The excitation
RF pulse was simultaneously outputted from eight RF coils, and nuclear magnetization of water in PEM was excited. Then, the RF coil received a NMR signal, which is modulated to two waveform components (SI, SQ) which intersect perpendicularly by quadrature detection in a detector. Eight NMR signals are received with eight coils and detected as 16 waveform elements by the modulators. The 16 waveform elements were simultaneously click here acquired using 16 AD converter units, and they were stored in the PC through the AD converter. A permanent magnet with a field strength of about 1.0 T and a central air gap of 100 mm was used in this system. The size of the resulting magnetic field, with a field strength that is uniform within ±50 ppm, is about ∅50 mm. The permanent magnet was designed and produced by NEOMAX Engineering, Ltd. A PEFC and RF coils were inserted in the central part of the magnet. A spin echo sequence was used to acquire a NMR signal. The measurement conditions of the spin echo signal are as follows, and as shown in Fig. 4. The shape of the 90° excitation LGK-974 mw pulse was a rectangle wave at a
frequency of 43 MHz and a pulse width of 40 μs. The 180° pulse used for spin echo measurements was a rectangle wave of 80 μs width. The spin echo time TE was 10 ms. A magnetic field gradient was applied over 1.5 ms in order to attenuate the FID signal. The sampling rate and the number of data points of the AD converter for acquiring the spin echo signal were 20 μs and 2048 points, respectively. The NMR signal was acquired for 40.96 ms. Since
the T1 relaxation time of the PEM at a temperature of 70 °C and a relative humidity of 60% was about 870 ms, the repetition time of a signal acquisition TR was 4 s. In order to acquire a large NMR signal from a relatively small target measurement area using 4-Aminobutyrate aminotransferase the planar surface coil, it is necessary to adjust the amplitude of the excitation pulse appropriately. The relation between the amplitude of the excitation pulse and the echo signal intensity was obtained by analyzing numerically the spatial distributions of the magnetic field induced around the planar surface coil and of the flip angle of nuclear magnetization in order to adjust the excitation pulse to suitable amplitude [15]. The analytical result showed that the flip angle of nuclear magnetization at the center of the coil would become 90° when the amplitude of the excitation pulse is made slightly smaller than the amplitude which reaches the maximum echo signal intensity. Based on the analytical result, the flip angle was adjusted to 90°. A standard PEFC with the structure shown in Fig. 5a and Fig. 5b was used in this research. The area of the PEFC that generates electric power was 50 mm × 50 mm. Hydrogen gas and air were supplied through serpentine type gas channels carved on the separators in that area.