Gravitoelectric effect in the condensed magnetic sea

IF 2.5 Q3 QUANTUM SCIENCE & TECHNOLOGY IET Quantum Communication Pub Date : 2023-12-22 DOI:10.1049/qtc2.12082
Jong hoon Lee
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Abstract

Trapped graviton in magnetic seas induces magnetic fields as a function of time in the additional space. The Soon Joe generator made the Graviton set behave as free relativistic quantum particles. The current and voltage generated when the LED was turned on and off were measured five times. Measurements were made in units of 1/1000 of a second, and the measured data were summed. In the LED off-state, the average current was −2.87E-03 (A), and the average voltage was −1.44E-01 (V) in VH and 6.83E-01 (V) in VL. The average current in the LED on-stage was −4.28E-03, the VH was 2.14E-01, and the VL was 6.57E-01. The voltage difference was −8.27E-01 in the off-stage and −8.71E-01 in the on-stage. Less current was generated in the off-stage, with less voltage difference. In this experiment, we confirmed that the graviton generates the current, and with the photons, more current is generated. This explains why the interactive induction protocol of gravitons or photons can be used to experiment with the magnetic field's ability to communicate or transfer energy with relativistic quantum particles. The gravitoelectric effect explains the photoelectric effect elements, and graviton has induced electricity as a physical entity in the magnetic sea.

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凝聚磁海中的引力场效应
被困在磁海中的引力子会在额外空间中诱导出与时间相关的磁场。顺乔发生器使引力子组表现为自由相对论量子粒子。对 LED 开启和关闭时产生的电流和电压进行了五次测量。测量以 1/1000 秒为单位,并对测量数据进行求和。在 LED 关闭状态下,VH 的平均电流为 -2.87E-03 (A),平均电压为 -1.44E-01 (V),VL 为 6.83E-01 (V)。LED 开启阶段的平均电流为 -4.28E-03,VH 为 2.14E-01,VL 为 6.57E-01。关断阶段和开启阶段的电压差分别为-8.27E-01 和-8.71E-01。关断阶段产生的电流较小,电压差也较小。在这个实验中,我们证实引力子产生了电流,而光子则产生了更多的电流。这就解释了为什么引力子或光子的交互感应协议可以用来实验磁场与相对论量子粒子沟通或传递能量的能力。引力子效应解释了光电效应元素,引力子在磁海中诱导出了电这一物理实体。
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