TWI796739B - Alloy bonding wire - Google Patents

Alloy bonding wire Download PDF

Info

Publication number
TWI796739B
TWI796739B TW110127276A TW110127276A TWI796739B TW I796739 B TWI796739 B TW I796739B TW 110127276 A TW110127276 A TW 110127276A TW 110127276 A TW110127276 A TW 110127276A TW I796739 B TWI796739 B TW I796739B
Authority
TW
Taiwan
Prior art keywords
wire
alloy
welding wire
alloy welding
silver
Prior art date
Application number
TW110127276A
Other languages
Chinese (zh)
Other versions
TW202304629A (en
Inventor
蔡幸樺
莊東漢
Original Assignee
樂金股份有限公司
Priority date (The priority date is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the date listed.)
Filing date
Publication date
Application filed by 樂金股份有限公司 filed Critical 樂金股份有限公司
Priority to TW110127276A priority Critical patent/TWI796739B/en
Publication of TW202304629A publication Critical patent/TW202304629A/en
Application granted granted Critical
Publication of TWI796739B publication Critical patent/TWI796739B/en

Links

Images

Landscapes

  • Conductive Materials (AREA)
  • Wire Bonding (AREA)

Abstract

An alloy bonding wire is provided. The alloy bonding wires contain a base material of Ag, Cu, or Al added with 0.001~2wt% of Ge. When the base material is Cu or Al, the alloy bonding wire may further contain 0.001~10wt% of at least one of Pt, Pd, Cu, Au, Ni, Si, and Sc elements. When the base material is Ag, the alloy bonding wire may further contain 0.001~10wt% of at least one of Pd, Cu, Au, Ni, Si, and Sc elements.

Description

合金銲線Alloy wire

本發明係有關於一種合金銲線,且特別關於用於電子封裝打線接合的合金銲線。The present invention relates to an alloy welding wire, and in particular to an alloy welding wire used for electronic package wire bonding.

打線接合為積體電路(IC)及發光二極體(LED)封裝製程的主要內連線(interconnection)方法。打線接合線材除了提供晶片與基材之間的訊號與功率傳輸,亦可兼具散熱功能。因此打線接合線材必須有高導電性、高導熱性、足夠的強度及延展性。但為了避免打線接合之熱壓過程導致晶片破裂,同時使線材與銲墊接觸良好以確保良好的接合性,線材的硬度不能太高。由於封裝之高分子封膠常含有腐蝕性氯離子,且高分子封膠本身具環境吸濕性,線材必須有良好的抗氧化性與耐腐蝕性。Wire bonding is the main interconnection method in the packaging process of integrated circuits (IC) and light emitting diodes (LED). In addition to providing signal and power transmission between the chip and the substrate, the wire bonding wire can also have the function of heat dissipation. Therefore, the wire bonding wire must have high electrical conductivity, high thermal conductivity, sufficient strength and ductility. However, in order to avoid the cracking of the chip caused by the hot-pressing process of wire bonding, and to ensure good contact between the wire and the pad to ensure good bonding, the hardness of the wire should not be too high. Since the polymer sealant for packaging often contains corrosive chloride ions, and the polymer sealant itself has environmental hygroscopicity, the wire must have good oxidation resistance and corrosion resistance.

在打線接合過程,首先要將線材末端以高壓放電方式燒熔(Electric Flame Off, EFO),利用表面張力形成結球(Free Air Ball, FAB),再將結球經由瓷嘴銲針下壓而與一銲墊接合形成第一銲點,而線材的另一端則會被牽拉至另一導電銲墊處,並與另一導電銲墊接合,形成第二銲點,藉此構成一電路的導通。結球的形狀決定後續第一球銲點(ball bond)的品質。此外,第一球銲點與半導體晶片銲墊的接合界面會形成介金屬化合物(intermetallic compounds)。這些介金屬化合物可確保界面接合性,但過量的介金屬化合物會造成界面脆裂及產生科肯達孔洞(Kirkendall voids)。另外,線材本身的抗氧化及腐蝕性更是決定電子產品可靠度的要件。In the wire bonding process, the end of the wire must first be fused by high-voltage discharge (Electric Flame Off, EFO), and the surface tension is used to form a ball (Free Air Ball, FAB). The welding pads are bonded to form a first welding point, and the other end of the wire is pulled to another conductive welding pad and joined with another conductive welding pad to form a second welding point, thereby forming a circuit conduction. The shape of the ball determines the quality of the subsequent first ball bond. In addition, intermetallic compounds are formed at the bonding interface between the first ball pad and the pad of the semiconductor chip. These intermetallic compounds can ensure interfacial bonding, but excessive intermetallic compounds can cause interface brittle cracks and Kirkendall voids. In addition, the anti-oxidation and corrosion resistance of the wire itself are the elements that determine the reliability of electronic products.

當半導體或發光二極體封裝完成,產品在使用過程,通過線材的高電流密度也可能帶動內部原子產生電遷移現象(Electron Migration),使得線材一端形成孔洞,因而降低導電性與導熱性,甚至造成斷線及產品失效;通電流也可能使封裝線材局部燒熔,使電壓急速上升,最後同樣導致斷線及產品失效,此問題對於高電壓大電流電子產品的封裝尤其嚴重,是影響這些電子產品可靠度的主要因素。When the packaging of the semiconductor or light-emitting diode is completed, the high current density passing through the wire may also drive the internal atoms to generate electromigration (Electron Migration) during the use of the product, causing holes to form at one end of the wire, thereby reducing electrical conductivity and thermal conductivity, and even Cause disconnection and product failure; the current may also cause partial melting of the packaging wire, causing the voltage to rise rapidly, and finally lead to disconnection and product failure. This problem is especially serious for the packaging of high-voltage and high-current electronic products. The main factor of product reliability.

