Since October 2007, we have been conducting rigorous scientific research on the unexplained “power” of a pyramidal structure (PS). From our research results so far, we could classify the pyramid effects by the PS in...Since October 2007, we have been conducting rigorous scientific research on the unexplained “power” of a pyramidal structure (PS). From our research results so far, we could classify the pyramid effects by the PS into the following two types. (i) The pyramid effects in which the PS converted the test subject’s unexplained energy to affect biosensors when the test subject entered the PS and meditated. (ii) The pyramid effects in which the potential power of the PS affect</span><span style="font-family:Verdana;">ed</span><span style="font-family:Verdana;"> biosensors if the test subject ha</span><span style="font-family:Verdana;">d</span><span style="font-family:Verdana;"> not been inside the PS for at least 20 days and the test subject’s unexplained energy was excluded. In this paper, we report new results regarding (ii). As a result of dividing a year according to the four seasons of winter, spring, summer, and autumn and analyzing the pyramid effect of each period, the following points were found. 1) There was a pyramid effect without seasonal variation. The pyramid effect on the lower and upper layers was different throughout the year for the biosensors placed at the PS apex in two layers, regardless of the season. 2) There was a pyramid effect with seasonal variation. The value of the psi index, which indicates the magnitude of the pyramid effect, changed as the seasons changed, while different pyramid effects were maintained on the lower and upper layers. Regarding the change in the pyramid effect depending on the season, the psi index in summer was larger than that in winter in both the lower and upper layers. From these results, we found that there are two types of potential power at the PS apex: seasonal potential power and non-seasonal potential power.展开更多
Since October 2007, we have been conducting rigorous scientific research on the unexplained “power” of a pyramidal structure (PS). From our research results so far, we could classify pyramid effects by the PS into t...Since October 2007, we have been conducting rigorous scientific research on the unexplained “power” of a pyramidal structure (PS). From our research results so far, we could classify pyramid effects by the PS into the following two types: (i) the pyramid effects due to the potential power of the PS and (ii) the pyramid effects due to the influence of the test subject meditating inside the PS. We have been using edible cucumber sections as the biosensors. The pyramid effect existence was clarified by measuring and analyzing the concentration of volatile components released from the biosensors. The biosensors were arranged as a pair: one member of the pair was placed at the PS apex and the other was placed at the calibration control point 8.0 m away from the PS. In this paper, we report a new discovery regarding the type (i) pyramid effects. We discovered a phenomenon considered to be entanglement between the biosensor pairs detecting the pyramid effects. In other words, the biosensors at the PS apex, which were affected by the potential power of the PS, affected the biosensors at the calibration control point. We also confirmed that the effects on the biosensors placed at the calibration control point were not due to the potential power of the PS. Furthermore, we showed that the magnitude of the effect of entanglement changed with the seasons. We expect that our research results will be widely accepted in the future and will become the foundation for a new research field in science, with a wide range of applications.展开更多
