Fet - Recon

The Recon FET is poised to become the cornerstone of —tiny, low-cost, low-power nodes that detect chemical, biological, or radiological threats passively. Within 5–10 years, fully integrated systems-on-chip (SoC) with:

| Type | Sensing Target | Functionalization | Example Application | |------------------|------------------------|---------------------------------------|-------------------------------| | | pH, ions | Si₃N₄ or Al₂O₃ passivation | Blood pH monitoring | | Enzyme FET | Glucose, urea | Immobilized enzyme (e.g., glucose oxidase) | Wearable diabetes sensor | | DNA FET | DNA strands | Single-stranded DNA probes | Rapid pathogen detection | | Gas FET | NO₂, NH₃, H₂S | Metal oxide or polymer film | Environmental surveillance | | Graphene FET | Single molecules | CVD graphene with linker molecules | Ultra-sensitive biosensing | recon fet

RFETs replace traditional chemical doping with . The Recon FET is poised to become the

Many reconfigurable designs utilize silicon nanowires or SiGe heterostructures to achieve the symmetric performance needed for high-speed switching. Reconfigurability makes it harder for malicious actors to

Reconfigurability makes it harder for malicious actors to "reverse engineer" a chip’s function because the logic gates can change their identity after the chip is manufactured.