摘要:
Disclosed is tin characterized in that a sample of the tin after melting and casting has an α dose of less than 0.0005 cph/cm2. Since recent semiconductor devices are highly densified and of high capacity, there is an increasing risk of soft errors caused by the influence of α rays emitted from materials in the vicinity of semiconductor chips. In particular, there are strong demands for high purification of solder materials and tin for use in the vicinity of semiconductor devices, and demands for materials with lower α rays. Accordingly, an object of the present invention is to clarify the phenomenon of the generation of α rays in tin and tin alloys, and to obtain high-purity tin, in which the α dose has been reduced, suitable for the required materials, as well as a method for producing the same.
摘要翻译:公开了锡,其特征在于熔融和铸造后的锡样品的α剂量小于0.0005cph / cm 2。 由于近来的半导体器件具有高度致密化和高容量性,所以存在由半导体芯片附近的材料发射的α射线的影响引起的软误差的风险增加。 特别是对于在半导体器件附近使用的焊料材料和锡的高纯化性以及对α射线较低的材料的要求的要求较高。 因此,本发明的目的在于明确在锡和锡合金中产生α射线的现象,并获得适合所需材料的α剂量已经降低的高纯度锡 作为其制造方法。
摘要:
An object of the present invention is to provide a high-purity Ru alloy target for sputtering and its manufacturing method, which are capable of reducing harmful substances as much as possible, refining the crystal grains as much as possible so as to make the film thickness distribution during deposition to be uniform, and preventing deterioration in adhesiveness with an Si substrate, and which are suitable in forming a capacitor electrode material of a semiconductor memory, as well as a high-purity Ru alloy sputtered film obtained by sputtering this Ru alloy target.In order to achieve the foregoing object, the present invention provides a high-purity Ru alloy target, wherein the content of the platinum group elements excluding Ru is 15 to 200 and remnants are Ru and inevitable impurities. Also, provided is the manufacturing method of a high-purity Ru alloy target, wherein the content of platinum group elements excluding Ru is 15 to 200 wtppm and remnants are Ru and inevitable impurities, including the steps of mixing Ru powder having a purity level of 99.9% or higher and powder of platinum group elements excluding Ru, performing press molding the mixed powder to obtain a compact, performing electron beam melting to the compact to obtain an ingot, and performing forge processing to the ingot to obtain a target.
摘要:
Copper or a copper alloy characterized in having an α-ray emission of 0.001 cph/cm2 or less. Since recent semiconductor devices are produced to have higher density and higher capacity, there is greater risk of soft errors caused by the influence of α rays emitted from materials positioned near semiconductor chips. In particular, there are strong demands for achieving higher purification of copper and copper alloys which are used near the semiconductor device, such as copper or copper alloy wiring lines, copper or copper alloy bonding wires, and soldering materials, and materials reduced in α-ray emission are also demanded. Thus, the present invention elucidates the phenomenon in which α rays are emitted from copper or copper alloys, and provides copper or copper alloy reduced in α-ray emission which is adaptable to the demanded material, and a bonding wire in which such copper or copper alloy is used as its raw material.
摘要翻译:铜或铜合金,其特征在于具有0.001cph / cm 2以下的α射线发射。 由于最近制造的半导体器件具有更高的密度和更高的容量,所以由位于半导体芯片附近的材料发射的α射线的影响引起的软错误的风险更大。 特别是对于半导体器件附近使用的铜,铜合金,铜或铜合金布线,铜或铜合金接合线以及焊接材料,以及α- 还要求射线辐射。 因此,本发明阐明了从铜或铜合金发射α射线的现象,并且提供了能够适应所需材料的减少的α射线发射的铜或铜合金;以及接合线,其中这种铜或铜 合金作为原料。
摘要:
Provided are high-purity lanthanum, wherein the purity excluding rare-earth elements and gas components is 4N or higher, and amounts of aluminum, iron and copper in the lanthanum are respectively 100 wtppm or less; as well as high-purity lanthanum, wherein the purity excluding rare-earth elements and gas components is 4N or higher, amounts of aluminum, iron and copper in the lanthanum are respectively 100 wtppm or less, oxygen content is 1500 wtppm or less, elements of alkali metals and alkali earth metals are respectively 1 wtppm or less, elements of transition metals and high-melting-point metals other than those above are respectively 10 wtppm or less, and radioactive elements are respectively 10 wtppb or less. The invention aims to provide technology capable of efficiently and stably providing high-purity lanthanum, a sputtering target comprising high-purity lanthanum, and a thin film for metal gate mainly comprising high-purity lanthanum.
