Lithium-ion batteries have been widely used in our daily life because the climate change, in part due to burning fossil fuels, forces human beings to alter the lifestyle. Recently electric vehicles developed rapidly and traditional lithium-ion batteries couldn’t meet the demand for the high energy density, so the lithium-sulfur (Li-S) batteries, which was considered as the next generation of lithium-ion batteries, gradually attract lots of attentions due to its high energy density. During the development of Li-S batteries, the polysulfide shuttle effect always limits its applications. Thus, in our work, we devote to exploiting two types of protection layer to alleviate the polysulfide shuttle effect and enhance the performance of the Li-S batteries. One of them is the lignin/MWCNT composite protection layer. We successfully prepare various weight ratios of lignin/MWCNT composite protection layer and find the 25 wt% lignin/MWCNT protection layer have the highest specific surface area and advantageous pore distribution on the basic of BET and SEM results. Moreover, we conduct the galvanostatic charge/discharge experiment for the Li-S batteries with various weight ratios lignin/MWCNT composite protection layer and discover that the Li-S batteries with 25 wt% lignin/MWCNT composite protection layer have the best electrochemical performance with its high capacity and low decay rate. Our results indicate that the 25 wt% lignin adding into the MWCNT protection layer is the best formula and alleviate the polysulfide shuttle effect effectively. The other type of protection layer is fabricated by amide and amine group multi-walled carbon tube (A-MWCNT), which is aimed to suppress shuttle effect by the polar surface of carbon materials to perform strong interaction with polysulfides. A-MWCNT not only have the physical hindering ability to limit polysulfide passing but also possess the chemical adsorption ability to polysulfides and so reduce the shuttle effect. In our work, we successfully synthesized A-MWCNT and confirm its characterization by using XPS and FTIR. Next, we fabricate the free-standing A-MWCNT protection layer and assemble it into the Li-S batteries. The Li-S batteries with the A-MWCNT protection layer are demonstrated to have high electrochemical reversibility and low charge transfer resistance according to the results of CV and EIS. We also find that the Li-S batteries with A-MWCNT protection layer show great electrochemical performance with high initial capacity (1470 mAh g-1) and low decay rate (0.25% per cycle) because the amide and amine interact with the polysulfide and increase the active material utilization. We further qualitatively determine the adsorption ability of A-MWCNT protection layer to polysulfide by using EDS mapping analysis and adsorption test and measure the blocking extent in quantitative by UV-Vis analysis.