Specific Process Knowledge/Characterization/SEM: Scanning Electron Microscopy: Difference between revisions

From LabAdviser
Jmli (talk | contribs)
Jmli (talk | contribs)
 
(20 intermediate revisions by 4 users not shown)
Line 2: Line 2:
'''Feedback to this page''': '''[mailto:labadviser@nanolab.dtu.dk?Subject=Feed%20back%20from%20page%20http://labadviser.nanolab.dtu.dk/index.php/Specific_Process_Knowledge/Characterization/SEM:_Scanning_Electron_Microscopy  click here]'''  
'''Feedback to this page''': '''[mailto:labadviser@nanolab.dtu.dk?Subject=Feed%20back%20from%20page%20http://labadviser.nanolab.dtu.dk/index.php/Specific_Process_Knowledge/Characterization/SEM:_Scanning_Electron_Microscopy  click here]'''  


''This page is written by DTU Nanolab  internal''


== Scanning electron microscopy in the cleanroom at DTU Nanolab==
=Scanning Electron Microscopy at Nanolab=
There is a large range of scanning electron microscopes (SEMs) at DTU Nanolab. The first couple of sections on this page are about the SEMs in and around the fabrication part of Nanolab in building 346 and 451. The last section is about the SEMs in building 314, which is our dedicated characterization facility.


The number of electron microscopes at DTU Nanolab is large. The five SEMs in building 346 cover a wide range of needs both in the cleanroom and outside: From fast in-process verification of different process parameters such as etch rates, step coverages or lift-off quality to ultra high resolution images on any type of sample intended for publication.
== Scanning electron microscopy in and around the cleanroom==
{{Template:ContentbySEMresponsibles}}


* The SEM Supra 1 is located in the basement outside the cleanroom. It is serving two purposes: Serving the users that have samples from outside the cleanroom and serving as training tool; all new SEM users with no/little SEM experience must be trained on this tool and gain basic knowledge (typically 10 hours of usage) here before being qualified for training on the SEMs in the cleanroom.
The four SEMs in building 346 and 451 cover a wide range of needs both in the cleanroom and outside: From fast in-process verification of different process parameters such as etch rates, step coverages or lift-off quality to ultra high resolution images on any type of sample intended for publication.  


* The SEM 2 and 3 are located in the cleanroom where they serve as general imaging tools for samples that have been fabricated in the cleanroom. Like SEM Supra 1, they are VP models from Carl Zeiss and will produce excellent images on any sample. The possibility of operating at higher chamber pressures in the VP mode makes imaging of bulk non-conducting samples possible. The SEM Supra 2 is also equipped with an airlock and an EDX detector.
* The [[Specific_Process_Knowledge/Characterization/SEM_Supra_1|SEM Supra 1]] is located in the basement outside the cleanroom. It is serving two purposes: Serving the users that have samples from outside the cleanroom and serving as training tool; all new SEM users with no/little SEM experience must be trained on this tool and gain basic knowledge (typically 10 hours of usage) here before being qualified for training on the SEMs in the cleanroom.


* The SEM Leo was a very reliable and rugged instrument that provided high quality images of most samples. It has now been decommissioned and relocated to DTU Mechanics.
* The [[Specific_Process_Knowledge/Characterization/SEM_Supra_2|SEM Supra 2]] and [[Specific_Process_Knowledge/Characterization/SEM_Supra_3|SEM Supra 3]] are located in the cleanroom where they serve as general imaging tools for samples that have been fabricated in the cleanroom. Like SEM Supra 1, they are VP models from Carl Zeiss and will produce excellent images on any sample. The possibility of operating at higher chamber pressures in the VP mode makes imaging of bulk non-conducting samples possible. The [[Specific_Process_Knowledge/Characterization/SEM_Supra_2|SEM Supra 2]] is also equipped with an airlock and an EDX detector.


* The SEM Tabletop 1 is a tabletop SEM that is located in the basement outside the cleanroom. It has a limited resolution, but it is fast and easy to use, also for non-conducting samples. Training in the others SEMs is not required to use this SEM.
* The [[Specific_Process_Knowledge/Characterization/SEM_Gemini_1|SEM Gemini 1]] is a state-of-the-art SEM from Carl Zeiss that was installed in the cleanroom in the autumn of 2023. It has an impressive range of detectors and modes that are intended to be used for the most demanding samples.


