The magnetocaloric effect (MCE) is characterized by a magnetic entropy change and an adiabatic temperature change. The NaZn13-type La(Fe,Si)13 system has attracted wide interest because of its first-order ferromagnetic phase transition with a large magnetocaloric effect. The transition temperature can be flexibly adjusted through substitution or interstitial insertion. Particularly, hydrogen interstitials can adapt the temperature range to room-temperature applications. Precise adjustment can be achieved by full hydrogen absorption then partial desorption. However, fully hydrogenated alloys are unstable upon heating. It is important to have a better understanding of its hydrogen stability to optimize its application potential.In the first part, the structural, magnetic, and magnetocaloric properties of La(Fe,Si)13 phases are studied. In particular, we have investigated the effect of substitution of Ce on the La site and Mn on the Fe sites. The partial substitution of Ce results in the decrease of TC with decreasing lattice constant. At the same time, Ce substitution for La results in a reduced volume of the octahedral interstitial site due to steric effect. The interstitial insertion is impeded by Ce partial substitution.Secondly, the effects of interstitial atoms such as hydrogen and carbon are examined. These elements are able to enter the interstitial voids in the La(Fe,Si)13 phase, expanding the lattice. Through the extension of Fe-Fe distances, the Curie temperature of the magnetocaloric phase can be raised up to room temperature range. The influence of small concentration of carbon on the magnetic properties of samples is examined prior to hydrogenation and carbon content is optimized. In order to investigate the interstitial dynamics, the hydrogen sorption kinetics is studied by the means of Sieverts’ volumetric method and neutron diffraction. Particular attention has been given to the adjustment of the structure in the course of hydrogen/deuterium interstitial absorption and desorption.Steady-state and in-situ neutron diffractions provide precise information of the interstitial atom location of the sequential filling of the accommodating sites. The structural investigation allows specifying the deformations undergone in the complex metallic alloys La-Fe-Si when subjected to light interstitial insertion or rare earth substitution at the cation site. We show that the depression or enhancement of the hydrogenation kinetics may be related to the particular inhomogeneous cell variation of bonding in the structure. A mechanism for the diffusion path is suggested.The mechanism is light atom insertion into the interstitial sites is not only strongly related to the available space for accommodation, but also associated with the facility of the diffusion path in the lattice. We demonstrate with experimental results that a modest addition of carbon in the La-Fe-Si phase prior to hydrogenation can effectively slow down the hydrogen insertion kinetics. In Ce-substituted La-Ce-Fe-Si phases, carbon insertion can help retain hydrogen atoms during desorption, therefore, offering a prospect to have improved stability of hydrogenated materials for long-term applications. The hydrogen stability of the material is examined by means of thermal desorption in DSC and an enhancement of the thermal stability of the material is achieved with carbon-doping.Lastly, in the search of new rare-earth-free materials for magnetocaloric applications, we have explored the capacity of alloys of types FeCrNi and FeCrMn. The magnetic and structural transitions of these alloys of different compositions are studied and their potential for magnetocaloric application is examined in this thesis.