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LT Nanoprobe – Low-temperature 4-probe STM

A major challenge in the development of molecular and spintronic nanodevices is their interconnection with larger scale electrical circuits required to control and characterize their functional properties. Local electrical probing by multiple probes with the ultimate precision of scanning tunneling microscopy (STM) and analytical capabilities of scanning tunneling spectroscopy (STS) can significantly improve efficiency in analyzing individual nanodevice approaches without the need for full electrical integration that conventionally requires extended fabrication techniques.

In order to meet the requirements for electrical probing of nanostructures Omicron has developed in collaboration with us the LT Nanoprobe, a sophisticated instrument specifically designed for local and non-destructive 4-probe measurements at low temperatures. Four fully functional STM scanners are located next to a sample stage on a support attached to a LHe cryostat. Efficient thermal shielding allows for temperatures well below 5 K, extremely low thermal drift, and thermal equilibrium of sample and probes. A high resolution, UHV-compatible scanning electron microscope (SEM) at sufficiently small working distance to the compact 4-probe STM is used to navigate the tips on the sample. The shared stack scanner allows coarse positioning of the sample within ±4 mm in both lateral directions at any temperature. The coarse positioning system of each probe enables the controlled displacement of the probes in a volume of 5 mm x 5 mm x 3 mm (XYZ). Each probe can individually be brought in tunnelling contact by means of an automatic approach. Alternatively, the probes can be manually approached until electrical contact is established. A TTL trigger-controlled switching technology specifically adapted to the pA-current regime is utilized to route signals to external measurement equipment. Thus, a structure of interest in the nanometre regime can be imaged by SEM and STM, selected, and contacted by the four probes under the guidance of the high resolution SEM for electrical measurements in tunnelling or ohmic contact regime.

 

 


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Figure: LT Nanoprobe mounted on a bath cryostat and with an UHV-compatible SEM column mounted on top.

 

 



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Figure: Sequence of SEM images taken at 5 K showing the coarse positioning of the 4 STM probes.

Dr. Frank Matthes
Dr. Daniel E. Bürgler

Results


1. STM performance
2. I-V measurement of a graphene flake


Results

1. STM performance

Each of the four scanner modules allows high-resolution and stable imaging as demonstrated by atomically resolving the Au(111) surface at 4.5 K. The constant-current mode STM data depicts the well-known Herring-bone superstructure superimposed with the hexagonal atomic lattice. The atomic corrugation is approximately 6 pm indicating a vertical stability of the LT Nanoprobe system in the low pm range. The image size is 21 nm x 25 nm (U = 310 mV, IT = 3 nA, raw data after slope subtraction).

 

2. I-V measurement of a graphene flake

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The SEM image shows graphene flakes that have been spread on an oxidized silicon wafer. The dark areas in the upper right part of the SEM image represents a region of overlapping and conducting graphene flakes. The LT Nanoprobe is used to electrically contact the flakes with the four STM tips. The I-V characteristics of overlapping graphene flakes measured in 4-point configuration and at 130 K indicates metallic behavior.


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