SEM Supra 1, 2 and 3 SEM Leo s all manufactured by Carl Zeiss and have the same graphical user interface and very identical electron optics. But there are there are small hardware and software differences, thus a training is needed for each SEM you want to use.
* The [[Specific_Process_Knowledge/Characterization/SEM_Tabletop_1|SEM Tabletop 1]] is a tabletop SEM that is located in the basement outside the cleanroom. It has a limited resolution, but it is fast and easy to use, also for non-conducting samples. Training in the others SEMs is not required to use this SEM.
 
SEM Supra 1, 2 and 3 and the SEM Gemini 1 are all manufactured by Carl Zeiss. The SEM Supra 1, 2 and 3 all have the same graphical user interface and nearly identical electron optics. But there are there are small hardware and software differences, thus a training is needed for each SEM you want to use.


The SEM Tabletop 1 is manufactured by Hitachi.
The SEM Tabletop 1 is manufactured by Hitachi.
Line 23: Line 28:
*[[/samplemount| Sample mounting]]
*[[/samplemount| Sample mounting]]


==Comparison of SEM's in building 346==
==Comparison of SEM's in building 346/451==


{| border="2" cellspacing="0" cellpadding="0"  
{| border="2" cellspacing="0" cellpadding="0"  
Line 30: Line 35:
|style="background:WhiteSmoke; color:black" align="center"|[[Specific_Process_Knowledge/Characterization/SEM_Supra_2|SEM Supra 2]]
|style="background:WhiteSmoke; color:black" align="center"|[[Specific_Process_Knowledge/Characterization/SEM_Supra_2|SEM Supra 2]]
|style="background:WhiteSmoke; color:black" align="center"|[[Specific_Process_Knowledge/Characterization/SEM_Supra_3|SEM Supra 3]]
|style="background:WhiteSmoke; color:black" align="center"|[[Specific_Process_Knowledge/Characterization/SEM_Supra_3|SEM Supra 3]]
|style="background:WhiteSmoke; color:black" align="center"|[[Specific_Process_Knowledge/Characterization/SEM_Gemini_1|SEM Gemini 1]]
|style="background:WhiteSmoke; color:black" align="center"|[[Specific_Process_Knowledge/Characterization/SEM_Tabletop_1|SEM Tabletop 1]]
|style="background:WhiteSmoke; color:black" align="center"|[[Specific_Process_Knowledge/Characterization/SEM_Tabletop_1|SEM Tabletop 1]]
<!--|style="background:WhiteSmoke; color:black" align="center"|[[Specific Process Knowledge/Characterization/SEM FEI QUANTA 200 3D|FEI Quanta 200 3D]]
<!--|style="background:WhiteSmoke; color:black" align="center"|[[Specific Process Knowledge/Characterization/SEM FEI QUANTA 200 3D|FEI Quanta 200 3D]]-->
|-
|-
!colspan="2" border="none" style="background:silver; color:black;" align="center"|Model  
!colspan="2" border="none" style="background:silver; color:black;" align="center"|Model  
Line 37: Line 43:
|style="background:WhiteSmoke; color:black" align="center"| Zeiss Supra 60 VP
|style="background:WhiteSmoke; color:black" align="center"| Zeiss Supra 60 VP
|style="background:WhiteSmoke; color:black" align="center"| Zeiss Supra 40 VP
|style="background:WhiteSmoke; color:black" align="center"| Zeiss Supra 40 VP
|style="background:WhiteSmoke; color:black" align="center"| Zeiss GeminiSEM 560
|style="background:WhiteSmoke; color:black" align="center"| SEM Tabletop 1
|style="background:WhiteSmoke; color:black" align="center"| SEM Tabletop 1
<!--|style="background:WhiteSmoke; color:black" align="center"| FEI Quanta 200 3D-->
<!--|style="background:WhiteSmoke; color:black" align="center"| FEI Quanta 200 3D-->
Line 42: Line 49:
!style="background:silver; color:black" align="center" valign="center" rowspan="2"|Purpose  
!style="background:silver; color:black" align="center" valign="center" rowspan="2"|Purpose  
|style="background:LightGrey; color:black" align="center" | Imaging and measurement of
|style="background:LightGrey; color:black" align="center" | Imaging and measurement of
|style="background:WhiteSmoke; color:black"|
* Conducting samples
* Semi-conducting samples
* Thin (~ 5 µm <) layers of non-conducting materials such as polymers
* Thick polymers, glass or quartz samples
|style="background:WhiteSmoke; color:black"|
|style="background:WhiteSmoke; color:black"|
* Conducting samples
* Conducting samples
Line 70: Line 82:
* Surface material analysis using EDX
* Surface material analysis using EDX
|style="background:WhiteSmoke; color:black"|  
|style="background:WhiteSmoke; color:black"|  
 
