This thesis consists of an introduction, four chapters and a conclusion, with each chapter covering a different topic. In the introduction, we introduce the various limitations of the conventional photodetectors that we study in the later chapters. In chapter 2, we demonstrated Si MSM PDs with ZnO nanorod arrays (NRAs) as a top layer, which absorbs the UV photons (photon energy > band gap of ZnO) effectively and serves as an ARC layer, providing an effective refractive-index gradient between Si and air in the long-wavelength region (photon energy < band gap of ZnO), enabling broadband detection with greatly enhanced responsivity. The responsivity of Si MSM PDs is increased by up to 3 orders of magnitude in the UV region and by 2 orders of magnitude in the visible/NIR regions due to ZnO NRA layers. The huge enhancement of broadband detection by Si MSM PDs with ZnO NRAs could allow the low-cost production of photonic devices and extend the application potential for Si-based optoelectronic devices. In chapter 3, the visible-blind UV PDs employing n-ZnO/LaAlO3 (LAO)/p-Si double heterojunction using pulse laser deposition (PLD) are presented. The n-ZnO/LAO/p-Si PDs exhibit visible-blind UV responsivity with the cutoff wavelength of responsivity at 380 nm, corresponding to the near band edge (NBE) absorption of ZnO. Inserted 10-nm-thick LAO layers effectively eliminate visible light responses via blocking the electrons excited by visible photons in p-Si near the interface owing to the high potential barrier between p-Si and LAO layers (~2.0 eV). This study paves the way for visible-blind UV photosensing applications under outdoor lighting. In chapter 4, we report few-layer MoS2 Schottky PDs with back-to-back MSM geometry, capable of broadband photodetection from visible to UV regions with working temperatures up to 200 °C for use in harsh environments. Until few-layer MoS2 is demonstrated here, the broadband responsivity feature is not previously achievable for harsh environment use since all of photodetection materials for harsh environments are wide-bandgap semiconductors. As a new record, the responsivity of 5.7 A/W, has never been obtained in 2D nanomaterial-based PDs due to very high optical absorption of ~10% (very high absorption coefficient of up to 7.5×105 cm-1) of the few-layer MoS2 and a high photogain of ~13.3. In addition, temporal measurements reveal fast response times (~70 μs) and recovery times (~110 μs). The excellent optical properties of few-layer MoS2 promise a new generation of fast, broadband PDs based on 2D nanomaterials for the applications in harsh environments, such as sensing, imaging, and intrachip optical interconnects at the high temperatures. In chapter 5, we demonstrate the Schottky PDs with back-to-back metal-semiconductor-metal (MSM) geometry by employing AlN thin films on Si(100) substrates from reactive sputtering deposition with working temperature up to 300 °C for use in solar-blind UV detection and harsh environments. For 2 MeV proton irradiation, the PDCR value of AlN MSM PDs is 0.7 under a 5 V bias at proton fluences up to 1013 cm-2, indicating that the PDs are well suited for space applications. The AlN MSM PDs show a fast and stable photoresponse, i.e., ~110 ms of the rise time and ~80 ms of the fall time at 5 V bias. This study paves the way for fast and solar-blind photosensing in the space environment and high-temperature conditions.