Ad 7013mzt

The water of breeding tank was made by mixing rearing water and purified water by reverse osmosis, then was treated with peat moss for cultivation. It was adjusted to 24 ± 0.5 °C, 30 ppm, and pH 5.0 ± 0.5, respectively. One day prior to the collection of fertilized eggs, male and female of experimental fishes in a 2 to 1 ratio were put into a glass water tank (45X30X30cm) with a net. The fertilized egg was corrected at the bottom of glass water tank after spawning. Fertilized eggs which confirmed the formation of perivitelline space were measured for size (n = 20) under digital microscope (AD-7013MZT, Dino-Lite, Anmo, Taiwan) and used in this study as experimental samples.

The water of breeding glass water tank (45X30X30 cm) was made by mixing rearing water and purified water by reverse osmosis, then was treated with peat moss for cultivation. It was adjusted to 25 ± 0.5 °C, 80 ppm, and pH 6.0 ± 0.5, respectively. The flower clay pot was used as a spawning ground. The fertilized egg mass was isolated using stainless chopsticks being careful not to break the fertilized eggs. Fertilized eggs which confirmed the formation of perivitelline space were measured for size (n = 20) under digital microscope (AD-7013MZT, Dino-Lite, Anmo, Taiwan) and used in this study as experimental samples.

To obtain electrical and microwave access to the nanodevice and then perform measurements, we used a custom-built probe station, where we mounted the sample with a fixed in-plane angle on top of a variable field module v.2 (VFM2)⁴⁸ . VFM2 uses permanent magnets (rather than electromagnetic coils) to avoid heating during ramping of the field and the associated drift and can apply in-plane magnetic fields of more than ±0.8 Tesla (8000 G) while offering a ∼1 G field resolution.
Moreover, a microscope was needed to make precise contact between the microwave probe and the sample. Therefore, for the vision part of the sample holder, we employed a Dino-Lite AD7013MZT digital hand-held microscope camera with a 5 megapixel sensor and an adjustable polarizer with up to x240 magnification on a fine-focus adjustment stand.
A direct electric current was applied to the devices through a high-frequency bias-T, and the resulting rf oscillations were amplified by a low-noise amplifier and recorded with a high-frequency spectrum analyzer (SA) using a low-resolution bandwidth of 1 MHz. The auto-oscillations were detected electrically in the tens of devices measured, and the results were reproducible from device to device.