The end stations

The transfer stage
 

The insertion of samples is done through the transfer stage. The sample is inserted in the load lock chamber (pressure 5e-6 mbar). The usual time for pumping is 15-20 minutes. The sample can then be inserted with a transfer arm in the garage chamber (base pressure 8e-10 mbar), where three sample holders can be placed. The samples from this stage can then be moved or to the preparation or directly to the experimental chambers with a second transfer arm.      Picture of the insertion stage

Layout of the insertion stage

  

The experimental chamber 

Specifications:
base pressure 1 x 10^-10mbar; 
sample manipulator with six degrees of freedom (X,Y,Z, Theta, Phi, Correction  of precession) click here for further details;
sample LN₂ cooling (220 K);
200 °C annealing;
availability of  a remainence magnetiser;
Available detectors are:
Luminescence channel;
Fluorescence detector; 
Light detectors for diffuse & specular reflectivity (Diodes IRD SXUV-100 and AXUV-100 and Channeltron SJUTS  model KBL15), covering a 2pi solid angle;
Electron analyser (MCP 16 channels, 66 mm radius, 1 deg acceptance, 2pi solid angle).
 

The experimental chamber

 

The preparation chamber
 

The preparation chamber is an UHV chamber (base pressure 1e-10 mbar) equipped with:
- a manipulator stage with 5 degrees of freedom (X,Y,Z,Theta,Phi). The manipulator stage allows to heat (up to 1000 K) and to cool down the sample (100 K).
The control of temperature can be done through an IRCON pyrometer (T>250°C) or through a thermocouple K that can be brought in touch with the sample;
- a leed VG;
- an ion gun VG;
- a mass spectrometer (model SRS RGA-200)
- two quartz microbalance thickness monitors (one on the chamber, one on the manipulator);
- Tricon evaporators or home made evaporators; click here to have further details for surface preparation;
- a Cylindrical mirror analyzer.
 

Picture of the preparation chamber
 

 

The ammeters 

The current measurements (for instance, reflectivity with diodes or total electron yield from the sample) require the use of Keithley model 6517A.   Setting the BIAS The ammeter has inside a VOLTAGE SOURCE, that can be used to bias (positive or negative) the samples respect to GROUND according to the Diagram 2 (negative bias). The Bias to the sample is given by the  'Bias with respect to GND' control. When the 'Bias with respect to GND' control is different from 0, the VOLTAGE SOURCE is ON, when the BIAS is 0 V the VOLTAGE SOURCE is off. When  the VOLTAGE SOURCE is ON (see the picture BELOW and diagram 2), the LOW of the VSOURCE is internally shortcircuited to the LOW of the ammeter, and the HIGH of the VSOURCE (RED PLUG) should be GROUNDED by connecting the RED PLUG to the GREEN PLUG of the BACK of the Keithley. In this way, the sample is BIASED to - the VSOURCE of the ammeter (for example, to bias the sample at 100 V, the Real Bias (V) control should be 100, corresponding to a Keithley Vsource=-100V). When the VOLTAGE SOURCE is OFF (Real Bias (V)=0),  see Figure UPPER PART and diagram 1. In this case, the sample is grounded (for XPS!!!!!) by connecting the LOW of the ammeter (BLACK PLUG) to GROUND (GREEN PLUG). In the case that the measurement is not ground referenced (for example, when measuring reflectivity with the photo current from a diode), this connection can be removed only in the case that a triaxial cable to the diode is used.       INTEGRATION AND WAITING TIME  The INTEGRATION TIME is the time in which the ammeter acquires data. It is given by the Number of Power Line Cycles NPLC (1 NPLC = 20 msec) times the number of readings N (N=1-100). The default value of integration time (basic mode)  is 0.4 sec (i.e. NPLC = 2, N = 10). The WAITING TIME is the time (to be set) in order the ammeter to stabilize. The default value of the waiting time is set to  0 msec. The time required to stabilize depends on the ammeter time constant according to the following table   range/gain       time constant 20 - 200 pA             1 s 2 - 200    nA           20 ms 2 - 200    uA             1 ms 2 - 20      mA         < 1 ms   During the waiting time, the ammeter measures but the data are not acquired. The following diagram shows the sequence of measurement: Set of scan parameter accomplished (for example, the monochromator energy);  Start of ammeter reading (but not sending data to PC) for a time interval equal to the waiting time;  Start of ammeter acquisition (data filed);  Stop of data acqisition.  //<--parameter set--> <--waiting time--> <-- integration time-->//<--parameter set--> < --waiting time--> <-- integration time--> //<--param..                                  >>>>>>>>>>>>>>>>>>>>>>time>>>>>>>>>>>>>>>>>>>>>>>>>>>>>time>>>>>>>>>>>>>>>>>>>