目前常見的封裝導線,例如包括下列幾種選擇:Currently common packaging wires, for example, include the following options:

(1)金線:金線可具有低電阻率,但是金線與鋁墊打線接合界面會大量的形成脆性介金屬化合物(包括Au 2Al、AuAl 4、Au 5Al 2等),使得導電性降低。此外,金/鋁界面介金屬反應會伴隨產生許多柯肯達孔洞(Kirkendall voids),更加提高接合界面電阻率,而導致接點的可靠度降低。 (1) Gold wire: Gold wire can have low resistivity, but a large number of brittle intermetallic compounds (including Au 2 Al, AuAl 4 , Au 5 Al 2 , etc.) will be formed at the bonding interface between gold wire and aluminum pad, making the conductivity reduce. In addition, the intermetallic reaction at the gold/aluminum interface will produce many Kirkendall voids, which will further increase the resistivity of the joint interface, resulting in a decrease in the reliability of the joint.

(2)銅線:近年來,封裝產業開始採用銅線作為半導體及發光二極體打線接合的線材。銅線雖具有較佳的導電性,但卻很容易氧化,故在線材儲存及運送過程均需要密封保護,打線接合製程更需要昂貴的氮氣加氫氣輔助,且在後續封裝電子產品可靠度試驗仍然會遭遇氧化及腐蝕性的問題。此外,銅線材質太硬,打線接合容易造成晶片破裂等問題。雖然在一些研究中提出在銅線表面鍍上其他金屬鍍層以改善易氧化及腐蝕問題的方法(例如參照美國專利US7645522B2、US2003/0173659A1、US7820913B2),但由於銅線本身硬度高,造成打線接合步驟易失敗,故仍無法達到高電壓大電流電子產品封裝時所需的可靠度。(2) Copper wire: In recent years, the packaging industry has begun to use copper wire as the wire bonding wire for semiconductors and light-emitting diodes. Although copper wire has good electrical conductivity, it is easy to oxidize. Therefore, the storage and transportation of wire rods need to be sealed and protected. The wire bonding process requires expensive nitrogen and hydrogen assistance. Will encounter oxidation and corrosion problems. In addition, the material of the copper wire is too hard, and the wire bonding is likely to cause problems such as cracking of the chip. Although it has been proposed in some studies to plate other metal coatings on the surface of copper wires to improve the oxidation and corrosion problems (for example, refer to US Patent No. It is easy to fail, so it still cannot achieve the reliability required for packaging high-voltage and high-current electronic products.

(3)銀線:銀是在所有材料中電阻率最低的元素,但是純銀在含硫的環境會有硫化腐蝕的問題,同時純銀線在鋁墊上打線接合時也會生成脆性的介金屬化合物(Ag 2Al或Ag 4Al)。此外,純銀線在含水氣的封裝材料內部很容易發生電解離子遷移現象(Ion Migration)。亦即,純銀在含水氣環境會經由電流作用水解溶出銀離子,再與氧反應成為不穩定的氧化銀(AgO),此氧化銀因而會進行去氧化作用(Deoxidize)形成銀原子,並向正極成長出樹葉紋理狀(leaf vein)的銀鬚,最後造成正負電極的短路(請參考:H. Tsutomu, Metal Migration on Electric Circuit Boards, Three Bond Technical News, Dec. 1, 1986.)。此外,在一些研究中提出在銀線表面鍍上其他金屬鍍層以改善硫化腐蝕及銀離子遷移的問題的方法(例如參照美國專利US6696756),但所形成的線材仍無法達到理想的可靠度及電阻率。 (3) Silver wire: Silver is the element with the lowest resistivity among all materials, but pure silver will have the problem of sulfide corrosion in a sulfur-containing environment, and at the same time, pure silver wire will also generate brittle intermetallic compounds when bonding on aluminum pads ( Ag 2 Al or Ag 4 Al). In addition, pure silver wires are prone to electrolytic ion migration (Ion Migration) inside the packaging material containing moisture. That is to say, pure silver will hydrolyze and dissolve silver ions through the action of electric current in the environment containing water and gas, and then react with oxygen to become unstable silver oxide (AgO). Silver whiskers grow out of leaf veins, and finally cause a short circuit between the positive and negative electrodes (please refer to: H. Tsutomu, Metal Migration on Electric Circuit Boards, Three Bond Technical News, Dec. 1, 1986.). In addition, in some studies, it is proposed to plate other metal coatings on the surface of silver wires to improve the problems of sulfide corrosion and silver ion migration (for example, refer to US Patent No. 6,696,756), but the formed wires still cannot achieve ideal reliability and resistance. Rate.

