synthesis and crystal structure. Chem Lett 40(4):423-425
43. Sisto TJ, Golder MR, Hirst ES, Jasti R (2011) Selective synthesis of strained [7]cyclopar-
aphenylene: an orange-emitting fluorophore. J Am Chem Soc 133(40):15800-15802
44. Hitosugi S, Nakanishi W, Isobe H (2012) Atropisomerism in a belt-persistent nanohoop
molecule: rotational restriction forced by macrocyclic ring strain. Chem Asian J 7:1550-2
45. Ishii Y, Nakanishi Y, Omachi H, Matsuura S, Matsui K, Shinohara H, Segawa Y, Itami K (2012)
Size-selective synthesis of [9]-[11] and [13]cycloparaphenylenes. Chem Sci 3:2340-2345
46. Matsui K, Segawa Y, Itami K (2012) Synthesis and properties of cycloparaphenylene-2,5-
pyridylidene: a nitrogen-containing carbon nanoring. Org Lett 14(7):1888-1891
47. Yagi A, Segawa Y, Itami K (2012) Synthesis and properties of [9]cyclo-1,4-naphthylene: a
π
-extended carbon nanoring. J Am Chem Soc 134(6):2962-2965
48. Segawa Y, Fukazawa A, Matsuura S, Omachi H, Yamaguchi S, Irle S, Itami K (2012)
Combined experimental and theoretical studies on the photophysical properties of cyclopar-
aphenylenes. Org Biomol Chem 10:5979-84
49. Xia J, Jasti R (2012) Synthesis, characterization, and crystal structure of [6]cyclopara-
phenylene. Angew Chem Int Ed 51(10):2474-2476
50. Swager TM, Han GD (2011) The smaller the redder. Synfacts 2011(12):1309-1309
51. Sisto TJ, Jasti R (2012) Overcoming molecular strain: synthesis of [7]cycloparaphenylene.
Synlett 23(EFirst):483-489
52. Li H-B, Page AJ, Irle S, Morokuma K (2012) Theoretical insights into chirality-controlled
SWCNT growth from a cycloparaphenylene template. Chemphyschem 13(6):1479-1485
53. Tian X, Jasti R (2011) Cycloparaphenylenes: the shortest possible segments of armchair
carbon nanotubes. In: Petrukhina MA, Scott LT (eds) Fragments of fullerenes and carbon
nanotubes. Wiley, Hoboken, pp 291-309
54. Bachrach SM, St¨ck D (2010) DFT study of cycloparaphenylenes and heteroatom-substituted
nanohoops. J Org Chem 75(19):6595-6604
55. Segawa Y, Omachi H, Itami K (2010) Theoretical studies on the structures and strain energies
of cycloparaphenylenes. Org Lett 12(10):2262-2265
56. Jasti R, Bertozzi CR (2010) Progress and challenges for the bottom-up synthesis of carbon
nanotubes with discrete chirality. Chem Phys Lett 494(1-3):1-7
57. Sundholm D, Taubert S, Pichierri F (2010) Calculation of absorption and emission spectra of
[n]cycloparaphenylenes: the reason for the large Stokes shift. Phys Chem Chem Phys 12
(11):2751-2757
58. Wong BM (2009) Optoelectronic properties of carbon nanorings: excitonic effects from time-
dependent density functional theory. J Phys Chem C 113(52):21921-21927
59. Friederich R, Nieger M, V¨gtle F (1993) Auf dem Weg zu makrocyclischen para-phenylenen.
Chem Ber 126(7):1723-1732
60. Ellis KK, Wilke B, Zhang Y, Diver ST (2000) A new method for the synthesis of
imidazolidinone- and benzimidazolone-containing [2.2]cyclophanes. Org Lett 2(24):3785-3788
61. Alonso F, Yus M (1992) Easy synthesis of 2,4-dialkyl substituted phenols and anisoles from
p-bensoquinone. Tetrahedron 48(13):2709-2714
62. Nijegorodov NI, Downey WS, Danailov MB (2000) Systematic investigation of absorption,
fluorescence and laser properties of some p- and m-oligophenylenes. Spectrochim Acta A Mol
Biomol Spectrosc 56(4):783-795
63. Yamago S, Watanabe Y, Iwamoto T (2010) Synthesis of [8]cycloparaphenylene from a
square-shaped tetranuclear platinum complex. Angew Chem Int Ed 49(4):757-759
64. Jagadeesh MN, Makur A, Chandrasekhar J (2000) The interplay of angle strain and aromatic-
ity: molecular and electronic structures of [0n]paracyclophanes. J Mol Model 6(2):226-233