Scheme for current measurement: Diagram 1: No bias; Diagram 2: Bias to the sample

 

Photodiodes

The experimental chamber is equipped with 4 silicon diodes for light detection. All diodes are mounted on  a aluminum frame placed on the PhiA analyzer frame, at 160 mm from the chamber center. These detectors are all at 160 mm from the chamber center. 3 diodes are SXUV-100 model and one is AXUV-100G for absolute intensity measurements. Moreover, there is also an absolute diode AXUV-300 mounted on the monitor chamber for I0. The following table summarizes the main properties of the detectors:

Diodes properties

model	distance from center (mm)	mask size (mm2) V X H	Acceptance (H x V) deg2	Group/connection	Direct beam position
sxuv100	160 mm	8 x 8	7.6 x 7.6	A 2	ThetaA -50 PhiA 0
sxuv100	160 mm	8 x 0.5	7.6 x 0.5	B 1	ThetaA -119.6 PhiA +2
axuv100	160 mm	8 x 8	7.6 x 7.6	A 1	ThetaA -129.6 PhiA -2.5
sxuv100	160 mm	8 x 8	7.6 x 7.6	B 2	ThetaA -59.4 PhiA +2
axuv300	monitor chamber	20 x 20	------------	A 3	---------------------------

The diodes are connected through a DN63CF 8-ways feedthrough placed near the phiA motor.

 
Diodes mounted on PhiA frame


UHV feedthrough for photodiodes. 

The sample holders  

 

We have available 4 sample holders (XL25 VG standard) for different uses. The sample holders 1 and 4 allows to heat and cool down samples, differently sample horders 2 and 3.

Sample holder 1 (with Mo plate) Sample holder 2

Sample holder 3 Sample holder 4 (electron bombardment)

The specifications of the standard XL 25 sample are given below. For further details, click here.
Sample Size: 25.4mm Diameter (N.B. The block sample holder + sample has to pass through a copper gasket of inner diameter 40 mm).
 

Sample holder 1 (heater element)

Heating: Maximum Continuous Current: 1.2 Amps. Maximum Short Term Current: 5 Amps for up to 10 minutes from a cold start. If the element is pre-heated, this must be reduced accordingly. The heater element is pyrolytic graphite (PG) encapsulated in pyrolytic boron nitride (PBN). The heating resistance is about 15 ohms.

Heating datsheet (preparation chamber) Current (Amps) Temperature (°C) Power (W) 1.2 500 8 1.5 600 13 2.0 700 23 2.5 800 35 3.0 900 60 3.5 1000 100

Heating datasheet (experimental chamber) Current (Amps) Temperature (°C) 0.1 40 0.2 90 0.3 135 0.4 180 0.5 220 0.6 260 0.7 300 0.8 320 0.9 340 1.0 36 Cooling: Minimum Temperature -170°C (100K).Time to Minimum Temperature* (about 60 minutes).

 

Sample holder 4 (electron bombardment)

The sample holder 4 permits to heat samples by electron bombardment. The home made filament is made in 0.2 mm annealed Goodfellow thoriated tungsten.
With a filament current of 3.4 Amps, we reached a temperature of 800°C, sample grounded.

Picture of XL25 sample holder

Details of XL25

 

 The magnetiser
 

A remanence magnetiser system has been developed on a standard XL25 sample holder. The magnetiser is based on  a ferromagnet with a 7 mm large air gap.
The magnetic field is applied through a kapton insulated wire. This device gives a magnetic field of about 130 Oe/Amp, with a maximum of about 600 Oe.   

