TY - GEN
T1 - Coherence and decoherence in de Broglie interference of fullerenes
AU - Arndt, Markus
AU - Nairz, Olaf
AU - Petschinka, Julia
AU - Voss-Andreae, Julian
AU - van der Zouw, Gerbrand
AU - Keller, Claudia
AU - Zeilinger, Anton
N1 - Zeitschrift: IQEC, International Quantum Electronics Conference Proceedings
Coden: IQECE
Affiliations: Universitat Wien, Wien, Austria
Adressen: Arndt, Markus; Universitat Wien Wien, Austria
Source-File: QFPScopus_iso.csv
Import aus Scopus: 2-s2.0-0033710393
Importdatum: 27.11.2006 19:29:43
25.02.2008: Datenanforderung 2152 (Import Sachbearbeiter)
PY - 2000
Y1 - 2000
N2 - Summary form only given, as follows. In a recent experiment we were able to demonstrate the de Broglie wave character of the fullerene molecule C/sub 60/ by diffraction at a free standing material grating. This proves that it is possible to preserve quantum coherence almost completely in the external degrees of freedom of a hot, massive and complex object over a long time and distance. This may seem astonishing in the light of the fact that the fullerenes were produced in a thermal source which was kept at about 900 K. At such a high temperature the de Broglie wavelength is about 400 times smaller than the size of the molecule (/spl lambda//sub dB//spl sim/25 pm), all internal degrees of freedom (174 different vibrational modes, and rotational modes up to J>100) are excited and the molecules may emit a few infrared photons (blackbody radiation and vibrational quanta) during their time of flight through the apparatus. Our published measurements so far have been essentially consistent with the absence of decoherence during the time of flight of the molecules. The interference contrast in all experiments has however so far been limited by the thermal velocity spread and the finite collimation of the fullerene beam.
AB - Summary form only given, as follows. In a recent experiment we were able to demonstrate the de Broglie wave character of the fullerene molecule C/sub 60/ by diffraction at a free standing material grating. This proves that it is possible to preserve quantum coherence almost completely in the external degrees of freedom of a hot, massive and complex object over a long time and distance. This may seem astonishing in the light of the fact that the fullerenes were produced in a thermal source which was kept at about 900 K. At such a high temperature the de Broglie wavelength is about 400 times smaller than the size of the molecule (/spl lambda//sub dB//spl sim/25 pm), all internal degrees of freedom (174 different vibrational modes, and rotational modes up to J>100) are excited and the molecules may emit a few infrared photons (blackbody radiation and vibrational quanta) during their time of flight through the apparatus. Our published measurements so far have been essentially consistent with the absence of decoherence during the time of flight of the molecules. The interference contrast in all experiments has however so far been limited by the thermal velocity spread and the finite collimation of the fullerene beam.
U2 - 10.1109/IQEC.2000.907954
DO - 10.1109/IQEC.2000.907954
M3 - Contribution to proceedings
SN - 0-7803-6318-3
T3 - International Quantum Electronics Conference (IQEC)
BT - Conference digest
PB - IEEE
CY - Piscataway, NJ
ER -