(4)合金線:合金線例如包括以金為主的合金以及以銀為主的合金。這些合金例如更包括銅、鉑、錳、鉻、鈣、銦等元素,然而這些合金線仍然無法同時兼具低阻抗及高可靠度的性質。(4) Alloy wire: The alloy wire includes, for example, gold-based alloys and silver-based alloys. These alloys include, for example, elements such as copper, platinum, manganese, chromium, calcium, indium, etc. However, these alloy wires still cannot have properties of low impedance and high reliability at the same time.

綜上所述,現有的各種純金屬線材、表面鍍金屬的複合線材、以及添加元素的合金線材在封裝上無法滿足全部的需求,因此,目前仍需一種具高可靠度的線材。To sum up, the existing pure metal wires, metal-coated composite wires, and alloy wires with added elements cannot meet all the packaging requirements. Therefore, there is still a need for a wire with high reliability.

本揭露的一些實施例提供一種合金銲線,其基材為銀、銅或鋁中任一者,其包括0.001至2wt.%的Ge,及餘量的基材。Some embodiments of the present disclosure provide an alloy bonding wire, the base material of which is any one of silver, copper or aluminum, including 0.001 to 2 wt.% of Ge, and the rest of the base material.

在一些實施例中,合金銲線為二元合金銲線。In some embodiments, the alloy wire is a binary alloy wire.

在一些實施例中,合金銲線的基材為銅或鋁,且更包括取自Pt、Pd、Cu、Au、Ni、Si或Sc中至少一者的添加元素,添加元素的總添加量為0.001至10wt.%。In some embodiments, the base material of the alloy welding wire is copper or aluminum, and further includes an additional element obtained from at least one of Pt, Pd, Cu, Au, Ni, Si or Sc, and the total amount of the added element is 0.001 to 10 wt.%.

在一些實施例中,合金銲線的基材為銀,且更包括取自Pd、Cu、Au、Ni、Si或Sc中至少一者的添加元素,添加元素的總添加量為0.001至10wt.%。In some embodiments, the base material of the alloy wire is silver, and further includes an additional element obtained from at least one of Pd, Cu, Au, Ni, Si or Sc, and the total amount of the added element is 0.001 to 10wt. %.

在一些實施例中,合金銲線為一圓形銲線。In some embodiments, the alloy wire is a round wire.

在一些實施例中,合金銲線的直徑為10μm至300μm。In some embodiments, the alloy wire has a diameter of 10 μm to 300 μm.

在一些實施例中,合金銲線為一扁帶形銲線。In some embodiments, the alloy wire is a flat ribbon wire.

在一些實施例中,合金銲線的厚度為20μm至300μm。In some embodiments, the alloy wire has a thickness of 20 μm to 300 μm.

在一些實施例中,合金銲線的寬度為100μm至2000μm。In some embodiments, the alloy wire has a width of 100 μm to 2000 μm.

在一些實施例中,合金銲線更包括一表面鍍層,表面鍍層含Au、Pd、Pt、其合金或其組合,且表面鍍層的厚度為0.01至10μm。In some embodiments, the alloy bonding wire further includes a surface coating, the surface coating includes Au, Pd, Pt, alloys thereof or a combination thereof, and the thickness of the surface coating is 0.01 to 10 μm.

以下揭露提供了許多的實施例或範例,用於實施所提供的標的物之不同元件。各元件和其配置的具體範例描述如下,以簡化本發明實施例之說明。當然,這些僅僅是範例,並非用以限定本發明實施例。舉例而言,敘述中若提及第一元件形成在第二元件之上,可能包含第一和第二元件直接接觸的實施例,也可能包含額外的元件形成在第一和第二元件之間,使得它們不直接接觸的實施例。此外,本發明實施例可能在各種範例中重複參考數值或字母。如此重複是為了簡明和清楚之目的,而非用以表示所討論的不同實施例或配置之間的關係。The following disclosure provides a number of embodiments, or examples, for implementing different elements of the provided subject matter. Specific examples of each component and its configuration are described below to simplify the description of the embodiments of the present invention. Of course, these are just examples, not intended to limit the embodiments of the present invention. For example, if a description mentions that a first element is formed on a second element, it may include an embodiment in which the first and second elements are in direct contact, or may include an additional element formed between the first and second elements , so that they are not in direct contact with the example. In addition, the embodiments of the present invention may repeat reference numerals or letters in various examples. This repetition is for the purpose of brevity and clarity and not to show the relationship between the different embodiments or configurations discussed.

再者,其中可能用到與空間相對用詞,例如「在……之下」、「下方」、「較低的」、「上方」、「較高的」等類似用詞,是為了便於描述圖式中一個(些)部件或特徵與另一個(些)部件或特徵之間的關係。空間相對用詞用以包括使用中或操作中的裝置之不同方位,以及圖式中所描述的方位。當裝置被轉向不同方位時(旋轉90度或其他方位),其中所使用的空間相對形容詞也將依轉向後的方位來解釋。Furthermore, terms relative to space may be used, such as "below", "below", "lower", "above", "higher", etc., for the convenience of description The relationship between one component or feature(s) and another component(s) or feature(s) in a drawing. Spatially relative terms are intended to encompass different orientations of the device in use or operation, as well as orientations depicted in the drawings. When the device is turned to a different orientation (rotated 90 degrees or otherwise), the spatially relative adjectives used therein shall also be interpreted in accordance with the turned orientation.

