在本論文的研究中我們展示了兩個新穎的光電發射器,一個是利用低溫成長砷化鎵(LTG-GaAs)為基材的分離式傳輸複合光二極體(STR-PD) ,另一者是以砷化鎵/砷化鋁鎵(GaAs/AlGaAs)為基材的單載子傳輸光二極體(UTC-PD)。此兩種元件結合槽孔式的單極圓碟微波天線,其具有無需要整合在Si-lens的優點。藉由中心波長為800nm超快速飛秒光脈衝光訊號的激發下,我們的光電發射器可幅射出一個強而有力的次兆赫波脈衝訊號(最大功率20mW)和一個較寬的頻帶(100GHz到250GHz)。並由兆赫波時域光譜(TDS)系統量測並轉換成頻域訊號,此頻域訊號可應用在兆赫波資料連結系統內。而當元件操作在逆偏下,此光電發射器的峰值功率(峰值電場平方)隨著外加偏壓有顯著的變化,並經由訊號歸一化分析後,我們可以清楚的看到峰值功率與外加逆偏壓呈現一線性關係,此線性現象對於我們調制光次兆赫波的傳輸資料,有很大的益助。 In this paper, we demonstrated two novel photonic transmitters; one is composed of low-temperature-grown GaAs (LTG-GaAs) based separated-transport-recombination photodiode (STR-PD) and the other is GaAs/AlGaAs based Uni-traveling-carrier photodiode (UTC-PD). Both devices are integrated with broadband micromachined monopole antennas but without the integration with Si-lens. Under femto-second optical pulse illumination which the wavelength of around 800nm, the photonic-transmitter can radiate strong sub-THz pulses (20mW peak-power) with a wide bandwidth (100~250GHz). Such result was directly measured by a THz-TDS system, which could be used as a THz UWB data link system. The bias dependent high-peak-power performance of our device implies its application of photonic emitter and data modulator in photonic sub-THz UWB system.
