In this dissertation, we investigated some applications based on the label – free detection properties between deoxyribonucleic acids (DNA) and 2D materials such as graphene and MoS2. In the first part, we developed the high transconductance and low noise of graphene based field effects transistors based on large area monolayer graphene prepared by chemical vapor deposition (CVD) process. The results were obtained to achieve the DNA detection sensitivity as low as 1pM (10-12M) based on different conditions: the gate materials, buffer concentration and surface condition of graphene. These developments indicated that the surface of graphene films using conventional PMMA – assisted transfer technique exhibits PMMA residues which degrade the sensing performance of graphene. In addition, the sensing performance of the graphene samples prepared by gold – transfer is largely enhanced by 125%. These advantages render graphene as a very promising candidate for sensor detection applications. Furthermore, we also constructed the devices for testing the Hall – effect measurement based on a Vander Pauw methods to perform the single – based sequence selective detection of DNA on the graphene sheets made by CVD system. In this contribution, we concluded that the increase of only the hole carrier density corresponds to the fact of single based specific detection. With the concentration of added complementary DNA or one – based mismatched DNAs, the hole carrier density of graphene devices increase. It indicates that the hole carrier density measurement is more sensible than the conductivity or mobility techniques. In addition, the increasing in hole carrier concentration also suggests that the DNA hybridization imposes p – doping through the electrostatic gating from negative charged phosphate group. Furthermore, in order to accurately detect the hybridization of target DNAs pre – immobilized on graphene with concentration of 0.01 nM, we fabricated the graphene devices by gold transfer. The second part of this thesis concerns on the ultrasensitive detection of DNA hybridization based on graphene/MoS2 stacking films. In this hetero-structure, the sensitive detection can reach at the aM (10-18M) level of DNA concentration. A new mechanism of detection of DNA hybridization in these heterostructures was identified. This detection, besides using the field effect transistors, Hall effect measurement and Raman spectroscopy can be applied in this study. The photoluminescence is also critical to observe the DNA hybridization in these heterostructures.