Your search keyword '"Alexander Deutschinger"' showing total 5 results

1. Performance of an Electrothermal MEMS Cantilever Resonator with Fano-Resonance Annoyance under Cigarette Smoke Exposure

Author

Andi Setiono, Michael Fahrbach, Alexander Deutschinger, Ernest J. Fantner, Christian H. Schwalb, Iqbal Syamsu, Hutomo Suryo Wasisto, and Erwin Peiner

Subjects

electrothermal piezoresistive cantilever sensors, parasitic feedthrough subtraction, particle mass concentration measurement, cigarette smoke exposure, Chemical technology, TP1-1185

Abstract

An electrothermal piezoresistive cantilever (EPC) sensor is a low-cost MEMS resonance sensor that provides self-actuating and self-sensing capabilities. In the platform, which is of MEMS-cantilever shape, the EPC sensor offers several advantages in terms of physical, chemical, and biological sensing, e.g., high sensitivity, low cost, simple procedure, and quick response. However, a crosstalk effect is generated by the coupling of parasitic elements from the actuation part to the sensing part. This study presents a parasitic feedthrough subtraction (PFS) method to mitigate a crosstalk effect in an electrothermal piezoresistive cantilever (EPC) resonance sensor. The PFS method is employed to identify a resonance phase that is, furthermore, deployed to a phase-locked loop (PLL)-based system to track and lock the resonance frequency of the EPC sensor under cigarette smoke exposure. The performance of the EPC sensor is further evaluated and compared to an AFM-microcantilever sensor and a commercial particle counter (DC1100-PRO). The particle mass–concentration measurement result generated from cigarette-smoke puffs shows a good agreement between these three detectors.

Published

2021

2. Atomic Force Microscopy Imaging in Turbid Liquids: A Promising Tool in Nanomedicine

Author

Michael Leitner, Hannah Seferovic, Sarah Stainer, Boris Buchroithner, Christian H. Schwalb, Alexander Deutschinger, and Andreas Ebner

Subjects

piezoresistive cantilever, self-sensing, self-actuating, electrical readout, platelet, all electric AFM, Chemical technology, TP1-1185

Abstract

Tracking of biological and physiological processes on the nanoscale is a central part of the growing field of nanomedicine. Although atomic force microscopy (AFM) is one of the most appropriate techniques in this area, investigations in non-transparent fluids such as human blood are not possible with conventional AFMs due to limitations caused by the optical readout. Here, we show a promising approach based on self-sensing cantilevers (SSC) as a replacement for optical readout in biological AFM imaging. Piezo-resistors, in the form of a Wheatstone bridge, are embedded into the cantilever, whereas two of them are placed at the bending edge. This enables the deflection of the cantilever to be precisely recorded by measuring the changes in resistance. Furthermore, the conventional acoustic or magnetic vibration excitation in intermittent contact mode can be replaced by a thermal excitation using a heating loop. We show further developments of existing approaches enabling stable measurements in turbid liquids. Different readout and excitation methods are compared under various environmental conditions, ranging from dry state to human blood. To demonstrate the applicability of our laser-free bio-AFM for nanomedical research, we have selected the hemostatic process of blood coagulation as well as ultra-flat red blood cells in different turbid fluids. Furthermore, the effects on noise and scanning speed of different media are compared. The technical realization is shown (1) on a conventional optical beam deflection (OBD)-based AFM, where we replaced the optical part by a new SSC nose cone, and (2) on an all-electric AFM, which we adapted for measurements in turbid liquids.

Published

2020

3. In-Plane and Out-of-Plane MEMS Piezoresistive Cantilever Sensors for Nanoparticle Mass Detection

Author

Andi Setiono, Maik Bertke, Wilson Ombati Nyang’au, Jiushuai Xu, Michael Fahrbach, Ina Kirsch, Erik Uhde, Alexander Deutschinger, Ernest J. Fantner, Christian H. Schwalb, Hutomo Suryo Wasisto, and Erwin Peiner

Subjects

mems piezoresistive cantilever sensors, dynamic mode, carbon nanoparticle, particle mass measurement, Chemical technology, TP1-1185

Abstract

In this study, we investigate the performance of two piezoresistive micro-electro-mechanical system (MEMS)-based silicon cantilever sensors for measuring target analytes (i.e., ultrafine particulate matters). We use two different types of cantilevers with geometric dimensions of 1000 × 170 × 19.5 µm3 and 300 × 100 × 4 µm3, which refer to the 1st and 2nd types of cantilevers, respectively. For the first case, the cantilever is configured to detect the fundamental in-plane bending mode and is actuated using a resistive heater. Similarly, the second type of cantilever sensor is actuated using a meandering resistive heater (bimorph) and is designed for out-of-plane operation. We have successfully employed these two cantilevers to measure and monitor the changes of mass concentration of carbon nanoparticles in air, provided by atomizing suspensions of these nanoparticles into a sealed chamber, ranging from 0 to several tens of µg/m3 and oversize distributions from ~10 nm to ~350 nm. Here, we deploy both types of cantilever sensors and operate them simultaneously with a standard laboratory system (Fast Mobility Particle Sizer, FMPS, TSI 3091) as a reference.