There have been various traditions and books which describe a so-called “pyramid power”, but there have been almost no reliable academic studies and no statistically significant data about it. We have continued scie...There have been various traditions and books which describe a so-called “pyramid power”, but there have been almost no reliable academic studies and no statistically significant data about it. We have continued scientifically rigorous experiments using biosensors to elucidate unexplained functions of a pyramidal structure (PS) since 2007. We used edible cucumber sections as biosensors and measured the concentrations of gas emitted from the sections by a technique developed by our group. From them we have demonstrated with high statistical accuracy the existence of the “pyramid power”, which was often recognized as having no scientific basis. We reached two conclusions from the work. 1) The PS converted the unconsciousness of a human (the test subject) more than 6 km away to energy detectable by the biosensors (1% significance). 2) The PS accumulated the influence that a human (the test subject) had when meditating within the PS. Then the PS converted the influence into the energy detectable by the biosensors (10-3% significance). These two conclusions showed that the functions of the PS were detected when “the PS and a human were related”. On the other hand, we hypothesized that the potential power of the PS could be detected even when “the PS and a human were not related”. In this paper, our purpose is to verify the existence of the potential power of the PS alone by experiment when “the PS and a human were not related”. The following three results were obtained by experiment. 1) The presence of the potential power of the PS was demonstrated with 1% significance. 2) The potential power of the PS changed in value between summer and winter, and it was clear that the non-contact effect on the biosensors was larger in summer and smaller in winter. 3) The potential power of the PS affected only the biosensors placed at the PS apex, and did not affect the biosensors placed at the calibration control point 8 m away from the PS. This paper is the first report in the world to show this type of effect by scientific measurements. Our research results may open up a new science field of “pyramid power”, from which we expect further development of fields applying this “pyramid power”.展开更多
Research on “pyramid power” began in the late 1930s. To date, many documents on “pyramid power” have been published. We have been conducting scientific research on the unexplained “power” of a pyramidal structur...Research on “pyramid power” began in the late 1930s. To date, many documents on “pyramid power” have been published. We have been conducting scientific research on the unexplained “power” of a pyramidal structure (PS) since October 2007. The research focuses on the detection of a non-contact effect of the unexplained “power” of the PS on biosensors (i.e., edible cucumber sections of Cucumis sativus “white spine type”) placed at the top of the PS. In this paper, in particular, we compared the non-contact effect of upper and lower biosensors placed in two layers on the PS apex, and we analyzed the difference of the non-contact effect due to the difference in the layers. The magnitude of the non-contact effect was represented by the calibrated psi index Ψ(E-CAL) calculated from gas concentrations emitted from the biosensors. A method to determine the presence or absence of the non-contact effect by analyzing the gas concentrations was developed by the International Research Institute (IRI). Ψ(E-CAL), which represents the magnitude of the non-contact effect, was the average value of the respective non-contact effect of the upper and lower biosensors stacked in two layers on the PS apex. We conducted the analysis on the assumption that the non-contact effect on the upper and lower biosensors might be different. Therefore, we considered that upper and lower biosensor calibration was required for Ψ(E-CAL), and we introduced a new calibrated psi index Ψ(E-CAL)Layer. Scientifically rigorous experiments to date have detected Ψ(E-CAL) with statistical significance and have demonstrated potential power of the PS (p = 6.0 × 10-3;Welch’s t-test, two-tails, the following p values are also the Welch’s t-test values). Based on data demonstrating the potential power of the PS, we analyzed the non-contact effects on the upper and lower biosensors of the PS apex. We obtained a surprising result that the non-contact effect on the upper biosensors (farther from the PS) was larger than that on the lower biosensors (closer to the PS) (p = 4.0 × 