此處所使用的用語「約」、「近似」等類似用語描述數字或數字範圍時,該用語意欲涵蓋的數值是在合理範圍內包含所描述的數字,例如在所描述的數字之+/- 10%之內,或本發明所屬技術領域中具有通常知識者理解的其他數值。例如,用語「約5 nm」涵蓋從4.5nm至5.5nm的尺寸範圍。When the terms "about", "approximately" and similar terms are used herein to describe numbers or numerical ranges, the terms are intended to cover values that include the stated number within a reasonable range, such as +/- 10% of the stated number. %, or other values understood by those skilled in the art to which the present invention pertains. For example, the phrase "about 5 nm" encompasses a size range from 4.5 nm to 5.5 nm.

本文所用用語僅用以闡釋特定實施例,而並非旨在限制本發明概念。除非表達在上下文中具有明確不同的含義,否則以單數形式使用的所述表達亦涵蓋複數形式的表達。在本說明書中,應理解,例如「包含」、「具有」、及「包括」等用語旨在指示本說明書中所揭露的特徵、數目、步驟、動作、組件、部件或其組合的存在,而並非旨在排除可存在或可添加一或多個其他特徵、數目、步驟、動作、組件、部件或其組合的可能性。The terms used herein are used to illustrate specific embodiments only, and are not intended to limit the inventive concepts. The expressions used in the singular also encompass the expressions in the plural unless the expressions have clearly different meanings in the context. In this specification, it should be understood that terms such as "comprising", "having", and "including" are intended to indicate the existence of the features, numbers, steps, actions, components, components or combinations thereof disclosed in this specification, and It is not intended to exclude the possibility that one or more other features, numbers, steps, actions, components, parts or combinations thereof may be present or may be added.

本揭露提供一種合金銲線,其組成為在銀、銅或鋁基材添加0.001至2wt.%的Ge,以及再添加0.001至10wt.%選自Pt、Pd、Cu、Au、Ni、Si、或Sc中至少一種的添加元素,此合金組成可提升銲線的抗高溫潛變性、抗硫化性、抗氧化性以及光澤性較佳,因此具有極佳的可靠度。The present disclosure provides an alloy welding wire, which is composed of adding 0.001 to 2wt.% of Ge to a silver, copper or aluminum substrate, and adding 0.001 to 10wt.% selected from Pt, Pd, Cu, Au, Ni, Si, Or at least one additional element in Sc, this alloy composition can improve the high temperature creep resistance, sulfidation resistance, oxidation resistance and gloss of the welding wire, so it has excellent reliability.

US8101123B2專利揭示一種Ag-Au-Pd組成的銀合金線材,雖然其在Ag合金組成內添加Au與Pd可改善純銀線的機械性質與抗氧化性,添加Pd更可減緩銀的離子遷移問題,然而此種組成之合金線材的抗高溫潛變性不佳,且其抗硫化性、抗氧化性及光澤性亦較差。US20130171470專利揭示一種Ag-Au-Pd組成且其晶粒結構呈現大量退火孿晶的銀合金線材,雖然其孿晶結構可提升線材的電遷移壽命,但是在抗高溫潛變性、抗硫化性、抗氧化性及光澤性亦均不足。JP1997275120、US20080240975A1、CN10215454A、US20130126934、TWI408787及US10840208B2等專利則在Ag合金內添加Pt及其他微量元素,然而這些習知技術的銀合金線材同樣抗高溫潛變性不足,而且其光澤性及抗硫化性亦均較差。The US8101123B2 patent discloses a silver alloy wire composed of Ag-Au-Pd. Although the addition of Au and Pd to the Ag alloy composition can improve the mechanical properties and oxidation resistance of pure silver wire, and the addition of Pd can slow down the silver ion migration problem, however The alloy wire rod of this composition has poor creep resistance at high temperature, and its sulfidation resistance, oxidation resistance and luster are also poor. The US20130171470 patent discloses a silver alloy wire composed of Ag-Au-Pd and whose grain structure exhibits a large number of annealing twins. Oxidability and luster were also insufficient. Patents such as JP1997275120, US20080240975A1, CN10215454A, US20130126934, TWI408787, and US10840208B2 add Pt and other trace elements to the Ag alloy. However, the silver alloy wire rods of these known technologies also have insufficient high-temperature creep resistance, and their gloss and sulfidation resistance are also insufficient. Both are poor.

而本案的銲線通過在銀、銅或鋁基材中添加0.001至2wt.%的Ge,可非常顯著提升抗高溫潛變性,同時其抗硫化性、抗氧化性以及光澤性亦得到改善。在一些實施例中,如果鍺的含量過高時,可能會使銲線延展性降低。除了Ge以外,本案之銲線可另外再添加0.001至10wt.%選自Pt、Pd、Cu、Au、Ni、Si、或Sc中至少一種的添加元素,可提升銲線的強度,並且更加改善銲線的抗氧化及氯離子腐蝕性,同時也減少銀合金線與鋁墊形成介金屬化合物。在一些實施例中,如果這些第三元素的含量過高時,可能會使銲線的電阻率明顯提高。In this case, by adding 0.001 to 2wt.% Ge to the silver, copper or aluminum substrate, the high temperature creep resistance can be significantly improved, and its sulfidation resistance, oxidation resistance and gloss are also improved. In some embodiments, if the content of germanium is too high, the ductility of the bonding wire may be reduced. In addition to Ge, the bonding wire in this case can add 0.001 to 10wt.% of at least one additional element selected from Pt, Pd, Cu, Au, Ni, Si, or Sc, which can increase the strength of the bonding wire and further improve The anti-oxidation and chloride ion corrosion resistance of the welding wire also reduces the formation of intermetallic compounds between the silver alloy wire and the aluminum pad. In some embodiments, if the content of these third elements is too high, the resistivity of the bonding wire may be significantly increased.

