This thesis holds the subject of magnonics, a research field investigating spin waves (SWs) transport in magnetic materials for potential future beyond CMOS technologies. The aim of my work relies on the generation, propagation, and detection of spin waves in ferromagnetic and antiferromagnetic materials, with a specific focus on Yttrium Iron Garnet (Y₃Fe₅O₁₂, known as YIG) and Hematite (α- Fe₂O₃). As a consequence, three main results have been achieved: 1. Time of flight spectroscopy on YIG: We introduce a method for extracting time-domain information on propagating spin-wave packets using a Vector Network Analyzer. The approach involves the inverse Fourier Transform of frequency domain data, showing its utility within the commercially available VNAs. We therefore conduct measurements on a 500 nanometer-thick YIG film, a well-known system in the aim to validate the technique's application. It results in isolating a single SW mode profile from a complex spectrum, enabling the identification of mode origins in addition to conducting individual mode study through time gating. From these results we were able to provide a better understanding of the SWs behavior in a YIG delay line, and therefore tailoring the antennas design according to the needed application. 2. Non-degenerated, non-reciprocal and ultra-fast spin-waves in Hematite:Spin waves in AFM have also been investigated for years, yet experimental observations are still lacking. Canted AFM, such as hematite with the presence of bulk Dzyaloshinskii-Moriya interaction and under applied magnetic fields, allow a dipole exchange regime of AFM spin waves. In this thesis, we were able to detect and demonstrate the presence of ultra-fast nonreciprocal SWs in this regime using inductive means of detection on a bulk Hematite. By using time-of-flight spectroscopy we find that the magnon wave packets can propagate as fast as 20 km/s for reciprocal bulk modes and up to 6 km/s for surface modes propagating parallel to the Néel vector. These findings can push forward the field of antiferromagnetic magnonics, and in unravelling the rich physics of coherent SWs. 3. Magnon spintronics on Hematite: An alternative technique to the inductive measurements to detect the spin waves can be done by using an electrical detection of antiferromagnetic spin-waves. This is achieved by using a platinum-based metallic transducer via the inverse spin hall effect. The response’s output voltage on Hematite is comparable to that obtained in ferromagnets like YIG, marking an efficient electrical detection of propagating spin-waves through the surface-sensitive inverse spin-Hall effect with a platinum-based metallic transducer. Another effect was also achieved in this thesis that is the realization of spin diode rectification in Hematite. In this work we evidence that as expected the Oersted field excitation dominates over spin-torque effects in the case of a single crystal. We also observe the presence of non-linear effects when pumping the system with high powers. To go further, we examine by simultaneously applying both AC and DC currents, the DC dependent characteristics of the system to validate our statements. These mentioned features further demonstrate that spin-pumping effects represent a promising tool to detect the spin-wave dynamics in antiferromagnets, and favorize their integration in magnonic devices. With these findings, we aim to unlock the potential for future advancements in radiofrequency applications, paving the way for the development of ultrafast magnonic and magnon spintronic based research for future ICT technologies.