FRB 20240114A is a hyperactive repeating fast radio burst (FRB) source discovered by the CHIME/FRB Collaboration in January 2024. The source has been followed up by numerous radio telescopes, including MeerKAT, uGMRT, and FAST, and has been localized to a dwarf star-forming galaxy at a redshift of z ∼ 0.13 with a confirmed persistent radio source. We report observations of FRB 20240114A with the Effelsberg 100-m radio telescope using the Ultra BroadBand (UBB) receiver, covering 1.3--6.0 GHz. Over four epochs, we detected more than 700 bursts, providing an unprecedented broadband dataset for statistical analysis of this active repeater. We performed a comprehensive study of the bursts’ morphologies, occurrence rates, spectral and temporal widths, and waiting-time distributions across six sub-bands spanning the UBB frequency range. The bursts exhibit four main spectral morphologies, including simple, complex, and frequency-drifting structures. No bursts were detected across the full 1.3--6 GHz band, confirming band-limited emission. Burst widths show modest frequency evolution, while fractional bandwidths remain roughly constant at ∼10%. Burst rates vary strongly with time and frequency, partly influenced by scintillation. The waiting-time distribution is bimodal, with largely independent bursts and short-timescale clustering on ∼10 ms, indicating a characteristic emission timescale. The source can switch emission frequencies by ≳GHz on seconds and by ∼700 MHz on millisecond timescales, implying a highly agile emission mechanism. Taken together, these results indicate that FRB 20240114A is powered by a dynamic emission mechanism capable of rapid spectral modulation. The short-timescale clustering, downward frequency drifts, and lack of separation between intra- and inter-burst intervals suggest a continuous burst behaviour arising from a common physical process. This emphasizes the importance of wideband, high-time-resolution observations to constrain emission models and reveals that even among active repeaters, individual sources can exhibit unique spectral-temporal signatures.
Limaye et al. (Wed,) studied this question.