Abstract: An advanced reverse treated electrodeposited copper foil and a copper clad laminate using the same are provided. The advanced reverse treated electrodeposited copper foil has an uneven micro-roughened surface. The micro-roughened surface has a plurality of copper crystals, a plurality of copper whiskers and a plurality of copper crystal groups, which are in a non-uniform distribution to form a non-uniformly distributed horizontal or vertical stripe pattern.

Abstract: An advanced electrodeposited copper foil having island-shaped microstructures and a copper clad laminate using the same are provided. The advanced electrodeposited copper foil includes a micro-roughened surface. The micro-roughened surface has a plurality of copper crystals, a plurality of copper whiskers and a plurality of copper crystal groups which are in a non-uniform distribution and form into island-shaped patterns.

Abstract: An advanced electrodeposited copper foil and a copper clad laminate using the same are provided. The advanced electrodeposited copper foil has an uneven micro-roughened surface. As observed by a scanning electron microscope operated with a +35 degree tilt and under 1,000× magnification, the uneven micro-roughened surface has a plurality of production direction stripes formed by copper crystals.

Abstract: The present disclosure provides a micro-rough electrolytic copper foil and a copper clad laminate. The electrolytic copper foil has a micro-rough surface formed with mountain-shaped structures and recessed structures. A multiplication value of an arithmetic mean height (Sa) and a vertex density (Spd) of the mountain-shaped structures measured according to ISO 25178 is between 150000 ?m/mm2 and 400000 ?m/mm2. An arithmetic mean undulation (Wa) of the mountain-shaped structures measured according to JIS B0601:2001 is between 0.06 ?m and 1.5 ?m. Therefore, the electrolytic copper foil with good binding strength and electrical properties can be obtained.

Abstract: Provided is a micro-roughened electrodeposited copper foil, which comprises a micro-rough surface and multiple copper nodules. The micro-roughened electrodeposited copper foil has an Rlr value of 1.05 to 1.60, or an Sdr of 0.01 to 0.08. With the surface characteristics, the electron path distance can be shortened, such that the micro-roughened electrodeposited copper foil can reduce the insertion loss of the copper clad laminate at high frequencies and have the desired peel strength.

Abstract: A micro-roughened electrodeposited copper foil and a copper foil substrate are provided. The micro-roughened electrodeposited copper foil includes a micro-rough surface. The micro-rough surface has a plurality of peaks, a plurality of V-shaped grooves and a plurality of micro-crystal clusters. Each of the V-shaped grooves is defined by adjacent two of the peaks and has an average depth less than 1 ?m. The micro-crystal clusters are correspondingly located on the tops of the peaks and each thereof has an average height less than 1.5 ?m. The micro-rough surface of the micro-roughened electrodeposited copper foil has an Rlr value less than 1.06.

Abstract: A micro-roughened electrodeposited copper foil and a copper foil substrate are provided. The micro-roughened electrodeposited copper foil includes a micro-rough surface. The micro-rough surface has a plurality of peaks, a plurality of grooves and a plurality of micro-crystal clusters. Each of the grooves has a U-shaped or V-shaped cross-section profile, and the grooves have an average maximum width between 0.1 ?m and 4 ?m and an average depth less than or equal to 1.5 ?m. Each of the micro-crystal clusters is composed of a plurality of micro-crystals each having an average diameter less than or equal to 0.5 ?m grouped together. The micro-rough surface of the micro-roughened electrodeposited copper foil has an Rlr value less than 1.3. The micro-rough surface has good bonding strength relative to a substrate, and the copper foil substrate has good insertion loss performance to significantly reduce signal loss.

Abstract: An advanced electrodeposited copper foil and a copper clad laminate using the same are provided. The advanced electrodeposited copper foil has an uneven micro-roughened surface. As observed by a scanning electron microscope operated with a +35 degree tilt and under 1,000× magnification, the uneven micro-roughened surface has a plurality of production direction stripes formed by copper crystals.

