Black hole evaporation experiments, inspired by Hawking radiation theory, require highly controlled environments to detect subtle quantum effects. Surprisingly, outdoor seating can play a crucial role in these experiments when designed with precision.

1. Material Selection: Seating structures must use non-interfering materials like carbon fiber or specialized polymers to avoid electromagnetic disruption of sensitive detectors.

2. Modular Geometry: Angular seating arrangements can help direct experimental equipment toward optimal celestial observation points while providing researcher workspace.

3. Thermal Regulation: Integrated cooling systems in seating platforms help maintain stable temperatures for equipment calibration against Hawking radiation predictions.

4. Vibration Dampening: Hydraulic or magnetic levitation elements in seating foundations isolate experiments from ground vibrations and pedestrian movement.

5. Data Integration: Smart seating with embedded fiber optics could potentially serve as secondary data collection points for cosmic background measurements.

This unconventional approach demonstrates how everyday infrastructure can be reimagined to support frontier physics research, creating hybrid spaces where public seating doubles as scientific instrumentation platforms. The design philosophy merges astrophysics requirements with human-centered functionality, potentially revolutionizing how we utilize public spaces for cutting-edge science.