This letter describes the scaling behavior and Josephson properties of improved YBCO/PBCO/ YBCO edge-type junctions. The critical current, normal-state resistance, and I& product scale with barrier thickness and junction area. The coherence length of the PBCO barrier is estimated to be between 5 and 8 nm. As unambiguous evidence of the Josephson behavior, the microwave response as a function of microwave power, as well as the current modulation with applied magnetic field, have been studied: well-developed Shapiro steps at 10 GHz have been observed, and the modulation of I,(H) shows Fraunhoferlike behavior with 95% Ic suppression.We have previously reported the fabrication of highquality epitaxial, all high-l', edge-type YBa&!usO, (YBCO)/PrBa&!u~O,(PBCO)/YBCO Josephson junctions,"' prepared with our modified off-axis sputtering technique.3s4 These junctions have shown Josephson behavior up to rather high temperatures, and dc SQUIDS with such junctions are promising for practical applications. However, the physical properties of these junctions are far from clear. For fabrication of really controllable and uniform junctions, these properties must be studied. The scaling behavior, intrinsic parameters, and magnetic field modulation, as well as the microwave response of our edge junctions, are presented here. the intrinsic nature of the PBCO might play a role.Our junctions show good uniformity in the scaling of the critical current and the inverse normal resistance with the junction area, defined as A = wXd/sin i) (w is the junction width, d is the thickness of the base electrode, and 6 is the angle of the junction edge). This is shown in Fig. 1 for junctions with the same barrier thickness. The values for the smallest junctions may be somewhat too low due to the larger influence of the damaged edge by ion etching. At any rate, Fig. 1 demonstrates uniform behavior with different junction areas.The dependence of J, on the-R;Rk product has -been investigated as well. The data shown in Fig. 3 are distributed along the line J,-(R&) -m, with m = 1.2. For SNS structures with L&, one would expect J,-(Rd) -2, whereas for superconductor/insulator/normal-metal/ superconductor (SINS) structures J,-(R&) -' (Refs. 5 and 6). The observed dependence differs from the predjction for SNS structures and more closely resembles that for SINS structures. On the other hand, the temperature dependence of the critical-current density,.-( 1 -T/T,)', is in good agreement with the SNS type model, as we reported earlier.' This discrepancy may 'be attributed to the interface resistance between the base elcctrode and PBCO barrier, and the influence of the speci:iic resistance of PBCO, which may be different for Lscn or
Lci5rIn addition, the I,$, products have been found to scale nearly linearly with L, ranging from 0.8 to 5 mV. TG highest values obtained were 8 mV. The damage of the edge surface due to our ex situ process could also detri-A strong dependence of the critical current density J, on the PBCO barrier thickness L has been observed....
