Programmable and Scalable Terahertz Holographic Metasurface with CMOS Chip Tiles

A dynamically programmable and Terahertz (THz) metasurface, in which each element can be individually reconfigured to allow controlled wavefront shaping at GHz speed can have a transformative impact in applications such as wireless communication, sensing, and high resolution imaging..

Like Comment
Read the paper

Spatial and temporal control of the far-field and near-field distribution of the THz signals is critical to enabling applications namely, high-speed wireless communication, high-resolution imaging, and sensing. Particularly, being able to manipulate THz fields at sub-wavelength scales at high speed can lead to the development of versatile THz sensing and communication systems for which rapid and reconfigurable beamforming is needed. This can also enable new forms of energy-efficient, compact, and lens-less THz sensing and imaging systems with a low number of pixels. Metasurfaces are two-dimensional surfaces with precisely designed scatterers that create controlled field transformation of incident wavefronts across the properties of amplitude, phase, frequency, and polarization. 

Concept of scalable THz holographic metasurface for wavefront manipulation.

Engineering the fundamental material properties such as electric and magnetic susceptances and thereby the overall surface impedance is a powerful technique to manipulate electromagnetic (EM) wave propagation and metasurfaces are one of the ways of achieving the same. Unlike conventional optical or antenna design, such surfaces are designed with carefully engineered scattering structures at sub-wavelength length scales that can collectively provide abrupt phase and amplitude changes of the incident THz field. This allows us to systematically design flat metasurfaces with scattering structures capable of a desired EM transformation.  Metasurfaces in conjugation with reconfigurable high speed electronics, can allow new methodologies through this ‘material as a device’ design approach. In many applications, metasurfaces are paving the way towards low-loss, flat, and ultra-thin form factor components.

Figure 1. Dynamically programmable and scalable THz metasurface with tiled silicon chips. a. Perspective and top view of the fabricated 2×2 tiled metasurface chips operating at 0.3 THz. b. A single silicon chip tile measuring overall 2×2 mm2, fabricated in an industry-standard 65 nm CMOS process, consists of a programmable 2D array of 12×12 meta-elements.

Here, we present a modular approach for programmable THz metasurface with fully integrated silicon chip tiles (See Fig. 1). Silicon chip architecture lends itself naturally for modular and repetitive architectures with seamless interconnects. In this article, we demonstrate this design methodology with silicon chip tiles fabricated in an industry-standard 65  nm  CMOS  process.   Each chip encompasses an array of 12×12 elements.   Each element is individually addressable and programmable with 8-bit control. Taking this as a unit tile, we demonstrate a 2×2 array of these tiles, creating a 2D surface with 576 meta-elements that are independently digitally reconfigurable at a maximum clock speed of 5 GHz. We demonstrate the capabilities of the surface with amplitude modulation with a switching depth of 25 dB, operation as a spatial light modulator, reconfigurable beamforming of ± 30o with phased surfaces, and programmable holographic projections at 0.3 THz. The tile-based approach is scalable to even larger arrays and potentially to the neighboring spectral regions. Some of the illustrative results are shown in Fig. 2.

Figure 2. Programmable THz beamforming, high-speed switching for spatial light modulation, and dynamic holographic projections. a. Simulated beamforming due to linear phase gradients along one axis of the metasurface. A group of 4 unit cells is consecutively set to a particular digital setting to achieve a specific linear phase gradients. b-d .Simulated and measured beamforming at -30o, 0o, and +30o respectively at 0.3 THz. The measurements demonstrate close correspondence with simulation. e. Measured ON-OFF ratio of the transmitted wave across the metasurface for the two digital states (all open and all short) as the clock frequency is varied from 1 MHz to 8 GHz. The measured amplitude depth modulation is about 25 dB up to 5 GHz enabling high-speed spatial light modulation. f. Measured near fields and holographic projections of letters ‘P’ and ‘U’ respectively at a distance of 5 mm.

The high-speed modulation of the surface at multi-GHz speed allows the surface to establish a high data rate THz communication link. With the ability to control amplitude and phase of the transmitted wave, the surface can be operated as a back-scatter radio that can convert a continuous-wave signal into a modulated one. This could potentially lead to THz surface modulators that enable high-speed THz transmitters that circumvent the need for frequency mixers. Such systems could be of use in future THz sensing and imaging systems, and in multi-Gbps THz wireless links. These applications can enable the next-generation of ubiquitous THz connectivity with high density deployment of low cost and low power THz wireless nodes.

Researchers of this work at Princeton University, Electrical Department. From left to right: Suresh Venkatesh (Postdoctoral Researcher), Hooman Saeidi (Graduate Student), and Kaushik Sengupta (Associate Professor). 

For more details, check out our paper “A High-Speed Programmable and Scalable Terahertz Holographic Metasurface based on Tiled CMOS Chips” on Nature Electronics, Dec 2020.

Suresh Venkatesh

Postdoctoral Researcher, Princeton University

Suresh Venkatesh received his M.S degree in Electrical and Computer Engineering from North Carolina State University in 2010 and his PhD in Electrical and Computer Engineering from University of Utah in 2017 under the guidance of Prof. David Schurig. His PhD dissertation received the ECE Outstanding Dissertation Award, 2016. He is currently a Postdoctoral Researcher at Integrated Micro-systems Research Lab, Electrical Engineering Department, Princeton University. He was also a Research Project Assistant at Molecular Astronomy Laboratory, Raman Research Institute, Bangalore during 2007-08, where he worked on 10.4 m millimeter-wave radio telescope. His research interests are in electromagnetics, metamaterials, antenna design, integrated circuits, computational imaging, and transformation optics design. He is an active IEEE MTTS volunteer and is serving as the IEEE MTTS YP Region 1-6 coordinator.

No comments yet.