In this paper, we investigate the effects of chromatic dispersion on the temporal wave functions (TWFs) of single photons in the context of quantum communications. We start by considering TWFs defined by generalized Gaussian modes. From this framework, we derive two specific models: chirped and unchirped Gaussian TWFs. In the first case, we explore the impact of the chirp parameter on the properties of single-photon TWFs. We show that by properly adjusting the chirp parameter, it is possible to compensate for the detrimental effects of chromatic dispersion, allowing for the maintenance of high-fidelity transmission of quantum information over long distances. Furthermore, we examine the effects of chromatic dispersion on a qubit defined in the time domain, illustrating how this phenomenon can influence the transmission of information encoded in time-bins. Finally, we consider non-Gaussian TWFs that are represented by hyperbolic-secant modes. Our results provide important insights into the design and implementation of high-speed and long-distance quantum communication systems. The findings underscore the potential for using chirp management techniques to mitigate the effects of chromatic dispersion.