|style="background:WhiteSmoke; color:black"|
|style="background:WhiteSmoke; color:black"|
|style="background:WhiteSmoke; color:black"|
|-
|-
Line 82: Line 94:
*Cleanroom of DTU Nanolab in building 346
*Cleanroom of DTU Nanolab in building 346
|style="background:WhiteSmoke; color:black"|
|style="background:WhiteSmoke; color:black"|
*Basement of building 346
*Cleanroom of DTU Nanolab in building 346
|style="background:WhiteSmoke; color:black"|
*Building 451 - room 913
(in the North-East corner of the building's basement)
<!--|style="background:WhiteSmoke; color:black"|
<!--|style="background:WhiteSmoke; color:black"|
*DTU CEN-->
*DTU CEN-->
Line 89: Line 104:
!style="background:silver; color:black" align="center" valign="center" rowspan="2"|Performance
!style="background:silver; color:black" align="center" valign="center" rowspan="2"|Performance
|style="background:LightGrey; color:black" rowspan="2" align="center" |Resolution
|style="background:LightGrey; color:black" rowspan="2" align="center" |Resolution
|style="background:Whitesmoke; color:black" colspan="4" align="center"| The resolution of a SEM is strongly dependent on the type of sample and the skills of the operator. The highest resolution is probably only achieved on special samples
|style="background:Whitesmoke; color:black" colspan="5" align="center"| The resolution of a SEM is strongly dependent on the type of sample and the skills of the operator. The highest resolution is probably only achieved on special samples
|-
|-
|style="background:WhiteSmoke; color:black"|
* 1-2 nm (limited by vibrations)
|style="background:WhiteSmoke; color:black"|
|style="background:WhiteSmoke; color:black"|
* 1-2 nm (limited by vibrations)
* 1-2 nm (limited by vibrations)
Line 119: Line 136:
* High Definition four quadrant Angular Selective Backscattered electron detector (HDAsB)  
* High Definition four quadrant Angular Selective Backscattered electron detector (HDAsB)  
* Variable pressure secondary electron (VPSE)
* Variable pressure secondary electron (VPSE)
|style="background:WhiteSmoke; color:black"|
* Secondary electron (Se2)
* Inlens secondary electron (Inlens)
* Inlens backscatter electron (Inlens ESB)
* Retractable, column mounted six segment backscatter electron (aBSD)
* Variable pressure secondary electron (VPSE)
* Retractable, four segment tranmitted electron (aSTEM)
<!--|style="background:WhiteSmoke; color:black"|
<!--|style="background:WhiteSmoke; color:black"|
* Secondary electron (Everhart-Thornley (ETD))
* Secondary electron (Everhart-Thornley (ETD))
Line 137: Line 161:
* X, Y: 150 &times; 150 mm
* X, Y: 150 &times; 150 mm
* T: -10 to 70<sup>o</sup>  
* T: -10 to 70<sup>o</sup>  
* R: 360<sup>o</sup>
* Z: 50 mm
|style="background:WhiteSmoke; color:black"|
* X, Y: 130 &times; 130 mm
* T: -4 to 70<sup>o</sup>
* R: 360<sup>o</sup>  
* R: 360<sup>o</sup>  
* Z: 50 mm
* Z: 50 mm
Line 151: Line 180:
|-
|-
|style="background:LightGrey; color:black" align="center" |Electron source
|style="background:LightGrey; color:black" align="center" |Electron source
|style="background:Whitesmoke; color:black" colspan="3" align="center"| FEG (Field Emission Gun) source
|style="background:Whitesmoke; color:black" colspan="4" align="center"| FEG (Field Emission Gun) source
