The state-of-the-art spin mapping technique of spin-polarized scanning tunneling microscopy (SP-STM) and spectroscopy (SP-STS) can provide information on magnetic domain and electronic structure with extremely high spatial resolution. This essentiality is desperate for the studying of interplay between structural, electronic and magnetic properties in various fascinating low dimensional magnetic systems within nanometer scale. In addition, the potentiality of this tool is possessed of high technological relevance in the respect of magnetic datastorage engineering and spintronic devices developing. In this dissertation work, the implementation with improved functionality of such versatile investigation tool has been realized in two different ultrahigh vacuum (UHV) STM chambers individually. Furthermore, the applications in the resolving spin structures of antiferromagnetic (AFM) manganese (Mn) ultrathin films and FM cobalt (Co) nanoislands have been demonstrated. In the first part of this dissertation, electronically patterning through one dimensional (1D) alumina nanostripes with high density of states (DOS) is presented. With low oxygen gas dosage on NiAl(001) substrate kept at high temperature, the single-crystalline Al2O3 domain with 1D nanostripes can be grown. From the bias dependent topographies and tunneling spectroscopy measurements, higher DOS of nanostripes than that of Al2O3 domain has been found. By using this electronic property, such nanostripes can construct an 1D electronically patterning template to have Co nanoparticles grown with self-alignment. In addition, single electron tunneling behavior of Coulomb blockade and nonuniform distribution of electronic structures within single Co nanoparticle have also been investigated accordingly. For the layered AFM spin structures of both bct and fct Mn with out-of-plane c-axis expansion resolved by SP-STM are included in the second part of this dissertation. With the ring shaped tip simply made by bending tungsten (W) wire,not only atomic resolution of different substrates in STM, but also the in-plane spin identification of magnetically coated ring shaped tip in SP-STM can be successfully achieved. After the room temperature SP-STM work on expanded bct (e-bct) Mn/Fe(001) substrate, the low temperature (77.5K) SP-STM work on e-fct Mn/Co/Cu(001) exchange-biased ultrathin films system is introduced. Due to epitaxially grown on and directly coupled with Co(001) films, not only the in-plane layered AFM spin structure of e-fct Mn ultrathin films, but also the spin frustration across same Mn layer due to the hidden steps of Co underlayers are investigated. The induced domain wall width from spin frustration phenomenon is fitted and in consistent with simulated micromagnetic OOMMF results. Triangular Co nanoislands with bilayer height can be grown on Cu(111) substrate and corresponding out-of-plane magnetic domain images have been resolved by SP-STM at 4.5 K. By using direct magnetic interactions with these single domain Co nanoislands in reduced tunneling distance, the in situ magnetization switching of most front soft magnetic tip end atoms is reliably controlled without applying external magnetic field. Besides, according to the spin-resolved tunneling spectroscopy measurements, not only the shift of spin-polarized surface state, but also non-collinear spin structures within single Cu covered Co island have been found. In addition, for the two connected Co nanoislands with antiparallel spin alignment, there is a competition between exchange coupling and dipolar interaction in the correlation with contact length and area size difference, respectively. After calculating by magnetic dipolar formula and simulation of corresponding magnetic field distribution, dipolar interaction is able to compete with ferromagnetic ordering energy and result in such dipolar antiferromagnetism of two Co nanoislands in close proximity. In the last, we evaporated organic molecule manganese phthalocyanine (MnPc) on these Co nanoislands and MnPc molecules show the preference of adsorption on magnetic Co nanoisland instead of the Cu(111) substrate at 4.5 K. The MnPc being spin-polarized through underneath Co nanoisland has been measured and major contribution to the magnetic asymmetry comes from the spin-polarized adsorption state near to the Fermi energy level.