DE202005020746U1 - Glow discharge source for analysis of solid sample by means of glow discharge has anode and cathode and by means of direct and indirect cooling of sample and cooling agent provide at least one peltier-element - Google Patents

Abstract

The glow discharge source (10) has anode (11) and cathode (12) and by means of direct and indirect cooling of a sample (16) and cooling agent provide at least one peltier-element (27). The peltier-element is arranged between node and cathode and in each case one of the two parts cooled and other part warmed up.

Description

The The invention relates to a glow discharge source, in particular for analysis of solid samples by means of glow discharge, with anode and cathode and with Means for direct or indirect cooling of a sample.

Known Glow discharge sources are among others as ion sources for mass spectrometry Analyzes. In the glow discharge source, the surface of a Sample removed by a plasma and ionized. The from the sample originating ions are derived from the source and fed to a mass spectrometer.

The solid sample is heated by the plasma. A cooling the sample is advantageous to avoid melting. this concerns especially thin Samples or layer systems. Also is a constant sample temperature for the Accuracy and reproducibility of the measurement results advantageous. Finally, should the stability the removal of the sample surface (sputter process) guaranteed be.

In known devices is carried out the cooling of the sample by means of Water. There are no additives only temperatures near freezing reachable. For samples with low melting point this may not be sufficient e.g. for gallium (Ga). Also, with this type of cooling, the temperature change rate low. After all It is beneficial to heat the sample after cooling to avoid condensation to heat up. This requires additional technical measures.

With The present invention seeks to cool the sample in the range the glow discharge source can be improved.

The glow discharge source according to the invention is characterized in that as coolant at least one Peltier element is provided. When applying a voltage to the Peltier element one side is cooled, while the opposite side of the element is heated becomes. The heat is therefore transported from one side to the opposite side. When the voltage on the Peltier element is reversed, it changes according to the direction of the heat flow.

With The Peltier element allows rapid temperature changes and is relatively low Temperatures, even below 0 ° C achievable. For heating the Sample to avoid condensation just needs the voltage be reversed.

To Another idea of the invention is the Peltier element between Anode and cathode of the glow discharge source arranged. It will one of the two parts cooled and the other part is heated. The Peltier element is preferably designed as an insulator, such as with ceramic surfaces, allowing a good electrical and thermal insulation between Anode and cathode is present.

To Another idea of the invention is that the Peltier element abuts the cathode and this cools, and the cathode at the Sample is present. The Peltier element absorbs the heat of the cathode and the latter the heat the sample up to a controllable by the Peltier element equilibrium state. By reversing the voltage at the Peltier element is also on simple way of warming the sample possible.

To Another idea of the invention is means for cooling the Anode provided. By the Peltier element, the heat energy of the Transfer cathode to the anode. This can be cooled accordingly be and this preferably has channels for flow of a flowing cooling medium on. Preference is given to cooling water or another coolant. Possible is also a gas cooling. The anode is advantageously at ground potential, so that a streaming coolant in this area is unproblematic.

According to one independent of the use of the Peltier element independent idea of the invention the cathode of the glow discharge source consists of a special one Material, namely a tungsten-copper alloy (WCu) or another alloy with similar ones Properties such as copper-chromium (CuCr), tungsten-silver (WAg), tungsten-carbon-silver (WCAg), Preferred is a tungsten-copper alloy with a proportion from 60-90% Tungsten, in particular W75Cu25. The material described has a big Hardness at at the same time good thermal and electrical conductivity on. The usual used stainless steel has significantly worse in this regard Properties on. Also important is the mechanical hardness, because the Sample is applied to the cathode and insufficient hardness of the Cathode whose surface scratch and so the electrical and thermal transition between sample and cathode and thus also the subsequent measurement results can influence.

According to another idea of the invention independent of the use of the Peltier element and the particular cathode material, a cover of the cathode is provided such that the sample is completely covered and the cover has a peripheral sealing edge opposite the cathode, with a volume between cover and sample is sucked and the Abde For this purpose, a connection for suction has. Within the glow discharge source there is a vacuum or pressure of about 1mb (0.1 to 10mb). So far, a pressure-tight arrangement of the sample at the cathode is customary, for example with an intermediate (very flat) sealing ring. This complicates the electrical and thermal transition between cathode and sample. With the inventive solution of the cover described eliminates the seal between the sample and the cathode.

To In another aspect of the invention, the cathode is split, being a near-sample part along with the sample and the cover from a remote portion of the cathode is removable. This measure allows a special easy sample change. A new sample can be placed outside the glow discharge source fixed to the near-sample part of the cathode and then subsequently with this together put on the progenferne part of the cathode become. Accordingly, between the two parts of the cathode provided a vacuum seal.