|style="background:WhiteSmoke; color:black"|
|style="background:WhiteSmoke; color:black"|
* Thermionic tungsten filament
* Thermionic tungsten filament
Line 167: Line 196:
* Fixed at High vacuum (2 &times; 10<sup>-4</sup>mbar - 10<sup>-6</sup>mbar)
* Fixed at High vacuum (2 &times; 10<sup>-4</sup>mbar - 10<sup>-6</sup>mbar)
* Variable at Low vacuum (0.1 mbar-2 mbar)
* Variable at Low vacuum (0.1 mbar-2 mbar)
|style="background:WhiteSmoke; color:black"|
* Fixed at High vacuum (2 &times; 10<sup>-4</sup>mbar - 10<sup>-6</sup>mbar)
* Variable at Low vacuum
** Standard VP (variable pressure): 5-60 Pa
** Nano VP, 350 um beamsleeve aperture: 5-150 Pa
** Nano VP, 800 um beamsleeve aperture: 5-40 Pa
|style="background:WhiteSmoke; color:black"|
|style="background:WhiteSmoke; color:black"|
* Conductor vacuum mode: 5 Pa
* Conductor vacuum mode: 5 Pa
Line 177: Line 212:
|style="background:WhiteSmoke; color:black"|
|style="background:WhiteSmoke; color:black"|
* All software options available
* All software options available
* Electron magnetic noise cancellations system
|style="background:WhiteSmoke; color:black"|
|style="background:WhiteSmoke; color:black"|
* Antivibration platform
* Antivibration platform
Line 183: Line 219:
|style="background:WhiteSmoke; color:black"|
|style="background:WhiteSmoke; color:black"|
*High Definition four quadrant Angular Selective Backscattered electron detector (HDAsB)
*High Definition four quadrant Angular Selective Backscattered electron detector (HDAsB)
|style="background:WhiteSmoke; color:black"|
* Antivibration platform
* Electron magnetic noise cancellations system
* Zeiss airlock taking up to 6" wafers
* Plasma cleaner
* Sample bias option
|style="background:WhiteSmoke; color:black"|
|style="background:WhiteSmoke; color:black"|
<!--|style="background:WhiteSmoke; color:black"|
<!--|style="background:WhiteSmoke; color:black"|
Line 190: Line 232:
|style="background:LightGrey; color:black" align="center" |Sample sizes
|style="background:LightGrey; color:black" align="center" |Sample sizes
|style="background:WhiteSmoke; color:black"|
|style="background:WhiteSmoke; color:black"|
* Up to 6" wafer with full view
* Up to 6" wafer with full view  
|style="background:WhiteSmoke; color:black"|
|style="background:WhiteSmoke; color:black"|
* Up to 8" wafer with 6" view
* Up to 8" wafer with 6" view
|style="background:WhiteSmoke; color:black"|
*  Up to 6" wafer with full view
|style="background:WhiteSmoke; color:black"|
|style="background:WhiteSmoke; color:black"|
*  Up to 6" wafer with full view
*  Up to 6" wafer with full view
Line 203: Line 247:
|style="background:WhiteSmoke; color:black"|
|style="background:WhiteSmoke; color:black"|
* Any standard cleanroom material and samples from the Laser Micromachining tool and the Polymer Injection Molding tool
* Any standard cleanroom material and samples from the Laser Micromachining tool and the Polymer Injection Molding tool
|style="background:WhiteSmoke; color:black"|
* Any standard cleanroom materials
|style="background:WhiteSmoke; color:black"|
|style="background:WhiteSmoke; color:black"|
* Any standard cleanroom materials
* Any standard cleanroom materials
Line 217: Line 263:


