KR20040070632A - An analyzer of an ion implanting apparatus - Google Patents

Abstract

PURPOSE: An analyzer of an ion implantation system is provided to reduce generation of silica and remove oxygen from a sensor by blocking the air in a leakage state of a process chamber. CONSTITUTION: A plurality of opening parts(23) are formed at both sides of a chamber(21). The chamber is surrounded by an insulating material. A thermometer(25) is installed into one side of the chamber. A sensor(26) is installed into the other side of the chamber in order to measure the amount of residual oxygen. A current detector(27) is installed at the sensor. A gas tube(28) is installed at a rear end of the sensor in order to receive a process gas. An exhaust tube(29) is used for exhausting the gas of the gas tube. A heater(30) is installed within the insulation of the chamber. A cooling line(40) is installed along the inside of the chamber. A first supply line(50) is installed at one side of the gas tube. A second supply line(60) is branched from the first supply line in order to receive the cooling gas.

Description

ANALYZER OF AN ION IMPLANTING APPARATUS

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an analyzer of an ion implantation apparatus in a semiconductor process, and more particularly to an analyzer of an ion implantation apparatus which prevents the formation of silica that prevents the diffusion of ions into a sensor inside the analyzer.

The ion implantation performed during the wafer processing step allows atomic ions to penetrate the surface of the wafer with high energy applied thereto. In general, implantation of impurities into silicon is performed by the ion implantation method.

Ion implantation is easy to control unit dosage, ease of ion distribution control, low temperature process, excellent process uniformity and reproducibility, easy source of impurities, high purity impurity implantation, transverse diffusion suppression, diversity of masking materials and accurate prediction of implant distribution It has many of the same advantages.

In this ion implantation, the unit implantation of ions is measured by the number of ions or charges per unit area implanted through the wafer surface.In an ion implantation facility, integrating all the current flowing through the wafer accurately measures the total amount of charge injected. Can

The ion implantation apparatus used in the prior art is a vacuum apparatus for creating a vacuum atmosphere, and electrons are removed from the neutral atoms to form positively charged particles, which are extracted from the ion supply unit with a strong electric field to form an ion beam required for ion implantation. An ion supply device, an ion analyzer that selects only the desired ion beam by appropriately adjusting the intensity of the magnetic field formed by the magnet, an accelerator that charges and accelerates the ion beam, and emits an electrostatic lens or magnetic field lens. A focusing device for focusing an ion beam, a neutral beam trap for offsetting a target from an ion beam to remove neutrons mixed in the ion beam, and a scanner for evenly spreading the ion beam on the wafer.

In the ion implantation apparatus of the above-described configuration, the ion analyzer is selected while passing through the analyzer in a state where a large number of ions generated in the ion source have a constant extraction energy of 0 to 50 KeV.

1 is a schematic configuration diagram of an analyzer of a conventional ion implantation apparatus, and an analyzer 1 for measuring the amount of oxygen remaining inside a process chamber (not shown) is installed. The analyzer 1 is equipped with a chamber 2, a heater 6 inside the chamber 2, and wrapped with a heat insulating material 5 to the outside. And the thermometer 7 is inserted through one opening 3 of the chamber 2, the other side is provided with a sensor 8 for measuring the amount of oxygen remaining in the process chamber. The sensor 8 is inserted into the opening 4, and a current detector 9 for checking the potential difference is provided on the sensor 8. In addition, a gas tube 10 through which the process gas flows into the rear end of the sensor 9 is installed, and a discharge pipe 11 through which the gas introduced through the gas tube 10 flows inside the sensor 8 and exits is installed. .

The sensor 8 has a silicon tube 8a which is open at both sides and is introduced into the gas tube 10, and the outside spaced apart from the silicon tube 8a is coated with zirconia and isolated from the inside of the chamber 2. It is.

The oxygen of the atmosphere is introduced through the opening 3 and exits through the opening 4.

The sensor 8 basically measures and detects a current generated by the movement of ions due to the difference in concentration between the chamber 2 side and the sensor 8 both ends.

However, when the zirconia coated on the outside of the sensor reacts with oxygen at high temperature, silica forms in the silicon tube, which prevents the diffusion of ions during normal operation. Therefore, when the oxygen concentration is not high inside the sensor, the oxygen contamination is not easy. However, when the process chamber is maintained or the process chamber is open for a long time, the concentration inside the analyzer becomes high and the contamination is easily contaminated. There was a problem of shortening or abnormally reading the amount of oxygen.

The present invention has been made to solve the above-described drawbacks, by reducing the formation of silica by blocking the air flow inside the sensor when the process chamber leaks or maintenance, and dropping the temperature of the heater and sensor rapidly It is an object of the present invention to provide an analyzer of an ion implantation apparatus capable of completely removing oxygen inside a sensor.