 

A picture of the magnetiser

 

Magnetic field as a function of the applied current 

The fluorescence detector 

A new large area Vacuum Silicon Drift Spectrometer by PN Detector GmbH has been installed on the spectroscopy chamber of the beam line. This detector has been conceived for light element detection from Mg down to C and B. From preliminary tests, we obtained an excellent energy resolution down to 133 eV @ Mn-K alfa and a low level noise <150 eV.  The main characteristics are:
Distance from sample ≥ 20mm
Solid angle ≤ 0.075 sterad
Energy range  200  - 8000 eV
Sensor cooled by a Peltier cell(T~-15°C)
Built in electronics (integrated JFET)
Input PN integrated window (optimized detection of low energy photons)
On-chip Zr collimator
MCA with 8192 channels, calibrated with 55Fe K line (6 keV), Ga Lα line (1098 eV), As Lα line (1282 eV).
In the figure below is shown a design of the detector and of its support that allows to regulate the distance to the sample. 

 

The Fluoresecence detector

 

Typical setup for fluorescence measurements

The luminescence apparatus 

The experimental chamber is also equipped with a luminescence apparatus. Important applications of this apparatus are the development of scintillating detectors, biomedical markers, Organic Light Emitting Diode (OLED), Light intensifier devices (ex: YAG), and the characterization of wavelength shifters. Important perspectives are the study of the lifetime of excited energy states and transition probabilities, the study of relaxation times and the dynamics of exciting processes (pumping-probe measurements), the opening in the direction of exploitation of fast sources (FEL).
The luminescence apparatus is based on: 
- a quartz UV/VIS fiber optic of diameter 1 mm that can be brought close to the sample;
- the luminescence light is recorded  or without monochromatization (photodiode, PMT) or with monochromatization (spectrometer Ocean Optics HR4000 (λ= 191 – 1100 nm) or monochromator (Acton Sp-300i + CCD camera cooled with Liquid Nitrogen    λ= 400 – 1100 nm).  
It's also possible to perform time resolved measurements with a TAC (Time to Analog Converter).

Luminescence apparatus layout


UV-VIS fiber optics transmission
 

An example of luminescence measurement is shown here:  the fiber optics collects the monochromatic radiation coming from sample in the experimental chamber (left figure),  the radiation is taken outside the apparatus through the UHV connector (central figure), the final output is based on a CCD equipped Andor monochromator for analysis (right figure). (Courtesy of Prof. Belski, Université Lyon1) .

The electron analyzer

The electron analyzer is an hemispherical spectrometer characterized by a mean radius of 66 mm.  The collecting system is based on three lenses V1, V2 and V3, while the detection system is based on a 16 channel Multi Channel Plate. The independent electrodes of the analyzer, the two spheres of the hemispherical part and  are polarized by programmable power supply following calibration curves previously obtained by electron trajectories simulation, to set for each point in the analyzed energy range, the optimal working conditions. This scheme ensures a very high flexibility of the apparatus being possible to weakly change the lens characteristic by software. The curves are dependent on the retarding factor R=Ek/Ep.

Transmission

The transmission of the analyzer as a function of the kinetic energy is shown in Fig. 2. The transmission has been determined by measuring the intensity of Au 4f xps spectra, after the data have been normalized taking into the photoemission cross section. Measurement have been done with pass energy 5 eV. The data have then been normalized to the incoming intensity by measuring the flux with a silicon detector diode and taking into account its responsivity. The transmission is well fitted with a 7th degree polynomial curve
T(Ek)= p1·Ek^7+p2·Ek^6+p3·Ek^5  p4·Ek^4+p5·Ek^3+p6·Ek^2+p7·Ek^1+p8 with
p1=-7.9564e-008;p2=0.00022951;p3=-0.26007;p4=142.36; p5=-34583;  p6= 5.4847e+005;  p7=1.0074e+009; p8=-2.2156e+010.

 
 

Instrumental broadening-energy resolution

The spectrometer resolution has been experimentally determined by measuring the broadening of Au 4f 7/2 and 5/2 XPS spectra of a polycrystalline gold sample cleaned with one hour cycle of  ion sputtering. The instrumental broadening has been calculated with a fitting procedure by using the reference ‘P.H. Citrin, “Surface-atom x-ray photoemission from clean metals: Cu, Ag, and Au”, PRB 27-6 (1983)’. The core level spectra have been fitted as the sum of 4 Voigt functions, after a linear subtraction of the background. The 2+2 components are given by the contribution of bulk and surface components, whose intensity ratio is given by the takeoff angle. Measurements have been done in normal emission. The instrumental broadening is given by the width of the Gaussian component of the 4 Voigt functions. The broadening is given by the contribution of the exciting radiation (then from resolution that is given by photon energy and vertical slit aperture) and of the spectrometer (then from the pass energy).