根據一些實施例,第1圖為本揭露第一形態之圓形合金銲線10。第1圖是圓形合金銲線10的一部分線段,圓形合金銲線10的基材為銀、銅或鋁,其包括0.001至2wt.%的Ge及餘量的基材,例如約0.01至約1wt%或約0.05至約2.0wt%的Ge。根據一些實施例,合金銲線10為二元合金銲線,即除了基材之外,只含有Ge。根據一些實施例,合金銲線10的基材為銅或鋁,且合金銲線10更包括選自Pt、Pd、Cu、Au、Ni、Si、或Sc中至少一者的添加元素,且上述添加元素的總添加量為0.001至10wt.%,例如約0.01至約1wt.%或約0.05至約5wt.%。根據一些實施例,合金銲線10的基材為銀,且合金銲線10更包括選自Pd、Cu、Au、Ni、Si、或Sc中至少一者的添加元素,且上述添加元素的總添加量為0.001至10wt.%,例如約0.01至約1wt.%或約0.05至約5wt.%。應該注意的是,當合金銲線10的基材為銀時,上述添加元素中不含Pt。其中銀、銅或鋁基材為實質上的純銀、純銅或純鋁。圓形合金銲線10的直徑為約10μm至約300μm,例如約100μm至200μm或約50μm至250μm。According to some embodiments, FIG. 1 is a round alloy welding wire 10 in a first form of the present disclosure. Fig. 1 is a part of the line segment of the round alloy welding wire 10, the base material of the round alloy welding wire 10 is silver, copper or aluminum, which includes 0.001 to 2wt.% Ge and the base material of the balance, such as about 0.01 to About 1 wt % or about 0.05 to about 2.0 wt % Ge. According to some embodiments, alloy wire 10 is a binary alloy wire, ie, contains only Ge in addition to the base material. According to some embodiments, the base material of the alloy welding wire 10 is copper or aluminum, and the alloy welding wire 10 further includes an additional element selected from at least one of Pt, Pd, Cu, Au, Ni, Si, or Sc, and the above-mentioned The total amount of added elements is 0.001 to 10 wt.%, for example about 0.01 to about 1 wt.% or about 0.05 to about 5 wt.%. According to some embodiments, the base material of the alloy welding wire 10 is silver, and the alloy welding wire 10 further includes an additive element selected from at least one of Pd, Cu, Au, Ni, Si, or Sc, and the total of the above additive elements The added amount is 0.001 to 10 wt.%, such as about 0.01 to about 1 wt.% or about 0.05 to about 5 wt.%. It should be noted that when the base material of the alloy bonding wire 10 is silver, Pt is not included in the above-mentioned additive elements. Wherein the silver, copper or aluminum substrate is substantially pure silver, pure copper or pure aluminum. The round alloy wire 10 has a diameter of about 10 μm to about 300 μm, such as about 100 μm to 200 μm or about 50 μm to 250 μm.

在一些實施例中,上述圓形合金銲線亦可在外層上均勻被覆表面鍍層,如第2A圖至第2B圖所示,且第2B圖為第2A圖的長度方向的縱切面圖。其中表面鍍層22可包括實質上的純金、實質上的純鈀、實質上的純鉑、其合金或其組合。可以適當之鍍層方法形成表面鍍層22(例如:電鍍、濺鍍及真空蒸鍍)。藉由表面鍍層22的材質的化學惰性,可保護其內的圓形合金銲線20而避免其受到腐蝕,同時在抽線成形時發揮潤滑效果,且表面鍍層22的厚度約0.01至約10μm,例如約0.1μm至約5μm或約1μm至約8μm。In some embodiments, the above-mentioned round alloy wire can also be uniformly coated with a surface coating on the outer layer, as shown in FIG. 2A to FIG. 2B , and FIG. 2B is a longitudinal section view along the longitudinal direction of FIG. 2A . The surface coating 22 may include substantially pure gold, substantially pure palladium, substantially pure platinum, alloys thereof, or combinations thereof. The surface coating 22 can be formed by an appropriate coating method (for example: electroplating, sputtering and vacuum evaporation). Due to the chemical inertness of the material of the surface coating 22, the circular alloy welding wire 20 inside can be protected from corrosion, and at the same time, it has a lubricating effect when the wire is drawn, and the thickness of the surface coating 22 is about 0.01 to about 10 μm. For example about 0.1 μm to about 5 μm or about 1 μm to about 8 μm.

