摘要:
Specific ionic interactions with a sensing material that is electrically coupled with the floating gate of a floating gate-based ion sensitive field effect transistor (FGISFET) may be used to sense a target material. For example, an FGISFET can use (e.g., previously demonstrated) ionic interaction-based sensing techniques with the floating gate of floating gate field effect transistors. The floating gate can serves as a probe and an interface to convert chemical and/or biological signals to electrical signals, which can be measured by monitoring the change in the device's threshold voltage, VT.
摘要:
Specific ionic interactions with a sensing material that is electrically coupled with the floating gate of a floating gate-based ion sensitive field effect transistor (FGISFET) may be used to sense a target material. For example, an FGISFET can use (e.g., previously demonstrated) ionic interaction-based sensing techniques with the floating gate of floating gate field effect transistors. The floating gate can serves as a probe and an interface to convert chemical and/or biological signals to electrical signals, which can be measured by monitoring the change in the device's threshold voltage, VT.
摘要:
Specific ionic interactions with a sensing material that is electrically coupled with the floating gate of a floating gate-based ion sensitive field effect transistor (FGISFET) may be used to sense a target material. For example, an FGISFET can use (e.g., previously demonstrated) ionic interaction-based sensing techniques with the floating gate of floating gate field effect transistors. The floating gate can serves as a probe and an interface to convert chemical and/or biological signals to electrical signals, which can be measured by monitoring the change in the device's threshold voltage, VT.
摘要翻译:可以使用与浮置栅极离子敏感场效应晶体管(FGISFET)的浮动栅极电耦合的感测材料的特定离子相互作用来感测目标材料。 例如,FGISFET可以使用浮动栅极场效应晶体管的浮动栅极(例如,先前证明的)基于离子相互作用的感测技术。 浮动栅极可以用作探针和将化学和/或生物信号转换成电信号的接口,这可以通过监测器件的阈值电压V T T的变化来测量。
摘要:
Specific ionic interactions with a sensing material that is electrically coupled with the floating gate of a floating gate-based ion sensitive field effect transistor (FGISFET) may be used to sense a target material. For example, an FGISFET can use (e.g., previously demonstrated) ionic interaction-based sensing techniques with the floating gate of floating gate field effect transistors. The floating gate can serves as a probe and an interface to convert chemical and/or biological signals to electrical signals, which can be measured by monitoring the change in the device's threshold voltage, VT.
摘要:
Specific ionic interactions with a sensing material that is electrically coupled with the floating gate of a floating gate-based ion sensitive field effect transistor (FGISFET) may be used to sense a target material. For example, an FGISFET can use (e.g., previously demonstrated) ionic interaction-based sensing techniques with the floating gate of floating gate field effect transistors. The floating gate can serves as a probe and an interface to convert chemical and/or biological signals to electrical signals, which can be measured by monitoring the change in the device's threshold voltage, VT.
摘要:
Specific ionic interactions with a sensing material that is electrically coupled with the floating gate of a floating gate-based ion sensitive field effect transistor (FGISFET) may be used to sense a target material. For example, an FGISFET can use (e.g., previously demonstrated) ionic interaction-based sensing techniques with the floating gate of floating gate field effect transistors. The floating gate can serves as a probe and an interface to convert chemical and/or biological signals to electrical signals, which can be measured by monitoring the change in the device's threshold voltage, VT.
摘要:
Methods for preparing an oligomer exhibiting supramolecular extension of π-conjugation are described. The manipulation of intra-oligomeric properties such as π-conjugation length and the precise architecture(s) resulting from inter-oligomeric variations resulting from supramolecular chemistry offers great promise in the design of nanoscale devices. As shown, self-assembly of the supramolecular structure can be induced by causing a molecule: dopant molar ratio to go beyond the predicted theoretical fully-doped molar ratio.
摘要:
Methods for preparing an oligomer exhibiting supramolecular extension of π-conjugation are described. The manipulation of intra-oligomeric properties such as π-conjugation length and the precise architecture(s) resulting from inter-oligomeric variations resulting from supramolecular chemistry offers great promise in the design of nanoscale devices. As shown, self-assembly of the supramolecular structure can be induced by causing a molecule:dopant molar ratio to go beyond the predicted theoretical fully-doped molar ratio.