Further Features of the invention are the description of the remainder and the claims to remove. Hereinafter, advantageous embodiments will be described with reference to FIG Drawings closer explained. Show it:

1 a section along a central axis of a first embodiment of the glow discharge according to the invention,

2 an execution similar 1 but with a cover over the sample,

3 an execution similar 2 but with a cover and a shared cathode,

4 a section along the line AB in the 1 - 3 .

5 a perspective view of the glow discharge source.

The figures show a glow discharge source 10 in the manner of a Grimm source. anode 11 and cathode 12 are substantially annular in shape with a common central axis 13 ,

Between anode 11 and cathode 12 is a gap 14 provided, which is partially filled by a substantially disc-shaped insulator 15 , The gap 14 runs perpendicular to the central axis 13 ,

The gap 14 opposite is at the anode 12 a sample 15 held by means not shown in detail. Between the sample 16 and the anode 12 should be ensured a good electrical and thermal transition.

Along the central axis 13 extends a free volume 17 with a glow discharge zone eighteen near the sample 16 , The cathode 12 has a much larger inner diameter than the anode 11 , In addition, a sleeve-like extension extends 19 the anode 11 into the cathode 12 in and towards the sample 16 ,

Between the sleeve-like extension 19 and the outer cathode for this purpose 12 is a ring volume 20 formed, which with the glow discharge zone eighteen over a radially directed volume 21 communicates. Here is the radial volume 21 in the axial direction on the one hand by the sample 16 and on the other hand by the extension 19 limited. The latter points in his the sample 16 facing area an outward thickening 22 on, leaving the ring volume 20 is divided into a wide section 23 near the gap 14 and a narrow section 24 at the height of the thickening 22 ,

A substantially sleeve-shaped insulator 25 is provided on a circumferential inner side 26 the cathode 12 , In this case, the insulator 25 extends from the insulator 15 to the sample 16 , so no "line of sight" between parts of the anode 11 and the cathode 12 consists.

In the area of the insulator 15 are between anode 11 and cathode 12 in the circumferential direction several, namely here six Peltier elements 27 arranged, see also 4 , These are on the top and bottom of the anode 11 and the cathode 12 so that a good heat transfer is guaranteed. At the same time are the Peltier elements 27 Made of ceramic material to ensure electrical insulation. Preferably, each 30 watts Peltier elements, the total power of 180 watts should be> = the power of the glow discharge. Such Peltier elements are for example the high-temperature elements PF-127-10-13 (silicone-sealed) to the telemeter Elektronik GmbH with I _max 3.9 amps, 16.4 volts U _max, P _cmax 35.6 watts, delta T: 72 ° Celsius. The dimensions of the around the Peltier elements 27 arranged around parts are such that the Peltier elements 27 without gap at anode 11 and cathode 12 abutment and good heat transfer are present.

The Peltier elements 27 are connected in a manner not shown to an electrical voltage source and directly cool the cathode 12 and thus indirectly the sample 16 , At the same time immediately becomes the anode 11 heated. A voltage reversal at the Peltier elements 27 is possible. This allows the sample 16 for example, by be heated to prevent a condensation precipitation after the vacuum in the region of the sample.

The anode 11 is equipped with cooling facilities. In the present example, the anode 11 cooling channels 28 on, which extend in particular in the circumferential direction, record a flowing cooling medium and can be connected in a manner not shown in detail to an external cooling unit.

Into the glow discharge source 10 flows as process gas argon, here by at least one radially directed channel 29 that in the free volume 17 flows and settles in the anode 11 between the (in a radial plane) cooling channels 28 and the Peltier elements 27 extends.

Accordingly, the cathode has 12 at least one radially directed drainage channel 30 on which of the ring volume 20 or the wide section 23 the same is connected and this the insulator 25 breaks through.

The process gas ionizes in the glow discharge zone eighteen , Ions beating out of the surface of the sample 16 ionized particles coming out of the sample 16 away, in the direction of the arrow 31 along the free volume 17 a mass spectrometer, not shown, are supplied.

The cathode 12 is made of a particularly hard and at the same time electrically and thermally conductive material, preferably of a tungsten-copper alloy with a tungsten content of 75% and corresponding to a copper content of 25%.

In operation, there is a glow discharge zone eighteen a pressure of about 0.1 to 10 mb. By providing cooling samples can be analyzed with temperatures well below 0 ° Celsius, for example, up to 70 Kelvin below the temperature of the anode, which is cooled by cooling water.

Via a control circuit, not shown, the temperature of the Peltier element or the sample can be kept constant. Important in this context is a tuning of the performance of the Peltier elements to that in the glow discharge source 10 resulting heat output.