<br clear="all" />
<br clear="all" />
[[Specific_Process_Knowledge/Characterization/SEM_LEO|SEM LEO]]


==Comparison of the SEMs at DTU Nanolab - building 307/314 [[image:Under_construction.png|50px]]==
==Comparison of the SEMs at DTU Nanolab - building 307/314 [[image:Under_construction.png|50px]]==
{{SEM comparison table 314}}
{{SEM comparison table 314}}

Latest revision as of 14:10, 19 December 2023

Feedback to this page: click here

This page is written by DTU Nanolab internal

Scanning Electron Microscopy at Nanolab

There is a large range of scanning electron microscopes (SEMs) at DTU Nanolab. The first couple of sections on this page are about the SEMs in and around the fabrication part of Nanolab in building 346 and 451. The last section is about the SEMs in building 314, which is our dedicated characterization facility.

Scanning electron microscopy in and around the cleanroom

Unless otherwise stated, the content of this page was created by the SEM responsibles at DTU Nanolab

The four SEMs in building 346 and 451 cover a wide range of needs both in the cleanroom and outside: From fast in-process verification of different process parameters such as etch rates, step coverages or lift-off quality to ultra high resolution images on any type of sample intended for publication.

  • The SEM Supra 1 is located in the basement outside the cleanroom. It is serving two purposes: Serving the users that have samples from outside the cleanroom and serving as training tool; all new SEM users with no/little SEM experience must be trained on this tool and gain basic knowledge (typically 10 hours of usage) here before being qualified for training on the SEMs in the cleanroom.
  • The SEM Supra 2 and SEM Supra 3 are located in the cleanroom where they serve as general imaging tools for samples that have been fabricated in the cleanroom. Like SEM Supra 1, they are VP models from Carl Zeiss and will produce excellent images on any sample. The possibility of operating at higher chamber pressures in the VP mode makes imaging of bulk non-conducting samples possible. The SEM Supra 2 is also equipped with an airlock and an EDX detector.
  • The SEM Gemini 1 is a state-of-the-art SEM from Carl Zeiss that was installed in the cleanroom in the autumn of 2023. It has an impressive range of detectors and modes that are intended to be used for the most demanding samples.
  • The SEM Tabletop 1 is a tabletop SEM that is located in the basement outside the cleanroom. It has a limited resolution, but it is fast and easy to use, also for non-conducting samples. Training in the others SEMs is not required to use this SEM.

SEM Supra 1, 2 and 3 and the SEM Gemini 1 are all manufactured by Carl Zeiss. The SEM Supra 1, 2 and 3 all have the same graphical user interface and nearly identical electron optics. But there are there are small hardware and software differences, thus a training is needed for each SEM you want to use.

The SEM Tabletop 1 is manufactured by Hitachi.

Common challenges in scanning electron microscopy

Comparison of SEM's in building 346/451

Equipment SEM Supra 1 SEM Supra 2 SEM Supra 3 SEM Gemini 1 SEM Tabletop 1
Model Zeiss Supra 40 VP Zeiss Supra 60 VP Zeiss Supra 40 VP Zeiss GeminiSEM 560 SEM Tabletop 1
Purpose Imaging and measurement of
  • Conducting samples
  • Semi-conducting samples
  • Thin (~ 5 µm <) layers of non-conducting materials such as polymers
  • Thick polymers, glass or quartz samples
  • Conducting samples
  • Semi-conducting samples
  • Thin (~ 5 µm <) layers of non-conducting materials such as polymers
  • Thick polymers, glass or quartz samples
  • Conducting samples
  • Semi-conducting samples
  • Thin (~ 5 µm <) layers of non-conducting materials such as polymers
  • Thick polymers, glass or quartz samples
  • Conducting samples
  • Semi-conducting samples
  • Thin (~ 5 µm <) layers of non-conducting materials such as polymers
  • Thick polymers, glass or quartz samples
  • Conducting samples
  • Semi-conducting samples
  • Thin (~ 5 µm <) layers of non-conducting materials such as polymers
  • Thick polymers, glass or quartz samples
Other purpose
  • Surface material analysis using EDX
Instrument location
  • Basement of building 346
  • Cleanroom of DTU Nanolab in building 346
  • Cleanroom of DTU Nanolab in building 346
  • Cleanroom of DTU Nanolab in building 346
  • Building 451 - room 913

(in the North-East corner of the building's basement)

