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Researchers have developed new transistors that can be stretched, which could improve the performance of devices that rely on memories.

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Researchers have developed new transistors that can be stretched, which could improve the performance of devices that rely on memories.

The team has designed the artificial synaptic transistor to be integrated into robots or wearables and use artificial intelligence to optimize functions.

The synaptic transistor is a device that can be used in robots or other electronic devices to help improve the performance of memories. The device is made up of transistors that can be stretched, which makes it possible for the device to be twisted and bent while still remaining functional. The team that designed the transistor believes that it could be used in conjunction with artificial intelligence to help optimize the functions of devices that use memories.

The artificial neurons in the device were designed to perform like neurons in the ventral tegmental area.

Excitatory neurotransmitters trigger the activity of other neurons and are associated with enhancing memories, while inhibitory neurotransmitters reduce the activity of other neurons and are associated with weakening memories.

In order to design the synaptic transistor to operate with both synaptic behaviors simultaneously, the researchers drew inspiration from neurons in the ventral tegmental area (VTA). The VTA is a region of the brain that is responsible for modulating mood and motivation. Neurons in the VTA can be either excitatory or inhibitory, depending on the type of neurotransmitter they release. Excitatory neurotransmitters trigger the activity of other neurons and are associated with enhancing memories, while inhibitory neurotransmitters reduce the activity of other neurons and are associated with weakening memories.

The researchers used this knowledge to design their artificial synaptic transistor such that it could perform both functions simultaneously. By doing so, they were able to reduce the number of transistors needed compared to conventional integrated electronics technology. This is an important advantage because it reduces power consumption and increases flexibility.

The researchers used stretchable bilayer semiconductor materials to fabricate the device, allowing it to stretch and twist while in use.

The transistor is mechanically deformable and functionally reconfigurable yet still retains its functions when stretched extensively.

The team used a two-layer semiconductor material that’s just three atoms thick for their device. The bottom layer is made of molybdenum disulfide (MoS2), while the top layer is composed of graphene. This combination of materials allows the device to be both flexible and conductive.

The researchers say that the transistor is mechanically deformable and functionally reconfigurable yet still retains its functions when stretched extensively. In other words, it can be twisted and bent without breaking, and it will still work properly after being stretched.

This is an important development because many current devices are made with rigid materials that can’t be stretched or bent without breaking. This means that they can’t be used in applications where flexibility is required, such as wearable devices or robotics.

The new transistor could open up a whole range of new possibilities for flexible electronics. For example, it could be used to create bendable displays or stretchable sensors. It could also be used in biomedical applications, such as implantable devices that need to move with the body.

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