In recent years, electronics engineers have been trying to identify semiconducting materials that could substitute for silicon and enable the further advancement of electronic devices. Two-dimensional (2D) semiconductors, such as molybdenum disulfide (MoS₂), have proved to be among the most promising solutions, as their thinness and resistance to short-channel effects could yield highly performing and smaller electronics.

To create transistors and other electronic components based on 2D materials, however, engineers need to be able to attach electrical connections to them and reliably form ohmic contacts, which allow electrical current to flow freely through the resulting devices. As devices get smaller, however, they also require smaller contacts that have proved to be very difficult to attach to 2D semiconductors.

Researchers at Nanjing University and other institutes in China recently introduced a new strategy to reliably grow ultra-short and low-resistance semimetallic antimony crystal contacts directly on MoS₂

A standard reference thermoelectric module (SRTEM) for objectively measuring thermoelectric module performance has been developed in Korea for the first time. A research team led by Dr. Sang Hyun Park at the Korea Institute of Energy Research developed the world’s second standard reference thermoelectric module, following Japan, and improved its performance by more than 20% compared with existing modules, demonstrating the excellence of Korea’s homegrown technology. The findings are published in the journal ACS Applied Materials & Interfaces.

A thermoelectric module is a device that generates electricity by creating a flow of electrons driven by a temperature difference, with one side becoming cold and the other becoming hot. Conversely, when an electric current is applied to a thermoelectric module, one side cools down while the other side heats up.

Thanks to these characteristics, thermoelectric modules are widely used in applications such as compact camping refrigerators and electronic equipment including computers. In addition, because they are environmentally friendly and well suited to miniaturization, they can be broadly applied to emerging fields such as carbon-free power generation and the space industry, which have recently drawn significant attention.