Performance Resolution The resolution of a SEM is strongly dependent on the type of sample and the skills of the operator. The highest resolution is probably only achieved on special samples
  • 1-2 nm (limited by vibrations)
  • 1-2 nm (limited by vibrations)
  • 1-2 nm (limited by vibrations)
  • 1-2 nm (limited by vibrations)
  • ~25 nm (limited by instrument)
Instrument specifics Detectors
  • Secondary electron (Se2)
  • Inlens secondary electron (Inlens)
  • 4 Quadrant Backscatter electron (QBSD)
  • Variable pressure secondary electron (VPSE)
  • Secondary electron (Se2)
  • Inlens secondary electron (Inlens)
  • 4 Quadrant Backscatter electron (QBSD)
  • Variable pressure secondary electron (VPSE)
  • Secondary electron (Se2)
  • Inlens secondary electron (Inlens)
  • High Definition four quadrant Angular Selective Backscattered electron detector (HDAsB)
  • Variable pressure secondary electron (VPSE)
  • Secondary electron (Se2)
  • Inlens secondary electron (Inlens)
  • Inlens backscatter electron (Inlens ESB)
  • Retractable, column mounted six segment backscatter electron (aBSD)
  • Variable pressure secondary electron (VPSE)
  • Retractable, four segment tranmitted electron (aSTEM)
  • Secondary electron (SE)
  • Backscatter electron (BSE)
Stage
  • X, Y: 130 × 130 mm
  • T: -4 to 70o
  • R: 360o
  • Z: 50 mm
  • X, Y: 150 × 150 mm
  • T: -10 to 70o
  • R: 360o
  • Z: 50 mm
  • X, Y: 130 × 130 mm
  • T: -4 to 70o
  • R: 360o
  • Z: 50 mm
  • X, Y: 130 × 130 mm
  • T: -4 to 70o
  • R: 360o
  • Z: 50 mm
  • X, Y: 35 mm
  • T: No tilt
  • R: No rotation
  • Z: 0 mm
Electron source FEG (Field Emission Gun) source
  • Thermionic tungsten filament
Operating pressures
  • Fixed at High vacuum (2 × 10-4mbar - 10-6mbar)
  • Variable at Low vacuum (0.1 mbar-2 mbar)
  • Fixed at High vacuum (2 × 10-4mbar - 10-6mbar)
  • Variable at Low vacuum (0.1 mbar-2 mbar)
  • Fixed at High vacuum (2 × 10-4mbar - 10-6mbar)
  • Variable at Low vacuum (0.1 mbar-2 mbar)
  • Fixed at High vacuum (2 × 10-4mbar - 10-6mbar)
  • Variable at Low vacuum
    • Standard VP (variable pressure): 5-60 Pa
    • Nano VP, 350 um beamsleeve aperture: 5-150 Pa
    • Nano VP, 800 um beamsleeve aperture: 5-40 Pa
  • Conductor vacuum mode: 5 Pa
  • Standard vacuum mode: 30 Pa
  • Charge-up reduction vacuum mode: 50 Pa
Options
  • All software options available
  • Electron magnetic noise cancellations system
  • Antivibration platform
  • Fjeld M-200 airlock taking up to 8" wafers
  • Oxford Instruments X-MaxN 50 mm2 SDD EDX detector and AZtec software package
  • High Definition four quadrant Angular Selective Backscattered electron detector (HDAsB)
  • Antivibration platform
  • Electron magnetic noise cancellations system
  • Zeiss airlock taking up to 6" wafers
  • Plasma cleaner
  • Sample bias option
Substrates Sample sizes
  • Up to 6" wafer with full view
  • Up to 8" wafer with 6" view
  • Up to 6" wafer with full view
  • Up to 6" wafer with full view
  • Up to 70 mm with full wiew
Allowed materials
  • Any standard cleanroom material and samples from the Laser Micromachining tool and the Polymer Injection Molding tool
  • Any standard cleanroom materials
  • Any standard cleanroom materials
  • Any standard cleanroom materials
  • Any standard cleanroom material and samples from the Laser Micromachining tool and the Polymer Injection Molding tool
  • Some biological samples (ask for permission)


