Abstract: A lead-frame assembly is disclosed, for a semiconductor die and comprising a die attach pad and a plurality of elongate leads spaced apart therefrom; wherein each elongate lead has a first proximal end portion, a second distal end portion and a middle portion therebetween; wherein the die attach pad and each of the plurality of elongate leads each comprise a coating-free portion, and a coated portion having a coating material thereon; wherein a part of a perimeter of the die attach pad proximal each lead is comprised in the coating-free portion, and wherein the proximal end portion of each elongate lead is comprised in the coating-free portion. Associated package assemblies and methods are also disclosed.

Abstract: A lead frame includes a metal plate, having a surface partitioned, by a concavity, into columnar areas, and a plating layer including stacked Ni, Pd and Au layers on the surface at top faces of the columnar areas, to form columnar pieces, which serve as internal connecting terminals, respectively, or as internal connecting terminals and pads, respectively. Each of the columnar pieces has, around a circumference of an upper portion thereof, curved regions intervening between straight regions. In each curved region, a side face of the plating layer protrudes outwardly in a horizontal direction from an uppermost portion of a side face of the metal plate in each of the columnar pieces. At a center of each straight region, the side face of the plating layer has substantially a same horizontal position as the uppermost portion of the side face of the metal plate in each of the columnar pieces.

Abstract: The present invention provides a method of fabricating a 3D stacked IC SiP which includes: providing a first semiconductor wafer having a plurality of first dies formed thereon, each having a first wire bond pad and a first dielectric layer, at least a portion of the first wire bond pad is not covered by the first dielectric layer and constitutes an exposed area of the first die; providing a plurality of second dies, each having a second wire bond pad and a second dielectric layer, at least a portion of the second wire bond pad is not covered by the second dielectric layer and constitutes an exposed area of the second die different in size from that of the first die; aligning the second dies with the first dies and bonding the second dielectric layer to the first dielectric layer; plating the first semiconductor wafer bonded with the second dies.

Abstract: A symmetrical, flat laminate structure used to minimize variables in a test structure to experimentally gauge white bump sensitivity to CTE mismatch is disclosed. The test structure includes a flat laminate structure. The method of using the test structure includes isolating a cause of a multivariable chip join problem that is adversely impacted by warpage and quantifying a contribution of the warpage, itself, in a formation of the multivariable chip join problem.

Abstract: The present invention relates to a multi-row leadframe for semiconductor packaging, characterized by: forming a plating pattern on a leadframe material (first step); forming a protective pattern on the plating pattern (second step); and forming a nano pattern by using the protective pattern as a mask (third step), whereby a protective pattern is formed on an upper surface of a plating pattern to increase reliability of a product by preventing damage to a plating layer caused by etching solution during pattern formation of leadframe and to thereby solve the problem of using the plating layer as an etching mask.

Abstract: A lead frame and a semiconductor package including the lead frame are provided. The lead frame includes: a base material; a first metal layer which is formed on at least one side of the base material, of which a surface is roughly formed, and which includes copper or nickel; a second metal layer which is formed on a surface of the first metal layer, of which a surface is roughly formed, and which includes palladium or a palladium alloy; a third metal layer which is formed on a surface of the second metal layer, of which a surface is roughly formed, and which includes gold or a gold alloy; and a fourth metal layer which is formed on a surface of the third metal layer, of which a surface is roughly formed, and which includes metal that includes silver.

Abstract: A package includes a die, which includes a semiconductor substrate, a plurality of through-vias penetrating through the semiconductor substrate, a seal ring overlapping and connected to the plurality of through-vias, and a plurality of electrical connectors underlying the semiconductor substrate and connected to the seal ring. An interposer is underlying and bonded to the die. The interposer includes a substrate, and a plurality of metal lines over the substrate. The plurality of metal lines is electrically coupled to the plurality of electrical connectors. Each of the plurality metal lines has a first portion overlapped by the first die, and a second portion misaligned with the die. A thermal conductive block encircles the die, and is mounted on the plurality of metal lines of the interposer.

Abstract: A semiconductor device comprises an aluminum alloy lead-frame with a passivation layer covering an exposed portion of the aluminum alloy lead-frame. Since aluminum alloy is a low-cost material, and its hardness and flexibility are suitable for deformation process, such as punching, bending, molding and the like, aluminum alloy lead frame is suitable for mass production; furthermore, since its weight is much lower than copper or iron-nickel material, aluminum alloy lead frame is very convenient for the production of semiconductor devices.

