Two work packages have been thoroughly investigated towards the objectives of this project listed above. In work package 1, a new family of 2D polymer crystal proton conductor was created, and the fast and selective proton transport features enabled by the aligned transport channels were highlighted, which reflects a new transport mechanism. In this work package, bulk MOFs single crystals have been grown. Towards few layer 2D crystals, exfoliation and transfer techniques have been developed. Furthermore, proton transport devices were fabricated in cleanrooms. In the following, the proton conductivity of the 2D MOFs crystals was investigated. The role of ultramicropore channels was found effective in enabling a low-energy-barrier Grotthuss hopping mechanism for proton conductance. Due to intriguing structural properties and high-performances as fast proton conductor, a research paper is expected to be published in a high-profile journal. In work package 2, a technical innovation of proton exchange membrane was presented, in which single layer proton selective conductor including the commercial CVD graphene and hBN was integrated with commercial proton exchange membranes. Dimensionally, the new type of graphene strengthened proton exchange membrane can be scale up to wafer-scale. In a working fuel cell, the fuel crossover was suppressed by up to 90%, while negligibly affected the proton conductivity. The dissemination of the work has been undertaken through presentations at Carbon international conference 2017 held in Melbourne, Australia.