Methane decomposition using nickel,copper,and aluminum(Ni:Cu/Al)and nickel,copper,potassium,and alu- minum(Ni:Cu:K/Al)modified nano catalysts has been investigated for carbon fibers,hydrogen and hydrocarbon production. X-ray photoelectron spectroscopy(XPS),static secondary ion mass spectrometry(SSIMS),thermal gravimetric analysis(TGA), Fourier transform infrared(FT-IR),secondary electron microscopy/X-ray energy dispersive(SEM-EDX),and temperature pro- grammed desorption(TPD)were used to depict the chemistry of the catalytic results.These techniques revealed the changes in surface morphology and structure of Ni,Cu,Al,and K,and formation of bimetallic and trimetallic surface cationic sites with different cationic species,which resulted in the production of graphitic form of pure carbon on Ni:Cu/Al catalyst.The addition of K has a marked effect on the product selectivity and reactivity of the catalyst system.K addition restricts the formation of carbon on the surface and increases the production of hydrogen and C_2,C_3 hydrocarbons during the catalytic reaction whereas no hydrocarbons are produced on the sample without K.This study completely maps the modified surface structure and its re- lationship with the catalytic behavior of both systems.The process provides a flexible route for the production of carbon fibers and hydrogen on Ni:Cu/Al catalyst and hydrogen along with hydrocarbons on Ni:Cu:K/Al catalyst.The produced carbon fibers are imaged using a transmission electron microscope(TEM)for diameter size and wall structure determination.Hydrogen produced is CO_x free,which can be used directly in the fuel cell system.The effect of the addition of Cu and its transformation and interaction with Ni and K is responsible for the production of CO/CO_2 free hydrogen,thus producing an environmental friendly clean energy. Methane decomposition using nickel, copper, and aluminum (Ni: Cu / Al) and nickel, copper, potassium, and alu- minum (Ni: Cu: K / Al) modified nano catalysts has been investigated for carbon fibers, hydrogen and hydrocarbon production . X-ray photoelectron spectroscopy (XPS), static secondary ion mass spectrometry (SSIMS), thermal gravimetric analysis (TGA), Fourier transform infrared (FT-IR), secondary electron microscopy / X-ray energy dispersive and temperature pro-grammed desorption (TPD) were used to depict the chemistry of the catalytic results. These findings revealed the changes in surface morphology and structure of Ni, Cu, Al, and K, and formation of bimetallic and trimetallic surface cationic sites with different cationic species, which resulted in the production of graphitic form of pure carbon on Ni: Cu / Al catalyst. The addition of K has a marked effect on the product selectivity and reactivity of the catalyst system. K except restricts the formation of carbon on the surface and increases the pro duction of hydrogen and C_2, C_3 hydrocarbons during the catalytic reaction and no hydrocarbons are produced on the sample without K. This study completely maps the modified surface structure and its re- lationship with the catalytic behavior of both systems. The process provides a flexible route for the production of carbon fibers and hydrogen on Ni: Cu / Al catalyst and hydrogen along with hydrocarbons on Ni: Cu: K / Al catalyst. The produced carbon fibers are imaged using a transmission electron microscope (TEM) for diameter size and wall structure Determination. Hydrogen produced is CO_x free, which can be used directly in the fuel cell system. The effect of the addition of Cu and its transformation and interaction with Ni and K is responsible for the production of CO / CO_2 free hydrogen, thus producing an environmental friendly clean energy.