Abstract: An electronic component and method of making an electronic component is disclosed. In one embodiment, the electronic component includes a frame having a base layer, a first layer, a second layer including palladium placed on the first layer, and a third layer including gold placed on the second layer. A semiconductor chip is positioned on the frame.

Abstract: To provide an inexpensive lead component which can be easily connected to a semiconductor chip and which has satisfactory connectability. There is provided a lead component including a base material having a connection part for connecting to a semiconductor chip, comprising: a solder part having a Zn layer made of a Zn-bonding material rolled and clad-bonded on the base material, and an Al layer made of an Al-bonding material rolled and clad-bonded on the Zn layer, in a prescribed region including the connection part on the base material; and the solder part further comprising a metal thin film composed of one kind or two kinds or more of Au, Ag, Cu, Ni, Pd, and Pt covering a surface of the Al layer.

Abstract: The present invention relates to a multi-row leadframe for semiconductor packaging, characterized by: forming a plating pattern on a leadframe material (first step); forming a protective pattern on the plating pattern (second step); and forming a nano pattern by using the protective pattern as a mask (third step), whereby a protective pattern is formed on an upper surface of a plating pattern to increase reliability of a product by preventing damage to a plating layer caused by etching solution during pattern formation of leadframe and to thereby solve the problem of using the plating layer as an etching mask.

Abstract: A current sense resistor integrated with an integrated circuit die housed in a chip-scale semiconductor package includes a metal layer formed over a passivation layer of the integrated circuit die where the metal layer having an array of metal pillars extending therefrom. The metal pillars are to be electrically connected to a first conductive electrode and a second conductive electrode external to the chip-scale semiconductor package where the first conductive electrode and the second conductive electrode are physically separated from each other by a separation of a first distance. The current sense resistor is formed in a portion of the metal layer spanning the separation between the first and second conductive electrodes. In some embodiments, a semiconductor device including an integrated circuit die housed in a chip-scale semiconductor package includes a current sense resistor formed in a metal layer formed over a passivation layer of the integrated circuit die.

Abstract: A method of manufacture of an integrated circuit packaging system includes: providing a leadframe having a mounting region; applying a mounting structure in the mounting region; mounting an integrated circuit die on the mounting structure; forming an encapsulation on the integrated circuit die and having an encapsulation cavity, the encapsulation cavity shaped by the mounting structure; forming a lead having a lead protrusion from the leadframe, the lead protrusion below a horizontal plane of the integrated circuit die; and removing the mounting structure for exposing the integrated circuit die.

Abstract: A lead frame (100) for a semiconductor device is formed by applying nickel plating (102), palladium plating (103), and gold flash plating (104) substantially entirely to lead frame body (101) such as copper thin plate in this order, and further applying silver plating (105) selectively to part of an inner part that is to be enclosed with a package of the semiconductor device. The lead frame (100) may also include a base of the package. The silver plating contributes to an excellent light reflectance and wire bonding efficiency of the inner part, whereas the gold flash plating contributes to an excellent resistance to corrosion and soldering efficiency of an outer part that is outside the package.

Abstract: A current sense resistor integrated with an integrated circuit die where the integrated circuit die is housed in a chip-scale semiconductor package includes a metal layer formed over a passivation layer of the integrated circuit die where the metal layer has an array of metal pillars extending therefrom. The metal pillars are to be electrically connected to a first conductive trace portion and a second conductive trace portion formed on a printed circuit board where the first conductive trace portion and the second conductive trace portion are electrically isolated from each other and physically separated by a separation of a first distance. The current sense resistor is formed in a portion of the metal layer spanning the separation between the first and second metal trace portions, the first and second conductive trace portions forming terminals of the current sense resistor.

Abstract: An electronic device including a die-pad area, a die fixed to the die-pad area, a connection terminal, and a ribbon of conductive material. The ribbon is electrically connected to the die and to the connection terminal, and has a prevalent dimension along a first axis, a width, measured along a second axis, which is transverse to the first axis, and a thickness, which is negligible with respect to the width; the ribbon moreover has a cross section that defines a concave geometrical shape.

