STS | Compressed Baryonic Matter Experiment at FAIR

Silicon Tracking System (STS)

Coordinator:
Christian Joachim Schmidt

c.j.schmidt(at)gsi.de

Technical Coordinator:
Johann Heuser

j.heuser(at)gsi.de

CBM simulation (UrQMD, Geant, CbmRoot)
central Au+Au collision, 10 AGeV/c

The Silicon Tracking System (STS) is CBM’s core detector to identify the charged particles that are created when the nuclear beams extracted from the SIS100 accelerator interact with the target. Hundreds of particles originate from the collision of a single beam ion with the target material. The interactions take place at rates up to ten million times per second. Eight STS tracking stations sample multiple intersection points along the particles’ flight paths. This allows reconstructing the particle trajectories (“tracks”) and to determine from their curvatures in the dipole magnetic field the particle momenta – a central quantity for CBM physics analyses. Unstable particles are identified through their decays into daughter particles, with their tracks pointing to vertices separate from the primary collision point.

The particle detection technology is based on highly-segmented double-sided Silicon microstrip sensors read out with fast self-triggering front-end electronics. Five-dimensional particle hit information (sensor channel coordinates, time and charge) is streamed at rates up to 1 Tbit/s to a compute farm where the trajectory reconstruction and finally the collision event analysis are performed. The STS hits are determined with 15 micrometer spatial resolution, the associated time is measured with 5 ns resolution. The STS detector can further contribute to particle identification through the measurement of energy loss.

Energy loss vs. Momentum
STS in J-PARC E16 experiment, 2024

A key design goal was to minimize particle multiple scattering in the physics aperture, while fulfilling the high detection-rate requirement. Several measures were taken:

Two-coordinate measurement is realized in the same Silicon material.
The functional building block, the module, separates the sensor from the read-out part and locates the fast, heat generating electronics with its powering and cooling infrastructure at the periphery of the system by using ultra-low mass cable and interconnection technologies.
The carrier structure for up to ten modules, the ladder, employs lightweight carbon fiber elements.

First STS detector series ladder comprising 10 detector modules

The STS system integration realizes eight tracking stations from 20 mechanical half-units, which are assemblies of ladders, read-out and powering electronics on C-shaped aluminum frames. In the detector, they are located evenly spaced between 0.3 m and 1 m distance downstream of the target. Their low-mass construction allows for momentum measurement with resolution better than 2%.

The tracking stations are installed into an enclosure with thermally insulating walls. Thermal runaway of sensor currents in the high-radiation environment will be avoided through the application of sensor air cooling down to 0° C. The readout and powering electronics, dissipating up to 40 kW, will be cooled in contact with a cold liquid circulated in cooling plates. All power, cooling and communication links are internally routed to the upstream enclosure wall where supplies in the CBM hall can be branched to. At the upstream wall, the STS box also comprises the vacuum chamber with the interaction-target and the Micro Vertex Detector (MVD). A 0.5 mm thick secondary particle track window separates target chamber and STS fiducial volume. It is integrated with the 1 mm thick STS beam pipe section forming one structure made from carbon fiber composite.

CAD model of the STS detector system in the dipole magnet

STS pre-series modules in the J-PARC E16 experiment, commissioning run 0e, 2024

Test experiments under realistic conditions in beam, most recently in the mCBM demonstrator at GSI-SIS18 and in the E16 experiment at J-PARC, have proven that design concept and prototype elements match STS specifications. Substantial experience has been gained on components and system integration, operation, data acquisition and data analysis towards the full-scale STS detector.

STS in the mCBM demonstrator at GSI-SIS18

Construction of the STS system started in fall 2023:

All of its thousands of custom-developed components (sensors, front-end electronics, micro cables, interconnections, mechanical parts), are available and have been quality-controlled in STS laboratories after production in industry in the past years.
The assembly and qualification of the basic STS elements, the modules, is being carried out in laboratories at GSI and KIT. In a multi-step workflow, the Silicon sensors are attached to the read-out electronics via ultra-low-mass multiline flat cables. Up to 10 modules are joined forming a ladder on a low-mass but stable supporting structure made from carbon-fiber elements. All ladders are being qualified at GSI prior to subsequent system integration.
As of the beginning of 2025, 39% of the 876 modules total have been assembled. The first three of the 106 detector ladders total have been integrated and passed the series production readiness review. The STS system integration at GSI is being prepared.

The Silicon Tracking System is being realized by expert teams of the CBM Collaboration comprised of physicists, engineers, technicians and doctoral and graduate students at:

	GSI-FAIR Goethe University Frankfurt/Main Karlsruhe Institute of Technology University of Tübingen
	AGH University of Krakow Jagiellonian University Warsaw University of Technology
	Kyiv Institute for Nuclear Research
	High Energy Accelerator Research Organization KEK (associated)