Ultra-low-power-consumption and high-speed DCFL circuits have been fabricated by using 0.2-µm Y-shaped gate E/D-heterojunction-FETs (HJFETs) with a high-aspect-ratio gate-structure, which has an advantage of reducing the gate-fringing capacitance (Cf) to about a half of that of a conventional low-aspect-ratio one. A fabricated 51-stage ring oscillator with the 0.2-µm Y-shaped gate n-AlGaAs/i-InGaAs E/D-HJFETs shows the lowest power-delay product of 0.21 fJ with an unloaded propagation delay of 34.9 ps at a supply voltage (VDD) of 0.4 V. We also analyze the DCFL switching characteristics by taking into account the intrinsic gate-to-source capacitance (Cgsint) and the Cf. The analysis results for the power-delay products agree well with our experimental results. Our analysis also indicates the DCFL circuit with the high-aspect-ratio Y-shaped gate E/D-HJFETs can reduce the power-delay products by 35% or more below 0.25-µm gate-length as compared to conventional ones with the low-aspect-ratio Y-shaped gate HJFETs. These results clarify that the Cf-reduction of the Y-shaped gate HJFETs is more effective in improving the power-delay products than reducing the gate-length.