Abstract: The present invention provides a method for manufacturing a modularized integrated circuit (IC). The method includes the following steps: providing a base; and coupling an input/output module with the base. The base includes a lead-frame and a first package. The first package covers the lead-frame but exposes first contact points. The input/output module includes a first substrate, a plurality of first conducting columns, and a plurality of third contact points. A portion of each of the third contact points is electrically connected to a corresponding one of the first contact points. The method enhances the flexibility of IC design, and reduces the time and costs of developing new process techniques.

Abstract: There is provided a system and method for a spot plated leadframe and an IC bond pad via array design for copper wire. There is provided a semiconductor package comprising a leadframe having a pre-plated finish and a spot plating on said pre-plated finish, a semiconductor die including a bond pad on a top surface thereof, and a copper wire bonded to said spot plating and to said bond pad. Optionally, a novel corner via array design may be provided under the bond pad for improved package performance while maintaining the integrity of the copper wire bond. The semiconductor package may provide several advantages including high MSL ratings, simplified assembly cycles, avoidance of tin whisker issues, and low cost compared to conventional packages using gold wire bonds.

Abstract: The present invention provides a Quad Flat Non-leaded (QFN) package, which comprises a chip, a lead frame, a plurality of composite bumps and an encapsulant. The chip has a plurality of pads, and the lead frame has a plurality of leads. Each of the plurality of composite bumps has a first conductive layer and a second conductive layer. The first conductive layer is electrically connected between one of the pads and the second conductive layer, and the second conductive layer is electrically connected between the first conductive layer and one of the leads. The encapsulant encapsulates the chip, the leads and the composite bumps. Thereby, a QFN package with composite bumps and a semi-cured encapsulant is forming between the spaces of leads of lead frame before chip bonded to the lead frame are provided.

Abstract: The package structure includes a metal sheet having a first central block, a plurality of first metal blocks, a second central block and a plurality of second metal blocks, a first finish layer and a second finish layer, at least a chip disposed on the metal sheet and a package body encapsulating the chip. The package structure may further include at least an area block for wire routing.

Abstract: A lead frame for a resin-seal type semiconductor device, which includes a semiconductor element having an electrode, a bonding wire connected to the electrode of the semiconductor element, and a sealing resin covering and sealing the semiconductor element and the bonding wire. The lead frame includes a substrate frame, a four-layer plating, and a three-layer plating. The substrate frame include leads, a connection region, which is sealed by the sealing resin and connected to the bonding wire, and an exposed region, which is not sealed by the sealing resin. A four-layer plating is applied to a portion of the substrate frame that is to be connected to the bonding wire and sealed by the sealing resin. A three-layer plating is applied to an exposed region of the substrate frame that is exposed from the sealing resin.

Abstract: A lead frame includes a plurality of leads electrically connected to a semiconductor chip and a lead lock including a base layer disposed over the plurality of the leads and formed of a material having a coefficient of thermal expansion similar to that of inner leads. An adhesive layer is disposed between the base layer and the plurality of leads to fix the plurality of leads and adhere the base layer to the leads. At least one line electrically connects the semiconductor chip to the base layer of the lead lock. Since regions for bus bars are replaced by the lead lock and are removed, the lead frame can be miniaturized and has superior thermal stability and dimension stability.

Abstract: The advanced quad flat non-leaded package structure includes a carrier, a chip, a plurality of wires, and a molding compound. The carrier includes a die pad and a plurality of leads. The inner leads of the leads are designed to possess incurved sidewalls for enhancing the adhesion between the inner leads and the surrounding molding compound.

Abstract: An integrated circuit package system includes a conductive substrate. A heat sink and a plurality of leads are etched in the substrate to define a conductive film connecting the heat sink and the plurality of leads to maintain their spatial relationship. A die is attached to the heat sink and wire bonded to the plurality of leads. An encapsulant is formed over the die, the heat sink, and the plurality of leads. The conductive film is etched away to expose the encapsulant and the bottom surfaces of the heat sink and the plurality of leads. Wave soldering is used to form solder on at least the plurality of leads. Multiple heat sinks and hanging leads are provided.

Abstract: A semiconductor device includes a semiconductor element; a group of back-inner terminals coupled with the semiconductor element through bonding wires and arranged in an area array shape so as to be exposed inside of the bottom; a group of back-outer terminals arranged outside the group of back-inner terminals; a group of front-outer terminals located immediately above the back-outer terminals to be exposed from the front surface, which are electrically coupled with the back-outer terminals located immediately therebelow through coupling conductors, respectively; and a sealing resin which seals the semiconductor element and bonding wires and non-exposed portions of said back-inner terminals, back-outer terminals and front-outer terminals. On at least the respective terminal faces of said back-inner terminals, back-outer terminals and front-outer terminals, noble-metal plated layers are formed.