根據一些實施例,第3圖為本揭露第二形態之扁帶形合金銲線30。第3圖是扁帶形合金銲線30的一部分線段,扁帶形合金銲線30的材質及其添加元素可以參照第1圖所示的圓形合金銲線10,在此不再贅述。根據一些實施例,扁帶形合金銲線30的厚度為約20μm至約300μm,例如約50μm至約125μm或約100μm至約250μm。根據一些實施例,扁帶形合金銲線30的寬度為約100μm至約2000μm,例如約500μm至約1400μm或約1000μm至約1800μm。值得注意的是,在一些實施例中,上述扁帶形合金銲線亦可在外層上均勻被覆表面鍍層,如第4A圖至第4B圖所示,其中第4B圖為第4A圖的長度方向的縱切面圖。如前文所述,表面鍍層42可保護其內的合金銲線30避免其受到腐蝕,同時在抽線成形時發揮潤滑效果。表面鍍層42可包括實質上的純金、實質上的純鈀、實質上的純鉑、其合金或其組合。可以適當之鍍層方法形成表面鍍層42(例如:電鍍、濺鍍及真空蒸鍍),且表面鍍層42的厚度為約0.01至約10μm,例如約0.1μm至約5μm或約1μm至約8.5μm。According to some embodiments, FIG. 3 is a flat strip-shaped alloy welding wire 30 in the second form of the present disclosure. Fig. 3 is a part of the flat strip-shaped alloy welding wire 30. The material and additive elements of the flat strip-shaped alloy welding wire 30 can refer to the round alloy welding wire 10 shown in Fig. 1, and will not be repeated here. According to some embodiments, the thickness of the flat alloy wire 30 is from about 20 μm to about 300 μm, such as from about 50 μm to about 125 μm or from about 100 μm to about 250 μm. According to some embodiments, the flat strip-shaped alloy wire 30 has a width of about 100 μm to about 2000 μm, such as about 500 μm to about 1400 μm or about 1000 μm to about 1800 μm. It is worth noting that, in some embodiments, the above-mentioned flat strip-shaped alloy welding wire can also be uniformly coated with a surface coating on the outer layer, as shown in Figures 4A to 4B, where Figure 4B is the longitudinal direction of Figure 4A longitudinal section view. As mentioned above, the surface coating 42 can protect the alloy welding wire 30 therein from corrosion, and at the same time play a lubricating effect when the wire is drawn and formed. Surface plating 42 may include substantially pure gold, substantially pure palladium, substantially pure platinum, alloys thereof, or combinations thereof. The surface coating 42 can be formed by an appropriate coating method (for example: electroplating, sputtering and vacuum evaporation), and the thickness of the surface coating 42 is about 0.01 to about 10 μm, such as about 0.1 μm to about 5 μm or about 1 μm to about 8.5 μm.

關於說明書所述實質上的純金屬,以純銀為例,係指在設計上期望為完全不含其他元素、化合物等的雜質的純銀,但在實際冶煉、精煉、鍍膜等的過程中卻難以完全除去上述雜質而達成數學上或理論上含100%的純銀,就視為「實質上的純銀」,因此,在其他實施例中,合金銲線及/或其鍍層可更包括其他金屬、非金屬元素、或其他雜質成分,而當上述雜質含量的範圍落於對應的標準或規格所訂定的允收範圍內。本發明所屬技術領域中具有通常知識者應當瞭解依據不同的性質、條件、需求等等,上述對應的標準或規格會有所不同,故文中並未列出特定的標準或規格。Regarding the substantially pure metal mentioned in the specification, taking pure silver as an example, it refers to pure silver that is expected to be completely free of impurities such as other elements and compounds in design, but it is difficult to completely remove it during the actual smelting, refining, coating, etc. Removing the above-mentioned impurities and achieving mathematically or theoretically 100% pure silver is regarded as "substantially pure silver". Therefore, in other embodiments, the alloy welding wire and/or its plating layer may further include other metals, non-metals Elements, or other impurity components, and when the range of the above-mentioned impurity content falls within the acceptable range stipulated in the corresponding standards or specifications. Those with ordinary knowledge in the technical field of the present invention should understand that the above-mentioned corresponding standards or specifications will be different according to different properties, conditions, requirements, etc., so no specific standards or specifications are listed in this document.

在一些實施例中,上述合金銲線的形成方法可為先形成粗線材,再交替進行複數道冷加工成形步驟及複數道退火步驟,以逐次縮減該粗線材的線徑。粗線材的形成方法可為將合金加熱熔融後,經澆鑄而成為鑄錠。而後,對鑄錠進行冷加工,以形成粗線材。在一些實施例中,上述冷加工成形步驟包括抽線、擠型或前述之組合。或者,上述冷加工成形步驟及退火步驟可為任何已知或未來發展的冷加工/退火方式。In some embodiments, the forming method of the above-mentioned alloy welding wire may be to form a thick wire first, and then alternately perform a plurality of cold forming steps and a plurality of annealing steps, so as to successively reduce the diameter of the thick wire. The thick wire rod can be formed by heating and melting the alloy, and then casting it to form an ingot. The ingot is then cold worked to form thick wire. In some embodiments, the above-mentioned cold forming step includes wire drawing, extrusion or a combination thereof. Alternatively, the above-mentioned cold forming step and annealing step can be any known or future developed cold working/annealing methods.

