U. Haak scite author profile

A standard complementary metal‐oxide‐semiconductor (CMOS) process is successfully modified to encompass the preparation of suspended TiN membranes of only 50 nm thickness from one of the metal layer stacks of the back‐end flow. The layers’ elastomechanical constants are determined with high precision by laser Doppler vibrometry. Residual stress gradients are compensated and a state of moderate tensile strain is introduced into the membranes. Test systems of TiN beams and bridges operating in a capacitive coupling scheme are optimized for the low voltage range attainable with CMOS devices. TiN actuators are particularly suited for applications in biotechnology like sensing of pressure or viscosity in microfluidic devices due to their high corrosion resistance in liquid electrolyte surroundings. The established inclusion of the process in a CMOS pilot line enables the production of cheap and monolithically integrated microelectromechanical systems (MEMS) and bio‐microelectromechanical systems (BioMEMS) devices.

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Sensing glucose concentrations at GHz frequencies with a fully embedded Biomicro-electromechanical system (BioMEMS)

Birkholz

Ehwald

Basmer

et al. 2013

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The progressive scaling in semiconductor technology allows for advanced miniaturization of intelligent systems like implantable biosensors for low-molecular weight analytes. A most relevant application would be the monitoring of glucose in diabetic patients, since no commercial solution is available yet for the continuous and drift-free monitoring of blood sugar levels. We report on a biosensor chip that operates via the binding competition of glucose and dextran to concanavalin A. The sensor is prepared as a fully embedded micro-electromechanical system and operates at GHz frequencies. Glucose concentrations derive from the assay viscosity as determined by the deflection of a 50 nm TiN actuator beam excited by quasi-electrostatic attraction. The GHz detection scheme does not rely on the resonant oscillation of the actuator and safely operates in fluidic environments. This property favorably combines with additional characteristics-(i) measurement times of less than a second, (ii) usage of biocompatible TiN for bio-milieu exposed parts, and (iii) small volume of less than 1 mm-to qualify the sensor chip as key component in a continuous glucose monitor for the interstitial tissue.

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U. Haak

SiGe HBT technology with f<inf>T</inf>/f<inf>max</inf> of 300GHz/500GHz and 2.0 ps CML gate delay

A 0.13 $\mu{\hbox {m}}$ SiGe BiCMOS Technology Featuring f$_{T} $/f$_{\max}$ of 240/330 GHz and Gate Delays Below 3 ps

Novel collector design for high-speed SiGe:C HBTs

Ultrathin TiN Membranes as a Technology Platform for CMOS‐Integrated MEMS and BioMEMS Devices

Sensing glucose concentrations at GHz frequencies with a fully embedded Biomicro-electromechanical system (BioMEMS)

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