Abstract: A metal leadframe to be used in manufacturing a “flip-chip” type semiconductor package is treated to form a metal plated layer in an area to be contacted by a solder ball or bump on the chip. The leadframe is then process further to form an oxide or organometallic layer around the metal plated layer. Pretreating the leadframe in this manner prevents the solder from spreading out during reflow and maintains a good standoff distance between the chip and leadframe. During the molding process, the standoff between the chip and leadframe allows the molding compound to flow freely, preventing voids in the finished package.

Abstract: A method of manufacture of an integrated circuit packaging system includes: forming a substrate; mounting a base integrated circuit on the substrate; forming a leadframe interposer, over the base integrated circuit, by: providing a metal sheet, mounting an integrated circuit die on the metal sheet, injecting a molded package body on the integrated circuit die and the metal sheet, and forming a ball pad, a bond finger, or a combination thereof from the metal sheet that is not protected by the molded package body; coupling a circuit package on the ball pad; and forming a component package on the substrate, the base integrated circuit, and the leadframe interposer.

Abstract: One embodiment includes an encapsulated semiconductor package having a lead frame with die pad surrounded by a plurality of first and second leadfingers. A semiconductor chip including chip contact pads on its upper active surface is attached to the die pad. A plurality of first bond wires, including a first electrically conductive material, extend between the chip contact pads and the plurality of first leadfingers. A plurality of second bond wires, including a second electrically conductive material, extend between a chip contact pad and a second leadfinger. The semiconductor package further includes a plurality of electrically conducting means attached to the second leadfingers.

Abstract: An insulated metal substrate composite has a patterned conductive layer on one surface and receives one or more electrodes of MOSFETs or other die on the patterned segments which lead to the edge of the IMS. The outer periphery of the IMS is cupped or bent to form a shallow can with two or more die fixed to and thermally coupled to the flat web of the can while electrodes on the die surfaces thermally coupled to the web of the can lead to terminals on the rim of the can which are coplanar with the bottom surfaces of the die. The electrodes can be externally or internally connected to form a half bridge circuit.

Abstract: A lead frame includes a plurality of leads electrically connected to a semiconductor chip and a lead lock including a base layer disposed over the plurality of the leads and formed of a material having a coefficient of thermal expansion similar to that of inner leads. An adhesive layer is disposed between the base layer and the plurality of leads to fix the plurality of leads and adhere the base layer to the leads. At least one line electrically connects the semiconductor chip to the base layer of the lead lock. Since regions for bus bars are replaced by the lead lock and are removed, the lead frame can be miniaturized and has superior thermal stability and dimension stability.

Abstract: A lead frame (100) for a semiconductor device is formed by applying nickel plating (102), palladium plating (103), and gold flash plating (104) substantially entirely to lead frame body (101) such as copper thin plate in this order, and further applying silver plating (105) selectively to part of an inner part that is to be enclosed with a package of the semiconductor device. The lead frame (100) may also include a base of the package. The silver plating contributes to an excellent light reflectance and wire bonding efficiency of the inner part, whereas the gold flash plating contributes to an excellent resistance to corrosion and soldering efficiency of an outer part that is outside the package.

Abstract: Provided is a GaN-based LED element having a novel structure for improving output by increasing light extraction efficiency.

Abstract: A leadframe with a structure made of a base metal (105), wherein the structure has a plurality of surfaces. On each of these surfaces are metal layers in a stack adherent to the base metal. The stack comprises a nickel layer (201) in contact with the base metal, a palladium layer (202) in contact with the nickel layer, and an outermost tin layer (203) in contact with the palladium layer. In terms of preferred layer thicknesses, the nickel layer is between about 0.5 and 2.0 ?m thick, the palladium layer between about 5 and 150 nm thick, and the tin layer less than about 5 nm thick, preferably about 3 nm. At this thinness, the tin has no capability of forming whiskers, but offers superb adhesion to polymeric encapsulation materials, improved characteristics for reliable stitch bonding as well as affinity to reflow metals (solders).

