Method for fabricating heterogeneous nickel-based catalyst on aluminum oxide support, heterogeneous nickel-based catalyst on aluminum oxide support and method for synthesizing polyetheramine

What is claimed is: 1. A method for fabricating a heterogeneous nickel-based catalyst on an aluminum oxide support, comprising: performing a solution preparation step, wherein a catalytically active precursor is used as a precursor solution, the precursor solution contains a nickel ion and a cerium ion, and a concentration of the nickel ion is 15 wt %, a concentration of the cerium ion is in a range of from greater than 5.0 wt % to 15 wt %; performing a drop-cast step, wherein the precursor solution is dropped on a support so as to obtain a catalyst precursor, and the support is an aluminum oxide support; performing a first calcining step, wherein the catalyst precursor is calcined so as to obtain an oxidation state catalyst; and performing a second calcining step, wherein the oxidation state catalyst is calcined under a reducing gas so as to obtain the heterogeneous nickel-based catalyst on the aluminum oxide support, the reducing gas is hydrogen, and a temperature of the second calcining step is 400° C. 2. The method for fabricating the heterogeneous nickel-based catalyst on the aluminum oxide support of claim 1 , wherein the precursor solution is a mixed solution of nickel nitrate and cerium nitrate. 3. The method for fabricating the heterogeneous nickel-based catalyst on the aluminum oxide support of claim 1 , wherein the support is dried at a temperature of 353 K to 393 K first, and reserved overnight. 4. The method for fabricating the heterogeneous nickel-based catalyst on the aluminum oxide support of claim 1 , wherein a temperature of the first calcining step ranges from 300° C. to 400° C. 5. The method for fabricating the heterogeneous nickel-based catalyst on the aluminum oxide support of claim 1 , further comprising a passivation step, wherein the passivation step is performed by introducing an air so as to passivate the heterogeneous nickel-based catalyst on the aluminum oxide support at a temperature of 180° C. to 220° C. 6. The method for fabricating the heterogeneous nickel-based catalyst on the aluminum oxide support of claim 5 , wherein the passivation step further comprises cooling the heterogeneous nickel-based catalyst on the aluminum oxide support at the temperature of 200° C. to 400° C. with nitrogen. 7. A heterogeneous nickel-based catalyst on an aluminum oxide support fabricated by the method for fabricating the heterogeneous nickel-based catalyst on the aluminum oxide support of claim 1 . 8. The heterogeneous nickel-based catalyst on the aluminum oxide support of claim 7 , wherein the heterogeneous nickel-based catalyst on the aluminum oxide support is a nickel-cerium oxide catalyst on the aluminum oxide support. 9. A method for synthesizing polyetheramine, comprising: providing the heterogeneous nickel-based catalyst on the aluminum oxide support of claim 7 ; and performing a reductive amination reaction of polypropylene glycol step, wherein polypropylene glycol is reductively aminated by the heterogeneous nickel-based catalyst on the aluminum oxide support used as a catalyst so as to obtain polyetheramine in an environment containing hydrogen and ammonia. 10. The method for synthesizing polyetheramine of claim 9 , wherein a molar ratio of hydrogen to polypropylene glycol ranges from 1 to 1.5. 11. The method for synthesizing polyetheramine of claim 9 , wherein a molar ratio of ammonia to polypropylene glycol ranges from 38 to 40.6. 12. The method for fabricating the heterogeneous nickel-based catalyst on the aluminum oxide support of claim 1 , wherein the concentration of the cerium ion is 15 wt %.