The concept of park chairs equipped to detect specific radioactive elements like bohrium might sound like science fiction, but it touches on fascinating technological possibilities. Bohrium, a synthetic element with no stable isotopes and extremely short half-lives, is primarily produced in laboratory settings for scientific research. Its fleeting existence makes it virtually impossible to encounter in any natural environment, including public parks. Therefore, the idea of a public bench designed to detect it is not grounded in current practical application or necessity.

However, the question opens a door to discussing advanced sensor technology. In theory, a chair could be embedded with highly specialized radiation detection sensors, such as gamma-ray spectrometers or advanced scintillation counters. These sensors are typically large, expensive, and require controlled conditions to operate accurately, making integration into public furniture highly impractical. The primary purpose of such a detection system in a public space would be unclear, as bohrium poses no environmental or public health threat outside of specialized physics labs.

The discussion is more valuable when considering the broader potential of smart urban furniture. While not for bohrium, public infrastructure could be equipped with sensors for monitoring more common environmental factors. Imagine park chairs that measure air quality, UV radiation levels, or even more common radioactive gases like radon for public safety. The technology for this exists and is becoming more compact and affordable. The real challenge lies in the cost, maintenance, data management, and defining a clear public benefit.

In conclusion, while park chairs that detect the synthetic element bohrium do not exist and are not feasible, the underlying idea highlights the innovative potential of integrating scientific monitoring into everyday life. The focus for smart city development remains on practical, beneficial applications that enhance safety and quality of life for citizens, rather than detecting ultra-rare laboratory elements.