Discrete frequency modes, or bins, present a blend of opportunities and challenges for
photonic quantum information processing. Frequency-bin-encoded photons are readily …

Integrated photonics provides a powerful approach for develo** compact, stable, and
scalable architectures for the generation, manipulation, and detection of quantum states of …

The time-frequency degree of freedom is a powerful resource for implementing high-
dimensional quantum information processing. In particular, field-orthogonal pulsed temporal …

Temporal modes (TMs) of photons provide an appealing high-dimensional encoding basis
for quantum information. While techniques to generate TM states have been established …

Frequency-bin quantum information encoding offers an intriguing synergy with classical
optical networks, with the ability to support many qubits in a single fiber. Yet, coherent …

Accurate time-delay measurement is at the core of many modern technologies. We present a
temporal-mode demultiplexing scheme that achieves the ultimate quantum precision for the …

Sorting quantum fields into different modes according to their Fock-space quantum numbers
is a highly desirable quantum operation. In this Letter, we show that a pair of two-level …

Spectral-and time-multiplexing are currently explored to generate large multipartite quantum
states of light for quantum technologies. In the continuous variable approach, the …

Manipulation of quantum optical pulses, such as single photons or entangled photon pairs,
enables numerous applications, from quantum communications and networking to …

Temporal modes (TMs) are field-orthogonal broadband wave-packet states of light
occupying a common frequency band, and they can encode information in a higher …