10-7). This suggested that the characteristic of the potential power of the PS, which is considered to exist near the PS apex, is distinctive. We also found that the non-contact effect due to the potential power of the PS varies with the season, and is large in summer and small in winter. In our discussion, we proposed a model that could theoretically explain the experimental results that the non-contact effect on the upper biosensors at the PS apex is larger than the lower biosensors. In proposing this model, we assumed that there were two different types of potential power at the PS apex and that the biosensors had two different gas-generating reactions. In a simulation using the model, the experimental results were well approximated in which the non-contact effect on the biosensors differs depending on the difference between the upper and lower layers. The results of this paper are the world’s first to prove aspects of the “pyramid power” through scientifically rigorous experiments and analysis. These results will become a new field of science in the future, and their broad applications are expected.展开更多
【目的】基因聚合是实现水稻稻瘟病广谱抗性的有效途径之一。通过构建粳稻背景下不同双基因聚合系,利用长江下游粳型稻瘟病菌(Magnaporthe oryzea)菌株评价其抗性效应并解析其抗性效应产生的构成因子,为长江下游粳稻抗稻瘟病育种提供广...【目的】基因聚合是实现水稻稻瘟病广谱抗性的有效途径之一。通过构建粳稻背景下不同双基因聚合系,利用长江下游粳型稻瘟病菌(Magnaporthe oryzea)菌株评价其抗性效应并解析其抗性效应产生的构成因子,为长江下游粳稻抗稻瘟病育种提供广谱抗性基因组合模式和种质资源。【方法】以粳稻07GY31为背景的Piz基因座不同复等位基因(Pigm、Pi40、Pi9、Pi2、Pizt和Piz)单基因系为核心,利用不完全NCII交配设计,分别与其他广谱抗性基因(Pi1、Pi54和Pi33)单基因系杂交,经分子标记辅助选择和农艺性状筛选,共构建18种不同基因组合的双基因聚合系。2019年利用长江下游粳稻种植区采集、分离的109个稻瘟病代表性菌株进行苗瘟、穗瘟人工接种鉴定及不同病圃的自然诱发鉴定,评价不同双基因聚合系的抗性效应,并分析双基因聚合系抗性效应的构成因子。【结果】Genotyping by sequencing(GBS)分析表明所构建的双基因聚合系均具有较高的背景恢复率,分布于97.08%(PPL^(Piz/Pi33))—99.08%(PPL^(Pigm/Pi1))。表明除了目标基因区域不同外,所有双基因聚合系的遗传背景几乎完全与受体亲本07GY31一致。同时人工接菌鉴定表明绝大部分双基因聚合系苗瘟和穗瘟抗性水平都优于单基因系。其中苗瘟抗性效应较好的聚合系分别为PPL^(Pigm/Pi1)、PPL^(Pigm/Pi54)、PPL^(Pigm/Pi33)、PPL^(Pi9/Pi33)、PPL^(Pi9/Pi54)、PPL^(Pi40/Pi54)、PPL^(Pi40/Pi33)、PPL^(Pi40/Pi1)、PPL^(Pi9/Pi1),而穗瘟抗性效应较好的聚合系分别为PPL^(Pigm/Pi1)、PPL^(Pigm/Pi54)、PPL^(Pigm/Pi33)、PPL^(Pi40/Pi33)、PPL^(Pi40/Pi54)、PPL^(Pi40/Pi1)、PPL^(Pizt/Pi33)。不同抗性基因聚合后产生不同的效应,其中互补效应高且能有效表达是提高双基因聚合系苗瘟和穗瘟抗性的关键因子。双基因聚合系PPL^(Pigm/Pi1)、PPL^(Pigm/Pi54)和PPL^(Pigm/Pi33)在苗瘟和穗瘟的人工接种,以及在不同病圃的自然诱发鉴定中均表现稳定的广谱抗性,同时,农艺性状调查结果也表明这3个双基因聚合系的基本农艺性状与轮回亲本07GY31基本一致,因此,基因组合Pigm/Pi1、Pigm/Pi54和Pigm/Pi33是适于长江下游粳稻的广谱抗性基因组合模式。【结论】抗性基因的组合方式影响聚合系的抗性水平,互补效应高且能有效表达是粳型双基因聚合系抗性效应提高的关键因子。本研究构建的双基因聚合系及其抗性效应分析为长江下游广谱稻瘟病抗性粳稻品种的精准培育提供了种质资源和理论支撑。展开更多
文摘Since October 2007, we have been conducting rigorous scientific research on the unexplained “power” of a pyramidal structure (PS). From our research results so far, we could classify the pyramid effects by the PS into the following two types. (i) The pyramid effects in which the PS converted the test subject’s unexplained energy to affect biosensors when the test subject entered the PS and meditated. (ii) The pyramid effects in which the potential power of the PS affect</span><span style="font-family:Verdana;">ed</span><span style="font-family:Verdana;"> biosensors if the test subject ha</span><span style="font-family:Verdana;">d</span><span style="font-family:Verdana;"> not been inside the PS for at least 20 days and the test subject’s unexplained energy was excluded. In this paper, we report new results regarding (ii). As a result of dividing a year according to the four seasons of winter, spring, summer, and autumn and analyzing the pyramid effect of each period, the following points were found. 1) There was a pyramid effect without seasonal variation. The pyramid effect on the lower and upper layers was different throughout the year for the biosensors placed at the PS apex in two layers, regardless of the season. 2) There was a pyramid effect with seasonal variation. The value of the psi index, which indicates the magnitude of the pyramid effect, changed as the seasons changed, while different pyramid effects were maintained on the lower and upper layers. Regarding the change in the pyramid effect depending on the season, the psi index in summer was larger than that in winter in both the lower and upper layers. From these results, we found that there are two types of potential power at the PS apex: seasonal potential power and non-seasonal potential power.