Abstract: A power semiconductor package is disclosed with high inductance rating while exhibiting a reduced foot print. It has a bonded stack of power IC die at bottom, a power inductor at top and a circuit substrate, made of leadframe or printed circuit board, in the middle. The power inductor has a inductor core of closed magnetic loop. The circuit substrate has a first number of bottom half-coil forming conductive elements beneath the inductor core. A second number of top half-coil forming conductive elements, made of bond wires, three dimensionally formed interconnection plates or upper leadframe leads, are located atop the inductor core with both ends of each element connected to respective bottom half-coil forming conductive elements to jointly form an inductive coil enclosing the inductor core. A top encapsulant protectively encases the inductor core, the top half-coil forming conductive elements, the bottom half-coil forming conductive elements and the circuit substrate.

Abstract: A lead frame includes a lead frame main body having a plurality of die pad portions each having a chip mounting surface on which a semiconductor chip is mounted, a plurality of lead portions provided to surround the plurality of die pad portions respectively, and a frame portion for supporting the plurality of die pad portions and the plurality of lead portions, an adhesive film pasted on a lower surface of the lead frame main body by pressing, and a first metal film provided on surfaces of the plurality of lead portions and connected electrically to the semiconductor chip respectively, wherein second metal films whose thickness is substantially equal to a thickness of the first metal film are provided to the chip mounting surface of the plurality of die pad portions respectively.

Abstract: An integrated circuit package system includes: providing a finger lead having a side with an outward exposed area and an inward exposed area separated by a lead cavity; positioning a chip adjacent the finger lead and connected to the finger lead; and a stack encapsulant encapsulating the chip and the finger lead with the outward exposed area and the inward exposed area of the finger lead substantially exposed.

Abstract: Methods and apparatus for improved thermal performance and electromagnetic interference (EMI) shielding in integrated circuit (IC) packages is described. A die-up or die-down package includes first and second caps defining a cavity, an IC die, and a leadframe. The leadframe includes a centrally located die attach pad, a plurality of leads, and a plurality of tie bars that couple the die attach pad to the leads. The IC die is mounted to the die attach pad. Planar rim portions of the first and second caps that surround the cavity are coupled to the leadframe. The first and second caps and the leadframe form an enclosure structure that substantially encloses the IC die, and shields EMI emanating from and radiating towards the IC die. The enclosure structure also dissipates heat generated by the IC die during operation.

Abstract: A lead frame includes a plurality of leads electrically connected to a semiconductor chip and a lead lock including a base layer disposed over the plurality of the leads and formed of a material having a coefficient of thermal expansion similar to that of inner leads. An adhesive layer is disposed between the base layer and the plurality of leads to fix the plurality of leads and adhere the base layer to the leads. At least one line electrically connects the semiconductor chip to the base layer of the lead lock. Since regions for bus bars are replaced by the lead lock and are removed, the lead frame can be miniaturized and has superior thermal stability and dimension stability.

Abstract: In accordance with the present invention, there is provided various methods of simultaneously fabricating a plurality of semiconductor packages (e.g., cavity type semiconductor packages) wherein the singulation process is achieved using etching techniques as opposed to more conventional cutting techniques such as sawing or punching. Such etching techniques are inherently lower in cost and free from many of the defects induced by other cutting techniques.

Abstract: A lead frame includes a lead frame body 21 having a die pad 24 to which a semiconductor chip 12 is bonded and a plurality of leads 25 arranged around the die pad 24 and made of Cu or an alloy containing Cu, and a metallic film formed on the lead frame body 21 and to connected to a metallic wire 15 connected to the electrode pad 36 of the semiconductor chip 12. The metallic film is an Ag-plated film 22 with nanoparticles 34 arranged in gaps 33 among Ag crystal grains 31.

Abstract: A connecting tape made of insulating material is adhered between a stage unit 21 and a stage unit 22. The stage units 21 and 22 form united stage units by that. Therefore, edge parts 211 and 221 of the stage units 21 and 22 are bound by the connecting tape 41 and of which movements are restricted. The united stage units 21 and 22 are securely supported by support units 31 and 32 and support units 33 and 34. As a result, number of the support units is reduced and inner lead 12 consumed.

Abstract: A lead frame (100) for a semiconductor device is formed by applying nickel plating (102), palladium plating (103), and gold flash plating (104) substantially entirely to lead frame body (101) such as copper thin plate in this order, and further applying silver plating (105) selectively to part of an inner part that is to be enclosed with a package of the semiconductor device. The lead frame (100) may also include a base of the package. The silver plating contributes to an excellent light reflectance and wire bonding efficiency of the inner part, whereas the gold flash plating contributes to an excellent resistance to corrosion and soldering efficiency of an outer part that is outside the package.