Abstract: An advanced electrodeposited copper foil having long and island-shaped microstructures and a copper clad laminate using the same are provided. The advanced electrodeposited copper foil includes a micro-roughened surface. The micro-roughened surface has a plurality of copper crystals, a plurality of copper whiskers and a plurality of copper crystal groups which are in a non-uniform distribution and form into a long and island-shaped pattern.

Abstract: Provided is a micro-roughened electrodeposited copper foil, which comprises a micro-rough surface and multiple copper nodules. The micro-rough surface includes multiple copper nodule-free areas and copper nodule-arranged areas. The micro-rough surface of 120 ?m2 has at least five copper nodule-free areas of 62500 nm2 or more. Each copper nodule-arranged area has a length of 300 nm to 2500 nm and includes three to fifty copper nodules with a mean width of 10 nm to 300 nm. Besides, the micro-roughened electrodeposited copper foil has an Rlr value of 1.05 to 1.60, or an Sdr of 0.01 to 0.08. With the surface profile and/or characteristics, the electron path distance can be shortened, such that the micro-roughened electrodeposited copper foil can reduce the insertion loss of the copper clad laminate at high frequencies and have the desired peel strength.

Abstract: An advanced reverse treated electrodeposited copper foil and a copper clad laminate using the same are provided. The advanced reverse treated electrodeposited copper foil has an uneven micro-roughened surface. The micro-roughened surface has a plurality of copper crystals, a plurality of copper whiskers and a plurality of copper crystal groups, which are in a non-uniform distribution to form a non-uniformly distributed horizontal or vertical stripe pattern.

Abstract: The present disclosure provides a micro-rough electrolytic copper foil and a copper clad laminate. The electrolytic copper foil has a micro-rough surface formed with mountain-shaped structures and recessed structures. A multiplication value of an arithmetic mean height (Sa) and a vertex density (Spd) of the mountain-shaped structures measured according to ISO 25178 is between 150000 ?m/mm2 and 400000 ?m/mm2. An arithmetic mean undulation (Wa) of the mountain-shaped structures measured according to JIS B0601:2001 is between 0.06 ?m and 1.5 ?m. Therefore, the electrolytic copper foil with good binding strength and electrical properties can be obtained.

Abstract: A micro-roughened electrodeposited copper foil and a copper foil substrate are provided. The micro-roughened electrodeposited copper foil includes a micro-rough surface. The micro-rough surface has a plurality of peaks, a plurality of grooves and a plurality of micro-crystal clusters. Each of the grooves has a U-shaped or V-shaped cross-section profile, and the grooves have an average maximum width between 0.1 ?m and 4 ?m and an average depth less than or equal to 1.5 ?m. Each of the micro-crystal clusters is composed of a plurality of micro-crystals each having an average diameter less than or equal to 0.5 ?m grouped together. The micro-rough surface of the micro-roughened electrodeposited copper foil has an Rlr value less than 1.3. The micro-rough surface has good bonding strength relative to a substrate, and the copper foil substrate has good insertion loss performance to significantly reduce signal loss.

Abstract: A micro-roughened electrodeposited copper foil and a copper foil substrate are provided. The micro-roughened electrodeposited copper foil includes a micro-rough surface. The micro-rough surface has a plurality of peaks, a plurality of V-shaped grooves and a plurality of micro-crystal clusters. Each of the V-shaped grooves is defined by adjacent two of the peaks and has an average depth less than 1 ?m. The micro-crystal clusters are correspondingly located on the tops of the peaks and each thereof has an average height less than 1.5 ?m. The micro-rough surface of the micro-roughened electrodeposited copper foil has an Rlr value less than 1.06.

Abstract: The electromagnetic interference shielding structure disclosed comprises a first metal layer, a second metal layer, a dielectric layer inter-disposed between the first metal layer and the second metal layer, an adhesive layer located on the second metal layer, and a release film located on the adhesive layer. The electromagnetic interference shielding film prevent the neighbouring circuits and components from the electromagnetic wave interference, the theories applied are reflections of the electromagnetic waves, and absorption of the electromagnetic waves.