The study, "Single-pulse terahertz spectroscopy monitoring sub-millisecond time dynamics at a rate of 50 kHz," was published in Nature Communications. The first technique imprints the information ...

Terahertz spectroscopy occupies the electromagnetic window between the microwave and infrared regions, spanning roughly 0.1–10 THz. It combines aspects of electronics and photonics to probe molecular ...

We employ ultrabroadband terahertz (THz) spectroscopy to expose the high-frequency transport properties of Dirac fermions in monolayer graphene. By controlling the carrier concentration via tunable ...

Terahertz (THz) radiation, which occupies the frequency band between microwaves and infrared light, is essential in many next-generation applications, including high-speed wireless communications, ...

The current understanding of the oil generation potential of oil shale and the dynamic process of organic matter pyrolysis is still unclear, leading to the relatively slow progress in its development ...

How do plants breathe? When do they open and close the tiny pores on their leaves, and what does this mean for their water balance? A research team led by Marburg physicist Professor Martin Koch has ...

Terahertz (THz) radiation is essential in many next-generation applications, including high-speed wireless communications, chemical sensing, and advanced material analysis. To harness THz waves, ...

Researchers developed a frequency-comb-referenced terahertz Fabry-Pérot interferometry platform that measures lithium-ion battery electrode thickness with nanometer-scale precision. The method also ...

Humans typically blink 4 times per second, equivalent to a frequency of 4 Hz. Blinking at a rate of 1 billion times per second, or 1 GHz, is not possible for a human being. But this is the current ...

Using a new method 'Terahertz (THz) calorimetry', a research team shed new light on the spontaneous phase separation into a protein-rich and a protein-poor phase in a solution. It is assumed that the ...

A research team in Bochum, Germany has unexpectedly found that light can slow down movements in the nanoworld. This is due to quantum friction, a phenomenon that has been poorly understood until now.