摘要:
Provided are high-purity lanthanum, wherein the purity excluding rare-earth elements and gas components is 4N or higher, and amounts of aluminum, iron and copper in the lanthanum are respectively 100 wtppm or less; as well as high-purity lanthanum, wherein the purity excluding rare-earth elements and gas components is 4N or higher, amounts of aluminum, iron and copper in the lanthanum are respectively 100 wtppm or less, oxygen content is 1500 wtppm or less, elements of alkali metals and alkali earth metals are respectively 1 wtppm or less, elements of transition metals and high-melting-point metals other than those above are respectively 10 wtppm or less, and radioactive elements are respectively 10 wtppb or less. The invention aims to provide technology capable of efficiently and stably providing high-purity lanthanum, a sputtering target comprising high-purity lanthanum, and a thin film for metal gate mainly comprising high-purity lanthanum.
摘要:
Disclosed is tin characterized in that a sample of the tin after melting and casting has an α dose of less than 0.0005 cph/cm2. Since recent semiconductor devices are highly densified and of high capacity, there is an increasing risk of soft errors caused by the influence of α rays emitted from materials in the vicinity of semiconductor chips. In particular, there are strong demands for high purification of solder materials and tin for use in the vicinity of semiconductor devices, and demands for materials with lower α rays. Accordingly, an object of the present invention is to clarify the phenomenon of the generation of α rays in tin and tin alloys, and to obtain high-purity tin, in which the α dose has been reduced, suitable for the required materials, as well as a method for producing the same.
摘要翻译:公开了锡,其特征在于熔融和铸造后的锡样品的α剂量小于0.0005cph / cm 2。 由于近来的半导体器件具有高度致密化和高容量性,所以存在由半导体芯片附近的材料发射的α射线的影响引起的软误差的风险增加。 特别是对于在半导体器件附近使用的焊料材料和锡的高纯化性以及对α射线较低的材料的要求的要求较高。 因此,本发明的目的在于明确在锡和锡合金中产生α射线的现象,并获得适合所需材料的α剂量已经降低的高纯度锡 作为其制造方法。
摘要:
In order to obtain a high purity sputtered film for a capacitor electrode of a semiconductor memory and to make the sputtered film have uniform thickness and good adhesiveness with Si substrate, a high-purity Ru alloy target is provided, wherein a total content of the platinum group elements excluding Ru is in a range of 15 to 200 wtppm and remnants are Ru and inevitable impurities. Also, provided is a manufacturing method of the high-purity Ru alloy target, comprising the steps of mixing Ru powder having a purity of 99.9% or higher and powder of platinum group elements excluding Ru, performing press molding of the mixed powder to obtain a compact, performing electron beam melting of the compact to obtain an ingot, and forging the ingot at 1400 to 1900° C.
摘要:
Copper or a copper alloy characterized in having an α-ray emission of 0.001 cph/cm2 or less. Since recent semiconductor devices are produced to have higher density and higher capacity, there is greater risk of soft errors caused by the influence of α rays emitted from materials positioned near semiconductor chips. In particular, there are strong demands for achieving higher purification of copper and copper alloys which are used near the semiconductor device, such as copper or copper alloy wiring lines, copper or copper alloy bonding wires, and soldering materials, and materials reduced in α-ray emission are also demanded. Thus, the present invention elucidates the phenomenon in which α rays are emitted from copper or copper alloys, and provides copper or copper alloy reduced in α-ray emission which is adaptable to the demanded material, and a bonding wire in which such copper or copper alloy is used as its raw material.