Two works are included in this thesis: The first part is to use an orthogonal acceleration reflectron time-of-flight mass spectrometer and soft X-rays from synchrotron radiation to measure near-edge X-ray absorption fine structure (NEXAFS) spectra of carbon atoms in dipeptide isomers, Gly−Phe and Phe−Gly. NEXAFS spectroscopy has been proved to provide a sensitive technique for determining the electronic structure of matter accurately and for chemical analysis. The NEXAFS spectra were recorded in the vicinity of the carbon K-edge, and the specific dissociation of Gly-Phe and Phe-Gly were explored based on the signal intensity of each product ion and the branching ratio of fragments. Three kinds of absorption properties were deduced according to the core electrons of the specific carbon atoms. They included aromatic rings, carbonyl groups and the side chain of Phenylalanine. Their assignment were πC = C* (Cring)、πC = O* and the mixing of σC-H* of the saturated bonding carbon atoms on the Phenylalanine side chain and the unsaturated bonding carbon atoms repectively. The second part is the design, assembling and sample source stability testing of the aerosol injection system. Such differential pumping plays an important role to the injection devices and the real pressures is the vacuum chambers. In differential pumping mathematics and measured results, the difference is between the values of evaluated 3.9×10-7 Torr and the 1.6×10-6 Torr of detection chamber pressure. Besides, the assembly of aerodynamic lens (ADL) to converge aerosol particles into bundles, which are instantaneously vaporized by a fast heat conduction effect occurs with a collimated particle beam. ADL also can solve the problem of thermal instability of nonvolatile biomolecules. The stability of particle size should be remained at long-term maintain. In the case of disproportionate aerosol particle concentration, it is found that the concentration of aerosol is not a factor affecting the stability. The stability of the aerosol concentration could last for more than four hours.