10:圓形合金銲線 20:圓形合金銲線 22:表面鍍層 30:扁帶形合金銲線 40:扁帶形合金銲線 42:表面鍍層 10: Round alloy welding wire 20: round alloy welding wire 22: Surface coating 30: flat strip alloy welding wire 40: flat strip alloy welding wire 42: Surface coating

以下將配合所附圖示詳述本揭露之各面向。應注意的是,依據在業界的標準做法,各種特徵並未按照比例繪製且僅用以說明例示。事實上,可能任意地放大或縮小元件的尺寸,以清楚地表現出本揭露的特徵。 第1圖係根據一些實施例,繪示出圓形合金銲線的一部分線段。 第2A圖係根據一些實施例,繪示出被覆表面鍍層的圓形合金銲線的一部分線段。 第2B圖係根據一些實施例,繪示出沿著平行於第2A圖所示被覆表面鍍層的圓形合金銲線的長度方向之縱切面圖。 第3圖係根據一些實施例,繪示出扁帶形合金銲線的一部分線段。 第4A圖係根據一些實施例,繪示出被覆表面鍍層的扁帶形合金銲線的一部分線段。 第4B圖係根據一些實施例,繪示出沿著平行於第4A圖所示被覆表面鍍層的扁帶形合金銲線的長度方向之縱切面圖。 Various aspects of the present disclosure will be described in detail below with reference to the accompanying drawings. It should be noted that, in accordance with the standard practice in the industry, the various features are not drawn to scale and are used for illustrative purposes only. In fact, the dimensions of the elements may be arbitrarily expanded or reduced to clearly illustrate the features of the present disclosure. Figure 1 illustrates a portion of a circular alloy wire, according to some embodiments. FIG. 2A depicts a portion of a circular alloy bonding wire with a surface plating, according to some embodiments. FIG. 2B shows a longitudinal section along the length of a round alloy wire with a surface plating as shown in FIG. 2A , according to some embodiments. Figure 3 depicts a portion of a flat ribbon-shaped alloy wire, according to some embodiments. FIG. 4A depicts a portion of a flat ribbon-shaped alloy bonding wire with a surface plating, according to some embodiments. Figure 4B shows a longitudinal section along the length of the flat ribbon-shaped alloy wire with the surface plating shown in Figure 4A, according to some embodiments.

20:圓形合金銲線 22:表面鍍層 20: round alloy welding wire 22: Surface coating

Claims (7)

一種合金銲線,其基材為銀、銅或鋁中任一者,其包括0.001至2wt.%的Ge,及餘量的基材,其中基材為銅時更包括取自Pt、Ni、Si或Sc中至少一者的添加元素,該添加元素的總添加量為0.001至0.01wt.%;基材為鋁時更包括取自Pt、Pd、Au、Ni或Sc中至少一者的添加元素,該添加元素的總添加量為0.001至0.01wt.%;基材為銀時更包括取自Pd、Au或Sc中至少一者的添加元素,該添加元素的總添加量為0.001至0.01wt.%。 A kind of alloy welding wire, its base material is any one in silver, copper or aluminum, and it comprises the Ge of 0.001 to 2wt.%, and the balance base material, wherein when the base material is copper, it further includes Pt, Ni, Addition of at least one of Si or Sc, the total addition of the addition is 0.001 to 0.01wt.%; when the base material is aluminum, it also includes the addition of at least one of Pt, Pd, Au, Ni or Sc element, the total amount of the added element is 0.001 to 0.01wt.%; when the base material is silver, it further includes an added element from at least one of Pd, Au or Sc, and the total added amount of the added element is 0.001 to 0.01 wt.%. 如請求項1所述之合金銲線,其中該合金銲線為一圓形銲線。 The alloy welding wire according to claim 1, wherein the alloy welding wire is a round welding wire. 如請求項2所述之合金銲線,其中該合金銲線的直徑為10μm至300μm。 The alloy welding wire according to claim 2, wherein the alloy welding wire has a diameter of 10 μm to 300 μm. 如請求項1所述之合金銲線,其中該合金銲線為一扁帶形銲線。 The alloy welding wire according to claim 1, wherein the alloy welding wire is a flat strip-shaped welding wire. 如請求項4所述之合金銲線,其中該合金銲線的厚度為20μm至300μm。 The alloy welding wire according to claim 4, wherein the thickness of the alloy welding wire is 20 μm to 300 μm. 如請求項4所述之合金銲線,其中該合金銲線的寬度為100μm至2000μm。 The alloy welding wire according to claim 4, wherein the alloy welding wire has a width of 100 μm to 2000 μm. 如請求項1至6中任一項所述之合金銲線,更包括一表面鍍層,該表面鍍層含Au、Pd、Pt、其合金或其組合,且該表面鍍層的厚度為0.01至10μm。The alloy bonding wire according to any one of claims 1 to 6, further comprising a surface coating, the surface coating contains Au, Pd, Pt, alloys thereof or a combination thereof, and the thickness of the surface coating is 0.01 to 10 μm.
TW110127276A 2021-07-26 2021-07-26 Alloy bonding wire TWI796739B (en)

Priority Applications (1)

Application Number Priority Date Filing Date Title
TW110127276A TWI796739B (en) 2021-07-26 2021-07-26 Alloy bonding wire

Applications Claiming Priority (1)

Application Number Priority Date Filing Date Title
TW110127276A TWI796739B (en) 2021-07-26 2021-07-26 Alloy bonding wire

Publications (2)

Publication Number Publication Date
TW202304629A TW202304629A (en) 2023-02-01
TWI796739B true TWI796739B (en) 2023-03-21

Family

ID=86661313

Family Applications (1)