文摘Since October 2007, we have been conducting rigorous scientific research on the unexplained “power” of a pyramidal structure (PS). From our research results so far, we could classify pyramid effects by the PS into the following two types: (i) the pyramid effects due to the potential power of the PS and (ii) the pyramid effects due to the influence of the test subject meditating inside the PS. We have been using edible cucumber sections as the biosensors. The pyramid effect existence was clarified by measuring and analyzing the concentration of volatile components released from the biosensors. The biosensors were arranged as a pair: one member of the pair was placed at the PS apex and the other was placed at the calibration control point 8.0 m away from the PS. In this paper, we report a new discovery regarding the type (i) pyramid effects. We discovered a phenomenon considered to be entanglement between the biosensor pairs detecting the pyramid effects. In other words, the biosensors at the PS apex, which were affected by the potential power of the PS, affected the biosensors at the calibration control point. We also confirmed that the effects on the biosensors placed at the calibration control point were not due to the potential power of the PS. Furthermore, we showed that the magnitude of the effect of entanglement changed with the seasons. We expect that our research results will be widely accepted in the future and will become the foundation for a new research field in science, with a wide range of applications.
文摘There have been various traditions and books which describe a so-called “pyramid power”, but there have been almost no reliable academic studies and no statistically significant data about it. We have continued scientifically rigorous experiments using biosensors to elucidate unexplained functions of a pyramidal structure (PS) since 2007. We used edible cucumber sections as biosensors and measured the concentrations of gas emitted from the sections by a technique developed by our group. From them we have demonstrated with high statistical accuracy the existence of the “pyramid power”, which was often recognized as having no scientific basis. We reached two conclusions from the work. 1) The PS converted the unconsciousness of a human (the test subject) more than 6 km away to energy detectable by the biosensors (1% significance). 2) The PS accumulated the influence that a human (the test subject) had when meditating within the PS. Then the PS converted the influence into the energy detectable by the biosensors (10-3% significance). These two conclusions showed that the functions of the PS were detected when “the PS and a human were related”. On the other hand, we hypothesized that the potential power of the PS could be detected even when “the PS and a human were not related”. In this paper, our purpose is to verify the existence of the potential power of the PS alone by experiment when “the PS and a human were not related”. The following three results were obtained by experiment. 1) The presence of the potential power of the PS was demonstrated with 1% significance. 2) The potential power of the PS changed in value between summer and winter, and it was clear that the non-contact effect on the biosensors was larger in summer and smaller in winter. 3) The potential power of the PS affected only the biosensors placed at the PS apex, and did not affect the biosensors placed at the calibration control point 8 m away from the PS. This paper is the first report in the world to show this type of effect by scientific measurements. Our research results may open up a new science field of “pyramid power”, from which we expect further development of fields applying this “pyramid power”.
文摘Research on “pyramid power” began in the late 1930s. To date, many documents on “pyramid power” have been published. We have been conducting scientific research on the unexplained “power” of a pyramidal structure (PS) since October 2007. The research focuses on the detection of a non-contact effect of the unexplained “power” of the PS on biosensors (i.e., edible cucumber sections of Cucumis sativus “white spine type”) placed at the top of the PS. In this paper, in particular, we compared the non-contact effect of upper and lower biosensors placed in two layers on the PS apex, and we analyzed the difference of the non-contact effect due to the difference in the layers. The magnitude of the non-contact effect was represented by the calibrated psi index Ψ(E-CAL) calculated from gas concentrations emitted from the biosensors. A method to determine the presence or absence of the non-contact effect by analyzing the gas concentrations was developed by the International Research Institute (IRI). Ψ(E-CAL), which represents the magnitude of the non-contact effect, was the average value of the respective non-contact effect of the upper and lower biosensors stacked in two layers on the PS apex. We conducted the analysis on the assumption that the non-contact effect on the upper and lower biosensors might be different. Therefore, we considered that upper and lower biosensor calibration was required for Ψ(E-CAL), and we introduced a new calibrated psi index Ψ(E-CAL)Layer. Scientifically rigorous experiments to date have detected Ψ(E-CAL) with statistical significance and have demonstrated potential power of the PS (p = 6.0 × 10-3;Welch’s t-test, two-tails, the following p values are also the Welch’s t-test values). Based on data demonstrating the potential power of the PS, we analyzed the non-contact effects on the upper and lower biosensors of the PS apex. We obtained a surprising result that the non-contact effect on the upper biosensors (farther from the PS) was larger than that on the lower biosensors (closer to the PS) (p = 4.0 × 10-7). This suggested that the characteristic of the potential power of the PS, which is considered to exist near the PS apex, is distinctive. We also found that the non-contact effect due to the potential power of the PS varies with the season, and is large in summer and small in winter. In our discussion, we proposed a model that could theoretically explain the experimental results that the non-contact effect on the upper biosensors at the PS apex is larger than the lower biosensors. In proposing this model, we assumed that there were two different types of potential power at the PS apex and that the biosensors had two different gas-generating reactions. In a simulation using the model, the experimental results were well approximated in which the non-contact effect on the biosensors differs depending on the difference between the upper and lower layers. The results of this paper are the world’s first to prove aspects of the “pyramid power” through scientifically rigorous experiments and analysis. These results will become a new field of science in the future, and their broad applications are expected.