Comparison of the SEMs at DTU Nanolab - building 307/314

Equipment Nova QFEG AFEG Helios
Purpose
  • Conductive samples in High Vac
  • Charge reduction in Low Vac
  • X Ray Analysis with EDS
  • Crystallographic analysis using EBSD and both On and Off axis TKD
  • In-situ experiments with Heating and Gas injection
  • Conductive samples in High Vac
  • Charge reduction in Low Vac
  • Environmental control using Peltier stage
  • Cryogenic sample fixing/stabilization using cryo stage
  • X Ray Analysis with EDS
  • Conductive samples in High Vac
  • Charge reduction in Low Vac
  • X Ray Analysis with EDS and WDS
  • Conductive samples in High Vac
  • Micro and Nano milling/fabrication using various gases and FIB
  • X Ray Analysis with EDS
  • Crystallographic analysis using EBSD and Off Axis TKD
Equipment position Building 314 Room 060 Building 314 Room 011 Building 314 Room 034 Building 314 Room 061
Resolution The resolution of a SEM is strongly dependent on sample type and the operator. Resolution quoted is using sputtered gold on carbon
  • High Vacuum operation in Mode II:
    • 1.0 nm at 15 kV (TLD detector and optimum working distance)
    • 1.8 nm at 1 kV (TLD detector and optimum working distance)
  • Low Vacuum operation in Mode II:
    • 1.5 nm at 10 kV (Helix detector and optimum working distance)
    • 1.8 nm at 3 kV (Helix detector and optimum working distance)
  • High vacuum
    • 0.8 nm at 30 kV (STEM)
    • 1.0 nm at 30 kV (SE)
    • 2.5 nm at 30 kV (BSE) - 3.0 nm at 1 kV (SE)
  • High vacuum with beam deceleration option
    • 3.0 nm at 1 kV (BD mode + BSE)
  • Low vacuum - 1.4 nm at 30 kV (SE)
    • 2.5 nm at 30 kV (BSE)
    • 3.0 nm at 3 kV (SE)
  • Extended vacuum mode (ESEM)
    • 1.4 nm at 30 kV (SE)
  • High vacuum
    • 0.8 nm at 30 kV (STEM)
    • 1.0 nm at 30 kV (SE)
    • 2.5 nm at 30 kV (BSE) - 3.0 nm at 1 kV (SE)
  • High vacuum with beam deceleration option
    • 3.0 nm at 1 kV (BD mode + BSE)
  • Low vacuum - 1.4 nm at 30 kV (SE)
    • 2.5 nm at 30 kV (BSE)
    • 3.0 nm at 3 kV (SE)
  • Electron Column Operation in Mode II
    • 0.8nm @15kV
    • 0.9nm @1kV
  • Ion Column
    • 4.5nm @ 30kV
Detectors
  • ETD/TLD Secondary Electrons
  • BSED Back Scatter Electrons
  • LVD/LFD Low Vac SE
  • Helix Low Vac SE
  • EDS X Ray by energy
  • EBSD Electron Back Scatter Diffraction
  • TKD Transmission Kikuchi Diffraction
  • STEM Scanning Transmission Electron Microscopy
  • GAD Low Vac BSED
  • ETD Secondary Electrons
  • BSED Back Scatter Electrons
  • LVD/LFD Low Vac SE
  • GSED ESEM SE
  • EDS X Ray by energy
  • STEM Scanning Transmission Electron Microscopy
  • ETD Secondary Electrons
  • BSED Back Scatter Electrons
  • LVD/LFD Low Vac SE
  • GSED ESEM SE
  • EDS X Ray by energy
  • STEM Scanning Transmission Electron Microscopy
  • ETD/TLD Secondary Electrons
  • ABS Annular BSED
  • EDS X Ray by energy
  • EBSD Electron Back Scatter Diffraction
  • CDEM Continuos Dinode Electron Multiplier
Stage specifications
  • X 150mm Piezo
  • Y 150mm Piezo
  • Z 10mm
  • R 360⁰ Piezo
  • T 70⁰
  • X 50mm
  • Y 50mm
  • Z 50mm
  • R 360⁰
  • T 70⁰ Manual
  • X 50mm
  • Y 50mm
  • Z 50mm
  • R 360⁰
  • T 70⁰ Manual
  • X 150mm Piezo
  • Y 150mm Piezo
  • Z 10mm
  • R 360⁰ Piezo
  • T 70⁰
Options B C D E
Max sample size Consult with DTU Nanolab staff as weight, dimensions, pumping capacity and technique all play a roll in the sample size