1. Study of vacuum stability at cryogenic temperature
WP4 - Activity at LNF
CERN 09/10/2017
Marco Angelucci
Roberto Cimino

2. Beam Screen Temperature
Working Pressure
(<10-11)
BS Temperature Range
LHC
SR Power = 0.13 W/m
FCC
SR Power = 40 W/m
CERN 10/09/17
Marco Angelucci

3. Study the behaviour of different surfaces (treated sample)
Temperature
Find right working temperature is a fundamental point for vacuum stability.
Work near a gas desorption temperature could generate great pressure oscillations.
Study of adsorption/desorption behaviour near critical temperature is mandatory to understand vacuum stability
Study the behaviour of different surfaces (treated sample)
CERN 10/09/17
Marco Angelucci

4. Vacuum Stability Interaction With Electrons Desorption
Interaction With Photons
Interaction With Electrons
Photoelectron Emission
Secondary Electron Emission
Heat Load
Electron Cloud
Interaction With Ions
Desorption
CERN 10/09/17
Marco Angelucci

5. Scanning Tunneling Microscopy
LNF-Lab Now
Two Different Ultra-High Vacuum Systems equipped with:
X-Ray/UV Photoemission
High Temperature Manipulator
Low Energy Electron Diffraction
Secondary Electron Yield Spectroscopy
Surface Preparation
Gas-Line
Low Temperature Manipulator (≈ 9 K)
New Mass Spectrometer
Raman Spectroscopy
Scanning Tunneling Microscopy
CERN 10/09/17
Marco Angelucci

6. LNF-Lab Now Two Different Ultra-High Vacuum Systems equipped with:
X-Ray/UV Photoemission
High Temperature Manipulator
Low Energy Electron Diffraction
Secondary Electron Yield Spectroscopy
Surface Preparation
Gas-Line
Low Temperature Manipulator (≈ 9 K)
New Mass Spectrometer
Raman Spectroscopy
Scanning Tunneling Microscopy
Synchrotron beamlines ( eV)
CERN 10/09/17
Marco Angelucci

7. Important Results
Follow Adsorption process checking the High- Energy SEY (HE-SEY)
Distinguish Single Layer (SL) from Thick Film (TF) formation by Low-Energy SEY (LE-SEY)
Quantify the number of adsorbed layers on surface
Measure the desorption temperature of TF and SL with SEY and TPD
Measure Work Function (WF) variation
CERN 10/09/17
Marco Angelucci

8. Important Tasks Distinguish electron-induced from thermal desorption
Study the contribution of reflected e- to Low- Energy SEY
Study the influence of the adsorbed gas in the Low- Energy SEY
CERN 10/09/17
Marco Angelucci

9. Important Tasks
Study the adsorption and desorption processes on Laser treated samples (preliminary results)
TPD measurements with new mass spectrometer (done)
Measure desorption with SEY and TPD at the same time (data acquisition system improved)
CERN 10/09/17
Marco Angelucci

10. LNF-Lab Activities SEY of Clean metals
SEY of clean Cu with low contaminants
Adsorption and Desorption processes from different surfaces (clean Cu, Laser Treated sample)
Interaction between electron and Argon
Contribution of reflected Electrons to the Low-Energy SEY (Graphite, Cu, Cu with Argon)
CERN 10/09/17
Marco Angelucci

11. LNF-Lab Activities SEY of Clean metals
SEY of clean Cu with low contaminants
Adsorption and Desorption processes from different surfaces (clean Cu, Laser Treated sample)
Interaction between electron and Argon
Contribution of reflected Electrons to the Low-Energy SEY (Graphite, Cu, Cu with Argon)
CERN 10/09/17
Marco Angelucci

12. Clean Metals High-Energy SEY dependence
Differences between “As Received” and Atomically Clean Metals
High-Energy SEY dependence
Contaminants (as received)
Materials (clean)
Lower SEY
Characteristic Curves
General High SEY
L. A. Gonzalez et al: "The secondary electron yield of noble metal surfaces.” In print to AIP Advances
CERN 10/09/17
Marco Angelucci

