Advances in attosecond science have led to a wealth of important discoveries in atomic,
molecular, and solid-state physics and are progressively directing their footsteps toward …

Over the past few decades, coherent broadband spectroscopy has been widely used to
improve our understanding of ultrafast processes (eg, photoinduced electron transfer, proton …

Attosecond science capitalizes on the extreme nonlinearity of strong fields—driven by few-
cycle pulses—to attain attosecond temporal resolution and give access to the electron …

Attosecond science offers formidable tools for the investigation of electronic processes at the
heart of important physical processes in atomic, molecular and solid-state physics. In the last …

The frequency of electric currents associated with charge carriers moving in the electronic
bands of solids determines the speed limit of electronics and thereby that of information and …

The generation of extremely short isolated attosecond pulses requires both a broad spectral
bandwidth and control of the spectral phase. Rapid progress has been made in both …

Femtosecond pulse generation was pioneered four decades ago using mode-locked dye
lasers, which dominated the field for the following 20 years. Dye lasers were then replaced …

The time it takes a bound electron to respond to the electromagnetic force of light sets a
fundamental speed limit on the dynamic control of matter and electromagnetic signal …

Modern electronics are founded on switching the electrical signal by radio frequency
electromagnetic fields on the nanosecond time scale, limiting the information processing to …

Extreme ultraviolet (EUV) high-harmonic radiation, emerging from laser-driven atoms,
molecules or plasmas underlies powerful attosecond spectroscopy techniques,, and …