The present invention for achieving the above object, the opening is formed on both sides and the outer side is wrapped in a heat insulating material, the thermometer is inserted through the opening of the chamber, and inserted through the other opening is installed inside the process chamber A sensor for measuring the amount of oxygen remaining in the sensor; In the analyzer of the ion implantation apparatus comprising a discharge pipe exiting after flowing; A heater is installed inside the insulation of the chamber; A cooling line circulating along the inner surface of the chamber is installed; A first supply line through which a cooling gas flows is connected to one side of the gas tube; Provided is an analyzer of the ion implantation device, characterized in that the second supply line is branched on the first supply line for introducing the cooling gas into the chamber.

The above objects and various advantages of the present invention will become more apparent from the preferred embodiments of the invention described below with reference to the accompanying drawings by those skilled in the art.

1 is a schematic configuration diagram of an analyzer of a conventional ion implantation apparatus,

2 is a block diagram of an analyzer of an ion implantation apparatus according to the present invention.

<Description of the symbols for the main parts of the drawings>

20 analyzer 21 chamber

22, 23: opening 24: heat insulating material

25: thermometer 26: sensor

27 current detector 28 gas tube

29: discharge pipe 30: heater

40: cooling line 41: supply port

43 outlet 42, 44 first and second valve

50, 60: 1st, 2nd supply line 51.61: 3rd, 4th valve

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings.

2 is a block diagram of an analyzer of an ion implantation apparatus according to the present invention.

As shown in FIG. 2, the analyzer 20 includes a rectangular chamber 21 into which atmospheric air flows in and out through the openings 22 and 23 on both sides, and is inserted and installed through the openings 22. A sensor 25 for measuring the amount of oxygen remaining inside the process chamber by being inserted through the thermometer 25 and the opening 23 on the other side, and a current provided on the sensor 26 to detect current. A detector 27, a gas tube 28 installed at the rear end of the sensor 26 and a process gas flows therein, and a discharge pipe 29 which flows out after the gas introduced through the gas tube 28 flows inside the sensor. It is largely composed of

Here, the heater 30 receiving power from the outside is installed in the heat insulating material 24 surrounding the outside of the chamber 21, and the cooling line 40 is installed along the inner surface of the chamber 21.

The cooling line 40 has a supply port 41 introduced from the outside and a discharge port 43 circulated inside the chamber 21 and discharged to the outside. And on the supply port 41 and the discharge port 43, the 1st, 2nd valve 42 and 44 which control these are provided.

In addition, a first supply line 50 through which the cooling gas flows is connected to one side of the gas tube 28.

A second supply line 60 branched to one side on the first supply line 50 and introducing a cooling gas into the chamber 21 is installed.

Third and fourth valves 51 and 61 are installed on the first and second supply lines 50 and 60 to control the inflow of the cooling gas.

As the cooling gas, nitrogen gas is preferably used.

Referring to the operation of the analyzer of the ion implantation apparatus according to the present invention configured as described above are as follows.

When the oxygen flows in a certain amount or more during the process or maintains the process chamber, the gas tube 28 is blocked to block the process chamber.

Subsequently, the first valve 42 of the supply port 41 and the second valve 44 of the discharge port 43 are opened to circulate the cooling water. As a result, the temperature of the heater 30 in which the power is off is sharply lowered.

The third valve 51 of the first supply line 50 is opened to supply cooling gas to the sensor 26 through the gas tube 28, and the fourth valve 61 of the second supply line 60 is opened. Open to supply the cooling gas into the chamber (21).

Therefore, the sensor 26 removes oxygen through the discharge pipe 29 by the cooling gas and lowers the temperature of the sensor 26.

As such, the formation of silica in the silicon tube 26a of the sensor 26 in which the temperature drops sharply by using the cooling line and the cooling gas is reduced.

In the above description, it should be understood that those skilled in the present invention can only make modifications and changes to the present invention without changing the gist of the present invention as merely illustrative of a preferred embodiment of the present invention.

As described above, the analyzer of the ion implantation apparatus according to the present invention prevents the formation of silica by blocking the air flowing into the sensor when the process chamber is leaked or maintained, and rapidly decreasing the temperature of the heater and the sensor. By reducing and completely removing the oxygen inside the sensor, there is an effect to prevent the sensor malfunction or contamination.

Claims (2)

A chamber having openings formed at both sides and having an outer side wrapped with a heat insulating material, a thermometer inserted through the opening of the chamber, a sensor inserted through the other opening, and measuring the amount of oxygen remaining in the process chamber; And an electric current detector on the sensor, a gas tube installed at a rear end of the sensor, into which a process gas is introduced, and a discharge tube through which the gas introduced through the gas tube flows out of the sensor and exits. In an analyzer; A heater is installed inside the insulation of the chamber; A cooling line circulating along the inner surface of the chamber is installed; A first supply line through which a cooling gas flows is connected to one side of the gas tube; And a second supply line branched on the first supply line and introducing a cooling gas into the chamber. The method of claim 1, The cooling gas analyzer of the ion implantation device, characterized in that nitrogen gas is used