13. Clean Metals
Differences between “As Received” and Atomically Clean Metals
in the Low-Energy range
General Behaviour
in all clean metals
Evaluation of Work Function
L. A. Gonzalez et al: "The secondary electron yield of noble metal surfaces.” In print to AIP Advances
CERN 10/09/17
Marco Angelucci

14. LNF-Lab Activities SEY of Clean metals
SEY of clean Cu with low contaminants
Adsorption and Desorption processes from different surfaces (clean Cu, Laser Treated sample)
Interaction between electron and Argon
Contribution of reflected Electrons to the Low-Energy SEY (Graphite, Cu, Cu with Argon)
CERN 10/09/17
Marco Angelucci

15. Sub-Monolayer Contaminations
Surface Modification
Induced SEY variation by external contaminants
Sub-Monolayer Contaminations
High-Energy Range
Low Variations
(SEY Max from 1.4 to 1.3)
Variation Dependence on Gas contaminant (?)
Low-Energy Range
Strong Variations
from 0.05 to 0.25)
New characteristic structures
L. A. Gonzalez et al: "The secondary electron yield of noble metal surfaces.” In print to AIP Advances
CERN 10/09/17
Marco Angelucci

16. Sub-Monolayer Contaminations
Surface Modification
Induced SEY variation by external contaminants
Sub-Monolayer Contaminations
High-Energy Range
Low Variations
(SEY Max from 1.4 to 1.3)
Variation Dependence on Gas contaminant (?)
Low-Energy Range
Strong Variations
from 0.05 to 0.25)
New characteristic structures
L. A. Gonzalez et al: "The secondary electron yield of noble metal surfaces.” In print to AIP Advances
CERN 10/09/17
Marco Angelucci

17. LNF-Lab Activities SEY of Clean metals
SEY of clean Cu with low contaminants
Adsorption and Desorption processes from different surfaces (clean Cu, Laser Treated sample) with Argon
Interaction between electron and Argon
Contribution of reflected Electrons to the Low-Energy SEY (Graphite, Cu, Cu with Argon)
CERN 10/09/17
Marco Angelucci

18. Argon Adsorption (SEY)
Adsorption process of Argon on Cu sample at 10 K
General behaviour
Max dose
160 L
Max dose
160 L
Two different regions
with characteristic trends
High Energy
(>50 eV)
Low Energy
(<50 eV)
Thick Film (TF)
Single Layer (SL) Cu Cu
Δ = 4.1
From 1.4 (10 K) to 5.5 (160 L) eV)
CERN 10/09/17
Marco Angelucci

19. Argon Desorption (SEY)
Adsorption
Desorption TF SL
CERN 10/09/17
Marco Angelucci

20. Argon Desorption (TPD)
Temperature Programmed Desorption (TPD) P2
Characteristic desorption behaviour
First desorption process around 20 K (P1)
Second desorption 30 K (P2)
Other desorption after 50 K P1
CERN 10/09/17
Marco Angelucci

21. Argon Desorption (TPD)
Temperature Programmed Desorption (TPD) P2
Correlation between P1 and SEY signals P1 P1
CERN 10/09/17
Marco Angelucci

22. Argon Results (Cu) Adsorption Process (LT)
Formation of a Thick Film (TF) at high coverage (increasing of SEY)
Formation of a Single Layer (SL) on Cu at LT (characteristic peaks)
Desorption Process (Heating)
System returns to the original state with slight differences
Possibility to follow formation of SL from TF
Possibility to measure desorption temperature with SEY and TPD
Berlin 30/05/17
Marco Angelucci

23. LNF-Lab Activities SEY of Clean metals
SEY of clean Cu with low contaminants
Adsorption and Desorption processes from different surfaces (clean Cu, Laser Treated sample) with Argon
Interaction between electron and Argon
Contribution of reflected Electrons to the Low-Energy SEY (Graphite, Cu, Cu with Argon)
CERN 10/09/17
Marco Angelucci

