This research is based on investigations of the fourth generation refrigerant R-1234ze that is considered to substitute R-134a due its low GWP which is as low as 7 in a microfin tube with outer diameter 9.52 mm, number of fins 70, and fin height 0.17 mm. In comparison, a smooth tube with similar geometries was used to study the pressure drop and the enhancement of heat transfer coefficients related to the two fluids. The microfin tube was brazed inside a stainless steel tube and heated electrically with direct current. T-type thermocouples were inserted in the wall to measure the temperature distribution during the phase change process. The experimental measurements were carried out at constant saturation temperatures of 10 – 200C by varying the refrigerant mass velocities between 50 kg/m2s and 300 kg/m2s, the vapor quality from 0.1 to 0.9, and heat flux range from 5 kW/m2 to 11 kW/m2. Results from the two refrigerants and tubes were analyzed and compared basing on the values of the two-phase heat transfer coefficient and pressure drop. The results showed that heat transfer performance of R-134a in both microfin and smooth tube was better than R-1234ze especially at mass velocities above G = 50 kg/m2s. However, at certain low mass velocities below G = 100 kg/m2s R-1234ze yield better heat transfer coefficients than R-134a. The pressure gradient of R-1234ze was markedly higher than that of R-134a at all mass flow rates and heat flux had no strong effect on friction pressure drop for R-134a whereas at low mass flux G = 50 kg/m2s, R-1234ze slightly registered an increase in pressure drop for higher heat flux q = 5 kW/m2. Saturation temperatures had no effect on heat transfer for both refrigerants at high mass flux whereas at lower mass flux G = 50 kg/m2s, R -134a dry-out inception was a bit longer for about x = 0.9 compared to that of R-1234ze. Murata et al. correlation showed the best thermal performance prediction of the data with E%= 28.9 and σ% = 37.2 for R-1234ze in a microfin tube whereas Kandlikar et al. predicted well the experimental data with the lowest E%= 24.9 for R-134a in the same microfin tube. For comparison purpose with R-1234ze in a smooth tube of similar geometries, Shah Correlation had the best thermal performance with an average percentage error of E%= 19.1 whereas Thome and Chisholm correlations slightly over-predicted and under-predicts respectively the experimental data at low pressure values.