文摘【目的】基因聚合是实现水稻稻瘟病广谱抗性的有效途径之一。通过构建粳稻背景下不同双基因聚合系,利用长江下游粳型稻瘟病菌(Magnaporthe oryzea)菌株评价其抗性效应并解析其抗性效应产生的构成因子,为长江下游粳稻抗稻瘟病育种提供广谱抗性基因组合模式和种质资源。【方法】以粳稻07GY31为背景的Piz基因座不同复等位基因(Pigm、Pi40、Pi9、Pi2、Pizt和Piz)单基因系为核心,利用不完全NCII交配设计,分别与其他广谱抗性基因(Pi1、Pi54和Pi33)单基因系杂交,经分子标记辅助选择和农艺性状筛选,共构建18种不同基因组合的双基因聚合系。2019年利用长江下游粳稻种植区采集、分离的109个稻瘟病代表性菌株进行苗瘟、穗瘟人工接种鉴定及不同病圃的自然诱发鉴定,评价不同双基因聚合系的抗性效应,并分析双基因聚合系抗性效应的构成因子。【结果】Genotyping by sequencing(GBS)分析表明所构建的双基因聚合系均具有较高的背景恢复率,分布于97.08%(PPL^(Piz/Pi33))—99.08%(PPL^(Pigm/Pi1))。表明除了目标基因区域不同外,所有双基因聚合系的遗传背景几乎完全与受体亲本07GY31一致。同时人工接菌鉴定表明绝大部分双基因聚合系苗瘟和穗瘟抗性水平都优于单基因系。其中苗瘟抗性效应较好的聚合系分别为PPL^(Pigm/Pi1)、PPL^(Pigm/Pi54)、PPL^(Pigm/Pi33)、PPL^(Pi9/Pi33)、PPL^(Pi9/Pi54)、PPL^(Pi40/Pi54)、PPL^(Pi40/Pi33)、PPL^(Pi40/Pi1)、PPL^(Pi9/Pi1),而穗瘟抗性效应较好的聚合系分别为PPL^(Pigm/Pi1)、PPL^(Pigm/Pi54)、PPL^(Pigm/Pi33)、PPL^(Pi40/Pi33)、PPL^(Pi40/Pi54)、PPL^(Pi40/Pi1)、PPL^(Pizt/Pi33)。不同抗性基因聚合后产生不同的效应,其中互补效应高且能有效表达是提高双基因聚合系苗瘟和穗瘟抗性的关键因子。双基因聚合系PPL^(Pigm/Pi1)、PPL^(Pigm/Pi54)和PPL^(Pigm/Pi33)在苗瘟和穗瘟的人工接种,以及在不同病圃的自然诱发鉴定中均表现稳定的广谱抗性,同时,农艺性状调查结果也表明这3个双基因聚合系的基本农艺性状与轮回亲本07GY31基本一致,因此,基因组合Pigm/Pi1、Pigm/Pi54和Pigm/Pi33是适于长江下游粳稻的广谱抗性基因组合模式。【结论】抗性基因的组合方式影响聚合系的抗性水平,互补效应高且能有效表达是粳型双基因聚合系抗性效应提高的关键因子。本研究构建的双基因聚合系及其抗性效应分析为长江下游广谱稻瘟病抗性粳稻品种的精准培育提供了种质资源和理论支撑。