Application Number Title Priority Date Filing Date
TW110127276A TWI796739B (en) 2021-07-26 2021-07-26 Alloy bonding wire

Country Status (1)

Country Link
TW (1) TWI796739B (en)

Citations (10)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
CN101974709A (en) * 2010-09-21 2011-02-16 安徽欣意电缆有限公司 Super-soft aluminum alloy conductor and preparation method thereof
CN103008908A (en) * 2012-12-13 2013-04-03 浙江大学 Germanium-contained (Ge-contained) corrosion-resistant aluminum-based solder
TW201336599A (en) * 2012-03-12 2013-09-16 Wire technology co ltd Composite wire of silver-palladium alloy coated with metal thin film and method thereof
TW201440074A (en) * 2013-04-01 2014-10-16 Prec Packaging Materials Corp Silver alloy welding leads
TW201444005A (en) * 2013-05-14 2014-11-16 Tanaka Electronics Ind Bonding wire for high-speed signal
TW201639972A (en) * 2015-05-07 2016-11-16 Mk電子股份有限公司 Silver alloy bonding wire and method of manufacturing the same
CN107186374A (en) * 2016-07-21 2017-09-22 北京诺飞新能源科技有限责任公司 A kind of low-temperature high-strength aluminium welding wire and preparation method thereof
CN107962313A (en) * 2015-06-15 2018-04-27 日铁住金新材料股份有限公司 Bonding wire for semiconductor device
CN111151916A (en) * 2019-12-26 2020-05-15 浙江大学 Foil brazing filler metal for brazing sintered neodymium-iron-boron permanent magnet material and preparation method
US20200312808A1 (en) * 2016-06-20 2020-10-01 Nippon Micrometal Corporation Copper alloy bonding wire for semiconductor devices

Patent Citations (10)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
CN101974709A (en) * 2010-09-21 2011-02-16 安徽欣意电缆有限公司 Super-soft aluminum alloy conductor and preparation method thereof
TW201336599A (en) * 2012-03-12 2013-09-16 Wire technology co ltd Composite wire of silver-palladium alloy coated with metal thin film and method thereof
CN103008908A (en) * 2012-12-13 2013-04-03 浙江大学 Germanium-contained (Ge-contained) corrosion-resistant aluminum-based solder
TW201440074A (en) * 2013-04-01 2014-10-16 Prec Packaging Materials Corp Silver alloy welding leads
TW201444005A (en) * 2013-05-14 2014-11-16 Tanaka Electronics Ind Bonding wire for high-speed signal
TW201639972A (en) * 2015-05-07 2016-11-16 Mk電子股份有限公司 Silver alloy bonding wire and method of manufacturing the same
CN107962313A (en) * 2015-06-15 2018-04-27 日铁住金新材料股份有限公司 Bonding wire for semiconductor device
US20200312808A1 (en) * 2016-06-20 2020-10-01 Nippon Micrometal Corporation Copper alloy bonding wire for semiconductor devices
CN107186374A (en) * 2016-07-21 2017-09-22 北京诺飞新能源科技有限责任公司 A kind of low-temperature high-strength aluminium welding wire and preparation method thereof
CN111151916A (en) * 2019-12-26 2020-05-15 浙江大学 Foil brazing filler metal for brazing sintered neodymium-iron-boron permanent magnet material and preparation method

Also Published As

Publication number Publication date
TW202304629A (en) 2023-02-01

Similar Documents

Publication Publication Date Title
JP5285079B2 (en) Solder alloys and semiconductor devices
JP5728126B2 (en) Power semiconductor device, manufacturing method thereof, and bonding wire
TWI394849B (en) Ag-based alloy wire and method for manufacturing the same
Uno et al. Surface-enhanced copper bonding wire for LSI
TW201336599A (en) Composite wire of silver-palladium alloy coated with metal thin film and method thereof
CN107195609B (en) Bonding wire for semiconductor device
JP5343069B2 (en) Bonding wire bonding structure
TWI490996B (en) Bonding wire
JP5270467B2 (en) Cu bonding wire
TW201336598A (en) Composite wire of silver -gold- palladium alloy coated with metal thin film and method thereof
JP5671512B2 (en) Bonding wire
Tsai et al. Materials characteristics of Ag-alloy wires and their applications in advanced packages
TW202115799A (en) Wire joining structure, bonding wire used in same, and semiconductor device
JP2010245390A (en) Bonding wire
JP6869920B2 (en) Precious metal-coated silver wire for ball bonding and its manufacturing method, and semiconductor device using precious metal-coated silver wire for ball bonding and its manufacturing method
JP2012009542A (en) Lead flame for optical semiconductor device and method for manufacturing the same
TWI796739B (en) Alloy bonding wire
TWI778583B (en) Silver alloy wire
TWI559417B (en) Bonding wire for power module package and method of manufacturing the same
JP5767521B2 (en) Lead frame for optical semiconductor device and manufacturing method thereof
TWI396756B (en) Electronic package alloy wire and methods for manufacturing the same
TWI731234B (en) Noble metal-coated silver wire for ball bonding and manufacturing method thereof, and semiconductor device using precious metal-coated silver wire for ball bonding and manufacturing method thereof
TWI471899B (en) Silver-based biphasic electrothermal resistance wire and manufacturing method thereof
JP6020972B2 (en) Copper bonding wire
KR102579479B1 (en) Connecting Pin