24. Strong Variation of SEY due to the contamination
Laser Treated Sample
Laser treated sample
at 10 K
Strong Variation of SEY due to the contamination
CERN 10/09/17
Marco Angelucci

25. Laser Treated Sample Laser treated sample Heated up to 300 K
Desorption of contaminants
SEY returns to the initial value
CERN 10/09/17
Marco Angelucci

26. Laser Treated Sample Cooling Process Adsorption of contaminants
Modification of SEY
Additional contribution to Thermal Desorption
CERN 10/09/17
Marco Angelucci

27. Laser Treated Sample
Adsorption process of Argon (500 L) on Laser Treated sample at 10 K
No “significant” variation of SEY
Δ = 0.05
From 0.55 (10 K) to 0.6 (500 L) eV)
CERN 10/09/17
Marco Angelucci

28. Laser Treated Sample Temperature Programmed Desorption (TPD)
Desorption process from Laser Treated Sample with Argon (500 L) P2
General behaviour between 30 and 100 K
No visible peak at 20 K (P1)
Huge peak at 30 K (P2) P1
CERN 10/09/17
Marco Angelucci

29. Laser Treated Sample
Adsorption process of Argon (2000 L) on Laser Treated sample at 10 K
minor differences in the starting point
No “significant” variation of SEY
Δ = 0.1
From 0.4 (10 K) to 0.5 (2000 L) eV)
CERN 10/09/17
Marco Angelucci

30. Laser Treated Sample Temperature Programmed Desorption (TPD)
Desorption process from Laser Treated Sample with Argon (2000 L) P2
General behaviour between 30 and 100 K
Visible peak at 20 K (P1)
Huge peak at 30 K (P2) P1
CERN 10/09/17
Marco Angelucci

31. Temperature Programmed Desorption (TPD)
Laser Treated Sample
Temperature Programmed Desorption (TPD) P2 P2 P1 P1
CERN 10/09/17
Marco Angelucci

32. Temperature Programmed Desorption (TPD)
Laser Treated Sample
Temperature Programmed Desorption (TPD) Cu
Laser
Laser
160 L
500 L
2000 L
CERN 10/09/17
Marco Angelucci

33. Maximum pressure during desorption process
Laser Treated Sample
Maximum pressure during desorption process
P1 20 K)
(10-7 mbar)
P2 30 K)
Cu (160 L)
0.1
0.45
Laser Treated (500 L)
0.013 2
Laser Treated (2000 L)
0.18 7
CERN 10/09/17
Marco Angelucci

34. Argon Results (Laser Treated)
Adsorption Process (LT)
Strong Variation during cooling process (contaminants)
No significant SEY variation during Argon Adsorption (up to 2000 L)
Desorption Process (Heating)
System returns to the original state with slight differences
Differences with Cu in the range around 20 K
Berlin 30/05/17
Marco Angelucci

35. Important Tasks
Study the adsorption and desorption processes on “As Received” samples
Adsorption/Desorption processes with different gases
CERN 10/09/17
Marco Angelucci

36. LNF-Lab Activities SEY of Clean metals
SEY of clean Cu with low contaminants
Adsorption and Desorption processes from different surfaces (clean Cu, Laser Treated sample) with Carbon-Monoxide
Interaction between electron and Argon
Contribution of reflected Electrons to the Low-Energy SEY (Graphite, Cu, Cu with Argon)
CERN 10/09/17
Marco Angelucci

37. Adsorption process of Carbon Monoxide on Cu sample at 10K
CO Adsorption (SEY)
Adsorption process of Carbon Monoxide on Cu sample at 10K
General behaviour
Two different regions
High Energy
(>50 eV)
Low Energy
(<50 eV)
eV decreases during deposition from 1.4 to 1.1
Formation of CO Thick Film (TF)
Characteristic peak of TF at 65 eV
CERN 10/09/17
Marco Angelucci

