RU1441991C - Method for part surface cleaning - Google Patents

Abstract

FIELD: microelectronic engineering. SUBSTANCE: discharge is initiated between liquid cathode (electrolyte) and hard anode (part being cleaned) at discharge carrent of 150 ≅ J ≅ 7000 mА mA, electrode-to-electrode distance 1= 1.0-1.5 mm, and disvharge voltage 5000 ≥ U ≥ 100 V V. EFFECT: improved quality and effectiveness of semiconductor surface cleaning. 1 dwg

Description

 The invention relates to the field of microelectronic technology and can be used to clean the surface of metal and semiconductor products.

 The aim of the invention is to improve the quality of cleaning, simplifying the method and ensuring the cleaning of semiconductor products.

 The drawing shows a device for implementing the method.

 The device comprises an anode — a workpiece 1 and an electrolytic cell 2 (cathode). The interelectrode distance between them is l = 1.0-1.5 mm. The electrolytic cell 2 (cathode) is filled with electrolyte 3. At the bottom of the cell 2 is a metal plate 4. A high-voltage power supply is connected directly to the electrodes.

 The method is as follows.

 The discharge is ignited between the anode 1 and the cathode 2. The current value is set from 150 to 7000 mA. Cleaning is carried out at atmospheric pressure for 60-240 s. The cleaning rate depends on the magnitude of the discharge current and the composition of the electrolyte. A prerequisite for cleaning is to maintain a gap between the anode and cathode l = 1.0-1.5 mm. In the case of a high voltage discharge, the electrolyte must adhere. In the case of a low-voltage discharge, the discharge burns without adherence of the electrolyte at a distance l = 1.0-1.5 mm and the sample surface is cleaned.

 From the analysis of the results obtained, it follows that the quality of cleaning is improved. The semiconductor surface is cleaned without the use of complex and inefficient equipment. In the case of a high voltage discharge, the cleaning process occurs as follows. At the anode, after electrolyte adherence, the discharge burns non-stationary. When gas bubbles form, the discharge burns, and when the bubbles disappear, the discharge goes out. Under the influence of these processes, the surface of the product is cleaned to a structural level. All this happens in a complex vapor-gas medium.

 At l≅1 mm, the sample cleaning process slows down and worsens; at l≥1.5 mm, the anode surface burns out in the case of a high-voltage discharge.

Claims (1)

 METHOD FOR CLEANING THE PRODUCT SURFACE, which consists in igniting a discharge between the workpiece and liquid electrolyte, characterized in that, in order to increase the cleaning efficiency and ensure cleaning of the surface of the semiconductors, a positive potential is applied to the workpiece, the gap l between the electrodes is 1.0-1, 5 mm and they support a discharge current of 0.15 ≅ I ≅ A at a discharge voltage of 500 ≥ U ≥ 1070 V, respectively.

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