Forming method of metal layer

What is claimed is: 1 . A forming method of a metal layer suitable for a 3D printing process, comprising the following steps: (1) providing a plurality of first metal particles on a substrate to form a first layer of the plurality of first metal particles; (2) performing a first pre-heat treatment on the first layer at a first pre-heat temperature; (3) applying an oxide-removing agent on selected first metal particles in the first layer to remove metal oxides on the selected first metal particles after providing the plurality of first metal particles on the substrate; (4) providing a plurality of second metal particles on the first layer to form a second layer of the plurality of second metal particles, wherein the second layer is farther away from the substrate than the first layer; (5) performing a second pre-heat treatment on the second layer at a second pre-heat temperature; (6) applying the oxide-removing agent on selected second metal particles in the second layer to remove metal oxides on the selected second metal particles; repeating (1) to (6) until a latent part is formed; performing a first heat treatment on the first and second metal particles of the latent part for which the metal oxides are removed at a first temperature to form a near shape; and performing a second heat treatment on the near shape at a second temperature to form a sintered body, wherein the first temperature is lower than the second temperature. 2 . The forming method of the metal layer of claim 1 , wherein the oxide-removing agent comprises an organic acid, an inorganic acid, a flux, or carbon particles. 3 . The forming method of the metal layer of claim 2 , wherein the organic acid comprises oxalic acid, acetic acid, citric acid, or a combination thereof. 4 . The forming method of the metal layer of claim 2 , wherein the inorganic acid comprises phosphoric acid, sulfuric acid, or a combination thereof. 5 . The forming method of the metal layer of claim 2 , wherein the carbon particles are applied to the metal particles in a hydrogen atmosphere. 6 . The forming method of the metal layer of claim 1 , wherein a method of applying the oxide-removing agent comprises inkjet, micro-dispensing, or spraying. 7 . The forming method of the metal layer of claim 6 , wherein the inkjet is implemented by a direct inkjet printing system for fabricating a part by an additive manufacturing process. 8 . The forming method of the metal layer of claim 7 , wherein the direct inkjet printing system performs a drop-on-demand inkjet printing process and comprises a print head for applying an inkjet ink onto the substrate. 9 . The forming method of the metal layer of claim 8 , wherein the inkjet ink is a water-based ink. 10 . The forming method of the metal layer of claim 1 , wherein a material of the first and second metal particles comprises a metal or an alloy. 11 . The forming method of the metal layer of claim 1 , further comprising applying the oxide-removing agent to the first and/or second metal particles at an activation temperature of the oxide-removing agent, and the activation temperature is lower than the first temperature. 12 . The forming method of the metal layer of claim 11 , further comprising directly increasing a temperature to the first temperature at the activation temperature after the metal oxides on the first and second metal particles are removed. 13 . The forming method of the metal layer of claim 1 , wherein the second heat treatment is performed in a vacuum environment or an inert environment. 14 . The forming method of the metal layer of claim 1 , wherein the second temperature is between 1523 K and 1698 K.