Orthogonal frequency division multiplexing (OFDM) and orthogonal frequency division multiple access (OFDMA) have been adopted as a modulation technique in many wireless communication standards. In most OFDM systems, cyclic prefix (CP) samples are added at the transmitter so that simple channel equalization can be used at the receiver. Besides CP, zero padding (ZP) has been proposed as an appealing alternative to the traditional cyclic prefix (CP) OFDM to ensure symbol recovery regardless of the channel nulls. However, OFDM-based systems (no matter CP or ZP) are sensitive to synchronization errors, such as carrier frequency offset (CFO). In the uplink OFDMA systems, the received signal at the base station (BS) is composed of all active users with individual CFO. CFO induces both intercarrier interference (ICI) and multi-access interference (MAI), which degrade the performance of systems significantly. Therefore, accurate estimation of these synchronization errors are important. In this thesis, receiver design and CFO estimation methods in ZP-OFDM/OFDMA systems are studied. Training sequence, virtual carriers, and blind methods are considered. In the first part, two receivers are designed for ZP-OFDM system with a tradeoff between performance and implementation complexity. Then, we show how much complexity is reduced. In the second part, we extend several CFO estimation methods from CP-OFDM to ZP-OFDM. These methods include channel residual energy(CRE-based), virtual carrier(VC-based) and frequency analysis(FA-based) methods. For FA method, a low complexity closed-form solution is developed for CFO estimation in ZP-OFDM. In addition, we develop a new null-space method to estimate CFO for ZP-OFDM. In the third part, we propose receivers and a joint estimation of CFO and channel response in ZP-OFDMA systems. Numerical simulations are provided to verify the performances of the proposed methods.