Terahertz (THz) radiation, widely defined as electromagnetic radiation in the frequency range 0.3–3 THz, is attracting considerable interest owing to potential applications in imaging and spectroscopy for medical diagnostics and biology, high-bandwidth communication, security and defence, and non-destructive evaluation.

THz optics has entered a new phase of research in recent years. The performance of THz sources has been significantly enhanced so that they now have considerably higher output powers, narrower pulses (in both the time and frequency domains) and wider frequency ranges. Furthermore, the increase in their degrees of freedom makes THz sources just as convenient as visible or infrared sources for pump–probe measurements. Finally, THz radiation can be used to obtain important physical data that is not accessible using X-ray or infrared radiation. Several measurement techniques based on THz radiation are now employed for fundamental material research. For example, THz radiation is used to manipulate spin and the superconductivity of materials.

Clearly, the interest in THz science extends beyond the development of light sources and measurement techniques to fundamental material research. This issue of Nature Photonics features a special focus on THz optics with three Reviews, a Commentary, and an Interview, which showcase the exciting state of current research in this area.

Credit: MIT

In the Interview on page 670, Xi-Cheng Zhang recalls the early development of THz science in the late 1980s and early 1990s. He identifies two milestones in the development of THz sources — the generation of THz pulses from short laser pulses and the development of the THz quantum cascade laser. He envisages that the next breakthrough in the field could be the development of high-intensity THz sources. He says that non-destructive THz imaging is highly promising for meeting the current demands in the areas of security and quality control. He also considers that combining different technologies, such as electronics and plasmonics, is important for realizing novel THz systems that offer orders of magnitude improvements in performance at a fraction of the cost of existing systems.

In their Review on page 680, Tobias Kampfrath and co-authors describe how intense THz transients interact with molecules in condensed matter and gases, and how they can be used to manipulate spin, electrons, lattice vibrations, molecular orientation and rotation. In addition to resonant manipulation, the Review also considers nonresonant manipulation such as field ionization of impurities, high-field electron transport and impact ionization.

Coincidentally, two of the research papers in this issue also fall in the area of terahertz transients. On page 720, Carlo Vicario and co-workers report off-resonant magnetization dynamics in a cobalt thin film. The strong phase locking between an intense single-cycle THz wave transient and the magnetization permits the magnetization vector of a THz magnetic field to be directly controlled on a femtosecond timescale. This finding promises to open up new avenues for realizing ultrafast data recording in magnetic media. On page 724, Masaaki Sato and co-workers report a new experimental technique for polarization shaping of terahertz pulses to arbitrarily control the chirality, phase, pulse duration and frequency of circularly polarized few-cycle THz pulses. This technique has numerous potential applications in areas such as nonlinear optics, coherent control and coherent multidimensional spectroscopy for which the polarization degree of freedom is important.

THz quantum cascade lasers have evolved dramatically since they were first developed. On page 691, Carlo Sirtori and co-authors review THz engineering using quantum cascade lasers and highlight methods that have been used to control their spectral and beam properties. On the other hand, on page 702, Ulrich Welp and co-authors provide an overview of the state-of-the-art research on superconducting THz emitters based on Bi2Sr2CaCu2O8+δ. The development of superconducting sources of THz- and sub-THz radiation is of technological importance, because this frequency range remains difficult to cover with compact solid-state sources.

The Commentary by Daniel Mittleman on page 666 notes the catch-22 situation that used to exist in THz research — there was no strong incentive to develop new technologies without first identifying a 'killer application', but there was little motivation to explore applications without establishing a viable technology base. He points out that the development of innovative tools and techniques is vital for improving research capabilities and opening up new research directions in the terahertz regime. He cites the recent progress in THz sources and plasmonics as two examples of exciting advances that contribute to the vibrancy of THz research and technology.

THz radiation shares some characteristics with both visible light and microwaves. This intermediate nature of THz radiation can make it useful for a wide range of applications and give it an advantage over electromagnetic radiation in other frequency regimes. This focus issue provides an overview of the importance and applications of THz radiation.