According to the generalized uncertainty principle (GUP), the Klein-Gordon equation is corrected by the quantum gravity
exactly. Hence, the corrected Klein-Gordon equation will be more precise on the
expression of the tunneling behavior. Then, the corrected Hawking temperature
of the Gibbons-Maeda-Dilaton black hole is obtained near the horizon by quantum
gravity. Analyzing the results carefully, it is obvious for us that the tunneling
result is not only related to the mass of black hole, but also related to the
mass and energy of outgoing fermions. Finally, we also infer that the tunneling
radiation would be stopped at some particular temperature.
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