Graphene sensors: introduction and market status

Researchers from Lithuania's Center for Physical Sciences and Technology and Kaunas University of Technology have reported a novel hybrid magnetic sensor that combines the unique properties of manganite and graphene to measure both the magnitude and direction of a magnetic field. 

The schematic drawing of the hybrid sensor. Image from: Scientific Reports

The sensor consists of a nanostructured manganite film to detect the magnetic field strength and a graphene layer to determine the angle between the magnetic field and the sensor plane. This dual sensor approach increases sensitivity over a wide range of magnetic field strengths and provides directional information, making it ideal for applications such as object positioning and navigation. 

A team led by researchers at the University of California San Diego Jacobs School of Engineering has been awarded a $5 million grant from the National Institutes of Health (NIH) to develop next-generation brain implants that can record brain activity with unprecedented resolution and speed across different brain regions. The technology aims to advance neuroscience by providing clearer insights into brain function and overcome key limitations of existing brain-monitoring devices.

The project builds on the team’s previous work on a neural implant that captures real-time information about activity deep inside the brain while sitting on its surface. This thin, transparent and flexible implant, called Neuro-clear, houses a dense array of graphene electrodes, offering a powerful alternative to current neural interface technologies. Conventional surface arrays are minimally invasive but struggle to detect signals from deeper brain structures. On the other hand, electrode arrays with penetrating needles provide deeper access but often lead to inflammation and scarring, which can degrade signal quality over time. The Neuro-clear technology developed at UC San Diego combines the strengths of both approaches, allowing it to achieve high-resolution, long-term neural recording with minimal invasiveness.

Researchers from the UK's University of Cambridge and China's Capital Medical University and Beihang University have developed a washable, skin-compatible smart garment sleep monitoring system that uses graphene sensors to capture local skin strain signals under weak device–skin coupling conditions without positioning or skin preparation requirements. 

The monitoring of sleep behavior begins by detecting subtle vibrations at the extrinsic laryngeal muscle, which are induced by physiological vibrations emanating from various anatomical locations such as the velum, oropharynx, tongue, and epiglottis. These vibrations are then captured by a six-channel strain sensor array printed onto the collar of a garment. The signals from the channel with the strongest response are processed by a deep learning neural network, SleepNet, which is designed for recognizing and analyzing sleep patterns. Image from PNAS

The comfortable, washable ‘smart pajamas' can monitor sleep disorders such as sleep apnea at home, without the need for sticky patches, cumbersome equipment or a visit to a specialist sleep clinic.

Researchers from AMO, Graphenea and RWTH Aachen University have, as part of the European experimental pilot line for electronic and optoelectronic devices based on graphene and related two-dimensional (2D) materials, namely the Experimental Pilot Line (2D-EPL) project, reported the results obtained during the first and third multi-project wafer (MPW) runs completed at the end of 2022 (MPW run 1) and 2023 (MPW run 3). 

The Experimental Pilot Line (2D-EPL) project, that aims to advance the widespread commercialization of electronic devices based on graphene, published the new report that summarizes the results of two multi-project wafer (MPW) runs, utilizing electrical and spectroscopic characterization to demonstrate the high quality of production in the 2D-EPL. MPW run 1 was intended mainly for graphene-based sensors, in particular chemical and biosensors, while MPW run 3 focused on graphene electronics. 

Researchers at Penn State and Hebei University of Technology recently developed stretchable thermoelectric porous graphene foam-based materials via facile laser scribing for self-powered decoupled strain and temperature sensing. The new sensor material enables precise and separate measurement of temperature and physical strain, a vital development for biosensors, for accurately tracking various health signals.

The team’s innovation is based on laser-induced graphene (LIG), created by using a laser to convert carbon-rich materials, such as plastic or wood, into graphene by heating their surfaces. This simple and scalable process is already used in a variety of applications, including gas sensors and electrochemical detectors. However, the scientists believe they have uncovered a new, critical property of LIG that makes it ideal for multi-signal sensing.

Researchers from Penn State recently developed a portable and wireless device to simultaneously detect SARS-CoV-2, the virus that causes COVID-19, and vitamin C, a critical nutrient that helps bolster infection resistance, by integrating commercial transistors with printed laser-induced graphene.  

By simultaneously detecting the virus and vitamin C levels, the test could help individuals and their health care providers decide on more effective treatment options, the researchers said. For example, someone with low vitamin C levels may benefit from a supplemental boost, while someone with normal or high vitamin C levels may need to consider other options.  

A research team, led by the University of Southampton and UWE Bristol, has developed graphene-based wearable electronic textiles (e-textiles) that are sustainable and biodegradable. In their new study, the team (which also involved the universities of Exeter, Cambridge, Leeds and Bath), describes and tests a new sustainable approach for fully inkjet-printed, eco-friendly e-textiles named 'Smart, Wearable, and Eco-friendly Electronic Textiles', or 'SWEET'.

a) Schematic of two important vital signs: skin surface temperature and heart rate of the human body. b) Schematic of wearable e-textiles as gloves. c) Schematic of the position of wearable textile electrode on human skin surface contact. d) Schematic of the textile electrode. e) Schematic of the textile electrodes' composition. f) Schematic of sustainable design approach for wearable e-textiles, including sustainable materials, sustainable manufacturing, and sustainability assessment. Image from: Energy and Environmental Materials

E-textiles are usually embedded with electrical components, such as sensors, batteries or lights. They might be used in fashion, for performance sportwear, or for medical purposes as garments that monitor people's vital signs. Such textiles need to be durable, safe to wear and comfortable, but also, in an industry which is increasingly concerned with clothing waste, they need to be easy on the environment when no longer required.

Versarien has launched a new biosensor chip utilizing novel graphene barristor sensor platform technology. These graphene barristor devices, developed in South Korea by A Barristor Company (ABC), will utilize chemical vapor deposition (CVD) grown graphene, that is produced under a Versarien license. Versarien has signed a distribution agreement with ABC to distribute the products in the UK and Europe.

A barristor (triode device) is a new type of graphene‐based transistor with a Schottky barrier between graphene and silicon. The current modulation is amplified more than 10,000 times compared to graphene field‐effect transistors (GFET), enabling the barristor transistors to overcome many GFET limitations.

Researchers from Friedrich Schiller University Jena, CNM Technologies, NOXXON Pharma, APTARION Biotech and Radboud University Medical Center have developed graphene field effect transistor (GFET) sensors based on van der Waals (vdW) heterostructures of single-layer graphene layered with a molecular ≈1 nm thick carbon nanomembrane (CNM).

1 / 1Schematic illustration of the fabrication steps of the l-AP/PEG-CNM GFET sensors. Credit: Advanced Materials 

The CNM acts as an ultrathin molecular interposer between the graphene channel and the analyte and allows bio-functionalization without impairing the graphene properties including its charge carrier mobility. 

A team of Spain-based researchers has developed a highly sensitive detector for identifying molecules via their infrared vibrational “fingerprint”. The new detector converts incident infrared light into ultra-confined "nanolight" in the form of phonon polaritons within the detector´s active area. This mechanism serves two crucial purposes: it improves the detector's overall sensitivity and enhances the vibrational fingerprint of nanometer-thin molecular layer placed on top of the detector, allowing this molecular fingerprint to be more easily detected and analyzed. 

The compact design and room-temperature operation of the device hold promise for developing ultra-compact platforms for molecular and gas sensing applications.