The arrangement of the Peltier elements can also be provided elsewhere, such as directly for cooling the sample. Also not mandatory is a dissipation of heat to the anode 11 ,

In the present case, the anode is located 11 at ground potential, while cathode 12 and sample 16 are under tension.

Another embodiment shows 2 , Here is the sample 16 from a cover, namely a housing 32 covered, which is formed lid-shaped with a peripheral peripheral seal 33 , The latter is far from the sample 16 at the cathode 12 at. The housing 32 points approximately in the middle and the sample 16 opposite a connecting piece 34 for a vacuum line. An interior 35 of the housing 32 is largely evacuated, preferably with a residual pressure which is approximately the pressure in the glow discharge source 10 corresponds or may be slightly higher. Holding devices for the sample are available but not shown.

The special advantage of the housing 32 lies in that the sample 16 opposite the cathode 12 does not have to be vacuum-tight. Special sealant between the cathode 12 and the sample 16 can be avoided.

Another embodiment finally shows 3 , Here is also the case 32 intended. Opposite the in 2 However, the embodiment shown is the cathode 12 formed in two parts with a sample near the part 36 (removable part) and a sample remote part 37 (fixed part) of the cathode. The sample part 36 is preferably formed with a smaller outer diameter than the probenferne part 37 , The housing 32 extends here over the sample-near part except for the off-sample part 37 , The circumferential seal 33 especially seals against the part away from the sample 37 but also opposite the sample part 36 , and is in the angle between the parts 32 . 36 . 37 arranged.

To remove the sample 16 is the case 32 with rehearsal part 36 and sample 16 from the glow discharge source 10 otherwise removable. Subsequently, an already prepared new housing can be used with another sample. The sequence of several measurements can be significantly accelerated. The insulator 26 is preferably with one of the two parts 36 . 37 firmly connected. The channel 30 runs in the part 37 , In the free volume 17 can be a guide tube 38 be used, as well as in the other embodiments of the glow discharge source 10 ,

5 shows a simplified perspective view of the glow discharge source 10 with analyzer. Of the latter, here is only one housing wall 39 indicated.

10

glow discharge

11

anode

12

cathode

13

central axis

14

gap

15

insulator

16

sample

17

free volume

18

glow discharge

19

extension

20

ring volume

21

radial volume

22

thickening

23

wider section

24

narrow section

25

insulator

26

inside

27

Peltier elements

28

cooling channels

29

channel

30

Effluent channel

31

arrow

32

casing

33

poetry

34

spigot

35

inner space

36

rehearse the near part

37

rehearse the near part

38

guide tube

39

housing

Claims (11)

Glow-discharge source, in particular for the analysis of solid samples by means of glow discharge, with anode ( 11 ) and cathode ( 12 ), characterized in that the cathode ( 12 ) is made of a tungsten-copper alloy (WCu) or other alloy having similar properties, preferably copper-chromium (CuCr), tungsten-silver (WAg), tungsten-carbon-silver (WCAg). Glow discharge source according to claim 1, characterized in that the cathode ( 12 ) is made of a material that is similar or equivalent in hardness, electrical and thermal conductivity of a tungsten-copper alloy (WCu). Glow discharge source according to claim 1 or 2, characterized characterized in that the cathode is made of a tungsten-copper alloy is prepared with a proportion of 60 to 90% tungsten, preferably from W75Cu25. Glow-discharge source, in particular for the analysis of solid samples by means of glow discharge, with anode ( 11 ) and cathode ( 12 ), characterized in that the cathode consists of at least one, in particular exactly one of the alloys CuCr, WAg, WCAg, WCu. Glow-discharge source according to at least one of the preceding claims, characterized by means for direct or indirect cooling of a sample, preferably with at least one Peltier element ( 27 ) as a coolant. Glow discharge source according to claim 5, characterized in that the Peltier element is arranged between the anode and the cathode and one of the two parts cools and the other part is heated. Glow discharge source according to claim 5 or 6, characterized characterized in that the Peltier element is applied to the cathode and this cools, and that the cathode abuts the sample. Glimmentladungsquelle according to claim 5 or a the further claims, characterized in that means for cooling the anode are provided. Glow discharge source according to claim 8, characterized in that the anode channels ( 28 ) to the flow of a flowing cooling medium. Glow discharge source according to at least one of the preceding claims, characterized by a cover of the cathode such that the sample ( 16 ) is completely covered and the cover has a peripheral sealing edge opposite the cathode, wherein a volume between the cover and sample can be sucked and the cover has a suction port for this purpose. Glow discharge source according to claim 10, characterized in that the cathode is formed divided, wherein a near-sample part ( 36 ) together with the sample and the cover from a remote part ( 37 ) the cathode is removable.