38. Adsorption process of Argon on Cu sample at 10K
CO Adsorption (SEY)
Adsorption process of Argon on Cu sample at 10K
Low Energy behaviour
Two different regions
High Energy
(>50 eV)
Low Energy
(<50 eV)
Characteristic peaks at different low energies
Formation of Argon Single Layer (SL)
CERN 10/09/17
Marco Angelucci

39. CO Results (SEY) Adsorption Process (10 K)
Formation of a TF with Low SEY
Characteristic peaks for SL in the
Low Energy Region
CERN 10/09/17
Marco Angelucci

40. LNF-Lab Activities SEY of Clean metals
SEY of clean Cu with low contaminants
Adsorption and Desorption processes from different surfaces (clean Cu, Laser Treated sample)
Interaction between electron and Argon
Contribution of reflected Electrons to the Low-Energy SEY (Graphite, Cu, Cu with Argon)
CERN 10/09/17
Marco Angelucci

41. Argon Adsorption II (SEY)
We can summarize the results observed for
Ar adsorption on Cu sample at 10 K 10
CERN 10/09/17
Marco Angelucci

42. e--Argon Interaction (SEY)
Subsequent SEY scans on
the Ar-dosed Cu sample 10
CERN 10/09/17
Marco Angelucci

43. e--Argon (SEY) Continuous SEY scans
GAS ON: Adsorption
GAS OFF: e- Desorption
e- bombardment induced different behaviour
SEY at 930 decreases as a function of time
SEY at 10 eV remains constant
CERN 10/09/17
Marco Angelucci

44. e--Argon (SEY) SEY measured in different points
New Point presents different SEY spectra
with the same features of SEY with large amount of Ar
CERN 10/09/17
Marco Angelucci

45. e--Argon (SEY) II Electron Stimulated Desorption at different Energies
900 eV
400 eV
Strong Interaction (desorption) with HE electrons
CERN 10/09/17
Marco Angelucci

46. e--Argon (SEY) II Electron Stimulated Desorption at different Energies
10 eV
Low interaction (no desorption) with LE electrons
CERN 10/09/17
Marco Angelucci

47. e--Argon (SEY) Continuous SEY scans (mass spec. signal)
Study Electron Stimulated Desorption with Mass spectrometer
complete SEY scan
CERN 10/09/17
Marco Angelucci

48. e—Argon results (SEY) Beam-Layer Interaction
Argon Thick film interacts with primary electrons and desorbs
CERN 10/09/17
Marco Angelucci

49. Beam Interaction Thermal Desorption Non-Thermal Desorption
Electron beam dependence (size, energy …)
CERN 10/09/17
Marco Angelucci

50. Important Tasks
Study the adsorption and desorption processes on “As Received” samples
Adsorption/Desorption processes with different gases
Study the Electron Stimulated Desorption with different parameters
CERN 10/09/17
Marco Angelucci

51. LNF-Lab Activities SEY of Clean metals
SEY of clean Cu with low contaminants
Adsorption and Desorption processes from different surfaces (clean Cu, Laser Treated sample)
Interaction between electron and Argon
Contribution of reflected Electrons to the Low-Energy SEY (Graphite, Cu, Cu with Argon)
CERN 10/09/17
Marco Angelucci

52. Low-Energy SEY Different LE-SEY structuresCO Ar 10
Different LE-SEY structures
depending from adsorbed gases
Study of reflected e- contribution
CERN 10/09/17
Marco Angelucci

53. Low Energy SEY SEY: Total number of electrons emitted (TEE , TEY,...)
True secondaries: number of electrons emitted between 0-50 eV. (if EP > 50 eV.)
Backscattered electrons (Reflected): number of electrons emitted at EP (+ D)
Rediffused electrons: number of electrons emitted between 50 eV and EP – D (if EP > 50 eV.)
”Probabilistic model for the simulation of secondary electron emission” M. A. Furman and M. T. F. Pivi Phys. Rev. ST Accel. Beams 5, (2002)
CERN 10/09/17
Marco Angelucci