Abstract: Provided is a device, an assembly comprising said device, a sub-assembly and an element suitable for use in the assembly. The device comprises a body of an electrically insulating material having a first side and an opposite second side, the body being provided with conductors according to a desired pattern, said conductors being anchored in the body. The body is provided with a through-hole extending from the first side to the second side of the body and having a surfacial area which is smaller on the first side than on the second side. Such a device can very suitably be used in an assembly comprising an element which is a sensor, preferably a chemical sensor, and particularly a biosensor.

Abstract: This semiconductor device includes a semiconductor chip, and a lead arranged around the semiconductor chip to extend in a direction intersecting with the side surface of the semiconductor chip, and having at least an end farther from the semiconductor chip bonded to a package board, wherein a joint surface to the package board and an end surface orthogonal to the joint surface are formed on the end of the lead farther from the semiconductor chip, and a metal plating layer made of a pure metal is formed on the end surface.

Abstract: An advantage of the present invention is to suppress moisture infiltrating from a pad electrode portion from spreading over the surface of a wiring pattern and improve the reliability of a packaging board. The wiring pattern of the packaging board is formed on an insulating substrate and includes a wiring region, an electrode region (pad electrode) connected with a semiconductor device, and a boundary region provided between the wiring region and the electrode region. A gold plating layer is provided on the surface of the electrode region of the wiring pattern. The top surface of the boundary region of the wiring pattern is so formed as to be dented from the top surface of the wiring region of the wiring pattern, and there is provided a stepped portion in the boundary region.

Abstract: A power semiconductor package is disclosed with high inductance rating while exhibiting a reduced foot print. It has a bonded stack of power IC die at bottom, a power inductor at top and a circuit substrate, made of leadframe or printed circuit board, in the middle. The power inductor has a inductor core of closed magnetic loop. The circuit substrate has a first number of bottom half-coil forming conductive elements beneath the inductor core. A second number of top half-coil forming conductive elements, made of bond wires, three dimensionally formed interconnection plates or upper leadframe leads, are located atop the inductor core with both ends of each element connected to respective bottom half-coil forming conductive elements to jointly form an inductive coil enclosing the inductor core. A top encapsulant protectively encases the inductor core, the top half-coil forming conductive elements, the bottom half-coil forming conductive elements and the circuit substrate.

Abstract: A semiconductor power device package having a lead frame-based integrated inductor is disclosed. The semiconductor power device package includes a lead frame having a plurality of leads, a inductor core attached to the lead frame such that a plurality of lead ends are exposed through a window formed in the inductor core, a plurality of bonding wires, ones of the plurality of bonding wires coupling each of the plurality of lead ends to adjacent leads about the inductor core to form the inductor, and a power integrated circuit coupled to the inductor. In alternative embodiments, a top lead frame couples each of the plurality of lead ends to adjacent leads about the inductor core by means of a connection chip.

Abstract: A substrate may receive an integrated circuit and a flex circuit on the same side in the same vertical direction. In addition, in some embodiments, a flex circuit adapter and the integrated circuit may be surface mounted in one operation.

Abstract: A leadframe with a structure made of a base metal (105), wherein the structure has a plurality of surfaces. On each of these surfaces are metal layers in a stack adherent to the base metal. The stack comprises a nickel layer (201) in contact with the base metal, a palladium layer (202) in contact with the nickel layer, and an outermost tin layer (203) in contact with the palladium layer. In terms of preferred layer thicknesses, the nickel layer is between about 0.5 and 2.0 ?m thick, the palladium layer between about 5 and 150 nm thick, and the tin layer less than about 5 nm thick, preferably about 3 nm. At this thinness, the tin has no capability of forming whiskers, but offers superb adhesion to polymeric encapsulation materials, improved characteristics for reliable stitch bonding as well as affinity to reflow metals (solders).

Abstract: Provided are a semiconductor lead frame, a semiconductor package having the semiconductor lead frame, and a method of plating the semiconductor lead frame. The method includes preparing a substrate formed of a Fe—Ni alloy (alloy 42), and a plating layer that contains grains less than 1 micrometer in size and is plated on the substrate. The growth of whiskers when a Sn plated layer is formed on a substrate formed of a Fe—Ni alloy (alloy 42) can be suppressed by minimizing the grain size of the Sn plated layer.