Published

2020

4. Performance of an Electrothermal MEMS Cantilever Resonator with Fano-Resonance Annoyance under Cigarette Smoke Exposure

Author

Ernest J. Fantner, Andi Setiono, Hutomo Suryo Wasisto, Iqbal Syamsu, Alexander Deutschinger, Michael Fahrbach, Erwin Peiner, and Christian H. Schwalb

Subjects

Cantilever, Materials science, particle mass concentration measurement, Feedthrough, 02 engineering and technology, TP1-1185, 01 natural sciences, Biochemistry, Article, Analytical Chemistry, Resonator, Sensitivity (control systems), Electrical and Electronic Engineering, Instrumentation, Microelectromechanical systems, business.industry, Chemical technology, 010401 analytical chemistry, Detector, Smoking, parasitic feedthrough subtraction, Fano resonance, Micro-Electrical-Mechanical Systems, 021001 nanoscience & nanotechnology, Atomic and Molecular Physics, and Optics, 0104 chemical sciences, Phase-locked loop, electrothermal piezoresistive cantilever sensors, Optoelectronics, cigarette smoke exposure, 0210 nano-technology, business

Abstract

An electrothermal piezoresistive cantilever (EPC) sensor is a low-cost MEMS resonance sensor that provides self-actuating and self-sensing capabilities. In the platform, which is of MEMS-cantilever shape, the EPC sensor offers several advantages in terms of physical, chemical, and biological sensing, e.g., high sensitivity, low cost, simple procedure, and quick response. However, a crosstalk effect is generated by the coupling of parasitic elements from the actuation part to the sensing part. This study presents a parasitic feedthrough subtraction (PFS) method to mitigate a crosstalk effect in an electrothermal piezoresistive cantilever (EPC) resonance sensor. The PFS method is employed to identify a resonance phase that is, furthermore, deployed to a phase-locked loop (PLL)-based system to track and lock the resonance frequency of the EPC sensor under cigarette smoke exposure. The performance of the EPC sensor is further evaluated and compared to an AFM-microcantilever sensor and a commercial particle counter (DC1100-PRO). The particle mass–concentration measurement result generated from cigarette-smoke puffs shows a good agreement between these three detectors.

Published

2021

5. In-Plane and Out-of-Plane MEMS Piezoresistive Cantilever Sensors for Nanoparticle Mass Detection

Author

Erik Uhde, Erwin Peiner, Maik Bertke, Ernest J. Fantner, Wilson Ombati Nyang’au, Michael Fahrbach, I. Kirsch, Hutomo Suryo Wasisto, Jiushuai Xu, Alexander Deutschinger, Christian H. Schwalb, Andi Setiono, and Publica

Subjects

Cantilever, Materials science, Nanoparticle, Bimorph, 02 engineering and technology, Bending, particle mass measurement, lcsh:Chemical technology, 01 natural sciences, Biochemistry, Article, carbon nanoparticle, Analytical Chemistry, lcsh:TP1-1185, Electrical and Electronic Engineering, Instrumentation, Microelectromechanical systems, Resistive touchscreen, business.industry, 010401 analytical chemistry, mems piezoresistive cantilever sensors, 021001 nanoscience & nanotechnology, Piezoresistive effect, dynamic mode, Atomic and Molecular Physics, and Optics, 0104 chemical sciences, Optoelectronics, Particle, 0210 nano-technology, business

Abstract

In this study, we investigate the performance of two piezoresistive micro-electro-mechanical system (MEMS)-based silicon cantilever sensors for measuring target analytes (i.e., ultrafine particulate matters). We use two different types of cantilevers with geometric dimensions of 1000 &times, 170 &times, 19.5 &micro, m3 and 300 &times, 100 &times, 4 &micro, m3, which refer to the 1st and 2nd types of cantilevers, respectively. For the first case, the cantilever is configured to detect the fundamental in-plane bending mode and is actuated using a resistive heater. Similarly, the second type of cantilever sensor is actuated using a meandering resistive heater (bimorph) and is designed for out-of-plane operation. We have successfully employed these two cantilevers to measure and monitor the changes of mass concentration of carbon nanoparticles in air, provided by atomizing suspensions of these nanoparticles into a sealed chamber, ranging from 0 to several tens of &micro, g/m3 and oversize distributions from ~10 nm to ~350 nm. Here, we deploy both types of cantilever sensors and operate them simultaneously with a standard laboratory system (Fast Mobility Particle Sizer, FMPS, TSI 3091) as a reference.

Published

2020