Photodoping of YBa2Cu3Ox: Dependence on temperature and photon energy

Autor(en)

Wilhelm Markowitsch, P. Brantner, Wolfgang Lang, Khurram Siraj, A Moser, Johannes D. Pedarnig

Abstrakt

We present studies of the photodoping process in underdoped metallic YBa2Cu3Ox, where x¿6.6. Measurements of the time-dependent electrical resistivity during photoexcitation were performed at several temperatures and with two different lasers as the light source. The effect of photodoping on the samples was characterized by the resistivity reduction ?R(N)/R(0) and by the enhancement ?Tc of the superconducting transition temperature for a fixed photon dose of N = 1.2 × 1023 cm-2. At low temperatures, we observed a large ?R(N)/R(0) but a small ?Tc. In the intermediate temperature range, both quantities were relatively small. At the highest studied temperature (270 K), ?Tc reached the largest values in these experiments, and ?R(N)/R(0) was almost as large as at low temperatures. Interestingly, only at low temperatures did we observe a significant dependence of ?R(N)/R(0) on the laser wavelength ?, whereas ?T c is essentially independent of ?. The time dependence of the resistivity during the photoexcitation showed a stretched-exponential decrease at all temperatures, with values of the dispersion parameter ß between 0.3 and 0.55, which are distinctly smaller than observed in persistent photoconductivity relaxation in YBa2Cu3Ox. ß was essentially the same for the two laser wavelengths and showed only a weak temperature dependence. We observed a tendency of ß towards smaller values (¿0.4) at low temperatures and to slightly higher values (¿0.5) above approximately 200 K. We interpret this finding within a microscopic theory of the stretched-exponential parameters, and conclude that there is a long-range interaction between the photoexcited electrons and the chain defects, which act as trapping centres and that the traps become mobile at high temperatures. © IOP Publishing Ltd.

Organisation(en)

Elektronische Materialeigenschaften

Externe Organisation(en)

Johannes Kepler Universität Linz

Journal

Superconductor Science & Technology

Band

21

Anzahl der Seiten

6

ISSN

0953-2048

DOI

https://doi.org/10.1088/0953-2048/21/7/075017

Publikationsdatum

2008

Peer-reviewed

Ja

ÖFOS 2012

1030 Physik, Astronomie, 103018 Materialphysik

Link zum Portal

https://ucrisportal.univie.ac.at/de/publications/89622a4a-492c-4904-aa0e-07512dd379a1