Mass spectrometer studies of high vacuum materials

Mass spectrometer studies of high vacuum materials

VACUUM Classified V a c u u m II -- Vacuum Apparatus and Auxiliaries -- II Contd. occupying 1.4 ft. 8 of space. The box containing the tube w...

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VACUUM Classified V a c u u m

II --

Vacuum

Apparatus

and

Auxiliaries

--

II

Contd.

occupying 1.4 ft. 8 of space. The box containing the tube was pressure-tight in order to prevent an evacuation of the rocket i n s t r u m e n t section, pressurised at one atmosphere, in case the glass envelope of the t u b e should break. The t u b e was connected b y a b r a s s bellows to the outside of the rocket. The outlet was protected b y a rubber stopper during the take-off which was forced out by the pressure differential shortly afterwards. The operation of t h e i n s t r u m e n t was started b y a timer at 100 km. altitude: The resolution of the i n s t r u m e n t was about 1 in 25. Sommaire : L ' o n a adapt6 u n spectrom~tre de masse ~ fr6quence radiophonique du t y p e B e n n e t t ~ l'usage darts des fus6es, en liaison avec des recherches ~t h a u t e altitude au del~ de 150 kin.

Abstract No. and References

Article by J. W. TownsendJr.

Rev. 8ci. lnstrum. a3, Oct, 1952 538-541

Mass Spectrometer Studies of H i g h V a c u u m Materials See Abstract No. : 28/II

21/II

Brazing Vacuum-Tight Joints in H i g h Nickel Alloys See Abstract No. : 33/II

22/II

z6

--

MATERIALS

--

26

Glass Surfaces in a High V a c u u m Germany. In the p a s t the behaviour of glass surfaces exposed to a v a c u u m was mainly of interest to t h e valve and bulb m a n u f a c t u r e r the problem being the prevention of gas evolution from the glass surface. Recent developments in v a c u u m coating added to this t h e necessity of eliminating layers of foreign m a t t e r from t h e glass surface prior to deposition. The present article surveys relevant research work bearing on b e t h problems. Substances can be bound to t h e glass surface in three different ways: (1) By chemical binding, (2) b y absorption and (3) by adsorption. As' it is not always possible to make certain which of the three conditions apply it is the c u s t o m to speak generally of absorption. The absorption m e c h a n i s m h a s b e e n investigated theoretically by F a j a n s and W e y l who stipulated t h a t the chemical behaviour of a t o m s and ions present in the b o u n d a r y face is governed b y t h e structure of the electron shell surrounding the nucleus. In certain materials the forces within t h e a t o m remain stabilised although a few surplus electrons are removed from the outer shell during an ionisation proces~ Ions of this kind are O z-', F-, Na +, Mg 2+, A1 s+, Sit+, K +, Ca z+ and B 8+. In others the removal of electrons from the exterior orbits will cause effective polarisation of the charge of t h e ion. Ions of this class are Cd s+, Zn =+, Sn =*, and P b s+. A P h 2+ ion in the b o u n d a r y face for instance can be polarised b y the field of force in t h e glass. I t will t h e n act like a P b 4+ ion with respect to the body of the glass, b u t like a neutral lead a t o m with respect to the area surrounding the glass. A n Si4+ ion in the b o u n d a r y face on the other h a n d has two free valencies which cannot be s a t u r a t e d from within the glass as it does n o t react to t h e internal field force. T h e latter, therefore, will show a t e n d e n c y to absorption from without. This h a s been confirmed by experiment. A freshly broken glass surface will cover itse~lf rapidly with O H ions in places where Si ions are present. These layers are i n s t r u m e n t a l in forming a water skin b u t t h e OH ions can be replaced b y ions of the fluoride groups which promote the formation of hydrophobic films. L a n g m u i r investigated the evolution of gases and vapours from glass of the t y p e used in valves a n d bulbs and found t h a t essentially water vapour was liberated. Harris and Schumacher investigated six glasses giving a proper chemical analysis as shown in the table reproduced below.

23/II

Chemical Analysis of Glasses Examined by Harris and Schumacher 1 Si0, '

January 1953

69.93

2 69.40



3

4

64,64

5'

61.50

72.05

6 65.47

AltO,

1.54

0.78

0.20

0.57

2.21

2.99

Fe=O,

0.19

0.]4

0.04

0.11

0.05

0.51

PbO

1.44

Spurious Amounts

21.66

22,55

6.11

20.20

CaO

3.17

5.15

0.02

0.21

0.05

0.22

MgO

0.03

4.09

0.02

0.36

0.09

O.13

NatO

21.02

16.67

9.10

8.14

4.23

6.40

K=O

0.10

0.20

3.20

3.76

1.12

3.59

PrO,

0.08

0.16

0.75

0.34

Spurious Amounts

Spurious Amounts

Sb=O=

0.05

O.lO

--

Spurious Amounts

--

--

MnO=

0,09

0.19

0.19

0.01

0.073

.BtO,

2.36

3.12

2.27

.14.07

--

0.37

Vacuum Vol, I l I No I

84