54. Evaluation of Reflected (R) and True Secondary (SE) electrons parts
Low Energy SEY a b d SE R d a b c
Evaluation of Reflected (R) and True Secondary (SE) electrons parts
Cimino et al., PRL 93 (2004)
CERN 10/09/17
Marco Angelucci

55. Low Energy SEY Ep= 2 eV Ep= 6.5 eV Wf
Plotting all the data normalizing to UNITY the intensity of the EDC @ Ep< Wf Or
Integrating the curves:
(when Ep <50 eV)
0 to EP – D (True Secondary)
EP – D to EP + D (Elastically Back.)
(when Ep > 50 eV)
0 to 50 eV (True Secondary)
50 eV to EP – D (Rediffused) Wf D
Ep= 20 eV
Ep= 130 eV
Ep= 310 eV Wf
CERN 10/09/17
Marco Angelucci

56. Reflected electrons in Copper
Low Energy SEY
Reflected electrons in Copper
Clean Poly-Cu
Plotting all the data normalizing to UNITY the intensity of the EDC @ Ep< Wf
SEY
Structures in SEY are oscillations in the elastically backscattered components
EDCs
CERN 10/09/17
Marco Angelucci

57. Low Energy SEY Reflected electrons in Copper Different Contributions
Second.
Second.
Redif.
Redif.
Reflec.
Reflec.
CERN 10/09/17
Marco Angelucci

58. Low Energy SEY Reflected electrons in Copper Different Contributions
Second.
Redif.
Reflec.
CERN 10/09/17
Marco Angelucci

59. Reflected electrons in Graphite
Low Energy SEY
Reflected electrons in Graphite
SEY
Plotting all the data normalizing to UNITY the intensity of the EDC @ Ep< Wf
Structures in SEY are oscillations in the elastically backscattered components
EDCs
CERN 10/09/17
Marco Angelucci

60. Low Energy SEY Reflected electrons in Graphite Different Contributions
Second.
Second.
Reflec.
Redif.
Redif.
Reflec.
CERN 10/09/17
Marco Angelucci

61. Reflected electrons in Argon
Low Energy SEY
Reflected electrons in Argon
Ar monolayer
Ar multilayer
SEY
SEY
EDCs
EDCs
CERN 10/09/17
Marco Angelucci

62. Low Energy SEY
... and: Bauer: “Surface microscopy with low energy electrons” Springher 2014
CERN 10/09/17
Marco Angelucci

63. Important Results I
Follow Adsorption process checking the High- Energy SEY (HE-SEY)
Distinguish Single Layer (SL) from Thick Film (TF) formation by Low-Energy SEY (LE-SEY)
Quantify the number of adsorbed layers on surface
Measure Work Function (WF) variation
CERN 10/09/17
Marco Angelucci

64. Important Results II
Measure the desorption temperature of TF and SL with SEY and TPD
Study the Electron Stimulated Desorption with mass spectrometer (quantify desorption)
Study the contribution of reflected e- to Low- Energy SEY
Study the influence of the adsorbed gas in the Low- Energy SEY
CERN 10/09/17
Marco Angelucci

65. Maintenance /Upgrades I
Standard chamber maintenance (transfer)
Preparation chamber
Implemented data acquisition software
Non Standard chamber maintenance (open system)
Implementations for Induced Desorption Studies
CERN 10/09/17
Marco Angelucci

66. Synchrotron Beamlines
Future Activities
Synchrotron Beamlines
XUV2:
High Energy
eV.
XUV1:
High Energy
eV.
CERN 10/09/17
Marco Angelucci

67. Maintenance /Upgrades II
Alignment of Sychrotron beamlines
Preparation for connection with Experimental Chamber
Connection (2/3 month)
System optimization for experiment with electrons and photons
CERN 10/09/17
Marco Angelucci

68. Future Activities
Different Gases adsorption (CO, CO2, CH4 ...) (pure and mixture)
Electron Stimulated Desorption
Measurements on treated samples (continue)
Study of reflected electron on different systems
Different studies with Synchrotron light
CERN 10/09/17
Marco Angelucci