A support substrate has first electric contacts in a front face. An electronic component is located above the front face of the support substrate and has second electric contacts facing the first electric contacts of the support substrate. An electric connection structure is interposed between corresponding first and second electric contacts of the support substrate and the electronic component, respectively. Each electric connection structure is formed by: a shim that is made of a first electrically conducting material, and a coating that is made of a second electrically conducting material (different from the first electrically conducting material). The coating surrounds the shim and is in contact with the corresponding first and second electric contacts of the support substrate and the electronic component.

An electronic component includes an insulating base material including insulating base material layers, a first main surface that is a mounting surface, a coil, mounting electrodes provided on the first main surface, and a projection. The coil includes coil conductors provided on the insulating base material layers and a winding axis in a laminating direction of the insulating base material layers. The projection is provided in an electrode non-forming portion of the first main surface, the electrode non-forming portion including no mounting electrodes therein, and provided along the coil conductors in planar view of the first main surface.

A support substrate has first electric contacts in a front face. An electronic component is located above the front face of the support substrate and has second electric contacts facing the first electric contacts of the support substrate. An electric connection structure is interposed between corresponding first and second electric contacts of the support substrate and the electronic component, respectively. Each electric connection structure is formed by: a shim that is made of a first electrically conducting material, and a coating that is made of a second electrically conducting material (different from the first electrically conducting material). The coating surrounds the shim and is in contact with the corresponding first and second electric contacts of the support substrate and the electronic component.

A method of manufacturing a component carrier is disclosed. The method includes galvanically depositing at least part of at least one electrically conductive pillar on a component, and inserting the at least one electrically conductive pillar and an electrically insulating layer structure into one another.

A semiconductor package module is provided. The semiconductor package module may prevent dropout of a large-scale device from a module substrate by improving bonding strength between the module substrate and a part, and perform assembling parts on a top surface and a bottom surface of the module substrate, simultaneously. The semiconductor package module includes: a module substrate; at least one first electric/electronic device mounted on the module substrate by using surface mount technology (SMT); a plurality of passive devices mounted on the module substrate; and at least one second electric/electronic device mounted on the module substrate by using SMT and a resin film adhesive, the at least one second electric/electronic device having a size or a weight greater than a size or a weight of the at least one first electric/electronic device.

An embodiment composite material for semiconductor package mount applications may include a first component including a tin-silver-copper alloy and a second component including a tin-bismuth alloy or a tin-indium alloy. The composite material may form a reflowed bonding material having a room temperature tensile strength in a range from 80 MPa to 100 MPa when subjected to a reflow process. The reflowed bonding material may include a weight fraction of bismuth that is in a range from approximately 4% to approximately 15%. The reflowed bonding material may an alloy that is solid solution strengthened by a presence of bismuth or indium that is dissolved within the reflowed bonding material or a solid solution phase that includes a minor component of bismuth dissolved within a major component of tin. In some embodiments, the reflowed bonding material may include intermetallic compounds formed as precipitates such as Ag.sub.3Sn and/or Cu.sub.6Sn.sub.5.

A mounting structure includes a bonding material (106) that bonds second electrodes (104) of a circuit board (105) and bumps (103) of a semiconductor package (101), the bonding material (106) being surrounded by a first reinforcing resin (107). Moreover, a portion between the outer periphery of the semiconductor package (101) and the circuit board (105) is covered with a second reinforcing resin (108). Even if the bonding material (106) is a solder material having a lower melting point than a conventional bonding material, high drop resistance is obtained.

A semiconductor package module is provided. The semiconductor package module may prevent dropout of a large-scale device from a module substrate by improving bonding strength between the module substrate and a part, and perform assembling parts on a top surface and a bottom surface of the module substrate, simultaneously. The semiconductor package module includes: a module substrate; at least one first electric/electronic device mounted on the module substrate by using surface mount technology (SMT); a plurality of passive devices mounted on the module substrate; and at least one second electric/electronic device mounted on the module substrate by using SMT and a resin film adhesive, the at least one second electric/electronic device having a size or a weight greater than a size or a weight of the at least one first electric/electronic device.

A method of manufacturing a component carrier is disclosed. The method includes galvanically depositing at least part of at least one electrically conductive pillar on a component, and inserting the at least one electrically conductive pillar and an electrically insulating layer structure into one another.

An electronic component includes an insulating base material including insulating base material layers, a first main surface that is a mounting surface, a coil, mounting electrodes provided on the first main surface, and a projection. The coil includes coil conductors provided on the insulating base material layers and a winding axis in a laminating direction of the insulating base material layers. The projection is provided in an electrode non-forming portion of the first main surface, the electrode non-forming portion including no mounting electrodes therein, and provided along the coil conductors in planar view of the first main surface.