With the popularity of wearable products, photovoltaic energy harvesting is an attractive method to develop battery-free systems or prolong battery life, such as wireless sensors, biomedical electronics, and the internet of things (IoT). To sustain normal operation with a limited power budget, low-power digital circuits operating in the near/sub-threshold region are widely used in such applications. Therefore, the design of a low-voltage high efficiency buck converter which converts the harvested energy to the regulated output is dispensable. On the top of that, the conversion efficiency under ultra-light load becomes significant to increase system standby time. In this work, a dual-mode digital buck converter for photovoltaic energy harvesting with a maximum conversion efficiency of 90.2% is proposed. The input voltage (VIN) is targeted at 0.55−1.0V to meet the maximum power point voltages of the photovoltaic cell. The output voltage (VOUT) ranges from 0.35−0.5V, so that near/sub-threshold CMOS digital circuits utilize photovoltaic energy effectively. By integrating digital pulse-width modulation (DPWM) and the proposed predetermined pulse-frequency modulation (PPFM) together, the dual-mode digital buck converter provides wide output range from 100nA to 30mA, while achieving more than 75% efficiency from 300nA to 30mA, that is, in this range the proposed converter provides a high conversion efficiency which is higher than ideal low dropout linear regulator’s under same conversion ratio. In addition, the proposed PPFM calculates the off-time of the power transistor in advance without any zero-current detection circuit, thus reducing the power budget in conventional PFM. Compared with the conventional approaches, the proposed method has a very little power consumption in order to improve the efficiency under ultra-light. Thus, the converter provides a 15.1% higher conversion efficiency than previous work.