電気学会論文誌Ｅ（センサ・マイクロマシン部門誌） 133 巻, 11 号

機能性ナノ界面を有するバイオトランジスタ

The convergence of nano-/bio- technology with biomedicine has occurred tremendously over the last few decades. In particular, next-generation biosensors offer great potential to treat serious medical problems in the fields of diagnostics, therapy, and drug delivery. Advantageously, an electrical biosensor platform composed of target-capturing element and semiconductor device as a signal transducer is compatible with a high-throughput analysis via miniaturization and integration into a small chip for decentralized bioanalytical applications. So far, we have successfully achieved potentiometric biosensing based mostly on a direct readout of innately charged biomolecules using field effect transistor (FET). Highly specific molecular recognition is available by constructing engineered biointerface on the sensor. Furthermore, the potentiometric technique provides the ability to perform label-free and real-time detection for various biomolecules. These features would help to promote personalized medicine for individual patients in the future. Here we describe fundamental aspects of electrical biosensing and review recent developments of the FET-based biotransistors.

剥離性基板上へのPZT薄膜作製とその密着特性

PZT (Pb(Zr_x,Ti_1-x)O₃) thin film capacitors using Nano-transfer method has been developed for the fabrication technology of smaller capacitors. The adhesion strength of Pt to SiO₂ was shown to be important among process factors. The adhesion force was shown to be originated from the material diffusion in the crystallization process mainly by the observation of TEM and XPS analysis. In this paper, diffusion of ingredients of PZT which is supposed to be one of the factors of the variation was investigated. It was confirmed that diffusion of Pb certainly occurs and this diffusion reinforces the adhesion strength in accordance with the Pt thickness. It is concluded that the diffusion is surely one of the factors of the variation of the adhesion strength.

熱音響超音波源を用いた単パルス超音波近接覚センサ

This paper proposes an ultrasonic proximal distance sensor, which uses a thermoacoustic device as a transmitter. Thermoacoustic transmitter doesn't have mechanical vibration and resonant frequency, thus it can emit a single-pulse ultrasonic, which width is under 10 µsec. Using a single-pulse ultrasonic, overlap of transmitting and receiving term is very short and it can measure very short rage such as 3 mm with excellent accuracy.

高い電流利得を有するVibrating-Body Field-Effect Transistorの提案

In this study, we propose a high current gain Vibrating-Body Field-Effect Transistor (Vertical VB-FET). The device has a specific structure in which drain, channel, and source electrodes of the FET are stacked. Since the current flow direction in the device is perpendicular to the wafer surface, the W/L_c (W : channel width, L_c : channel length) value is increased and improved the properties of Vertical VB-FET. In order to evaluate the dynamic properties, we derived the Lagrange's function and the dissipation function from a resistance-capacitance ladder equivalent circuit. Using these functions, we calculated the transconductance and current gain for a ring structured VB-FET. As a result, the estimated transconductance of the Vertical VB-FET was 1.81×10^-2mS, whereas 1.78×10^-4mS for the conventional type VB-FET with the same structure dimensions. The current gain of the vertical VB-FET also increased 15 times as large as the conventional one.

車載インバータ向けダイレクトセンシング電流センサの開発

This paper describes a Direct Sensing Current Transformer (DSCTs) for the vehicle inverter system. The DSCTs was designed to measure the motor current without magnetic cores and consist of a Hall-IC and a detection wiring. The detection wiring was arranged on a power wiring of a cooling fin plate of the power module. The detection current generates the mirror current in the cooling fin plate. The mirror current generates a causes of detection error and changes the detection flux depending on the detection current frequency. The Technology of the wiring layout of Low-detection error of DSCTs in the power module is presented.