探测来自太阳的卡西米尔辐射

Richard A. Hutchin
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Two other authors have found the fine structure constant α (proportional to 1/h) is varying across the cosmos at up to 4.2 sigma certainty. All these results suggest that the vacuum field (and thus h) varies in time and space. In a previous paper we reported our tunnel diode experimental results as well as the results of six other organizations (including German, Russian and US national labs).The six organizations reported sinusoidal annual variations of 1000 - 3000 ppm (peak-to-valley) in the decay rates of 8 radionuclides over a 20-year span, including beta decay (weak interaction) and alpha decay (strong interaction). All decay rates peaked in January-February and minimized in July-August without any candidate cause suggested. We confirmed that Planck’s constant was the cause by verifying similar variations in Esaki tunnel diode current, which is purely electromagnetic. The combined data from previous strong and weak decays plus our own E & M tunnel data showed similar magnitude and time phasing for strong, weak and E & M interactions, except that the tunnel diode temporal variations were 180 deg out of phase—as we predicted. The logic for this 180 deg phase shift was straight forward. Radioactive decay and electron tunneling both have h in the denominator of the tunneling exponent, but tunnel diodes also have h2 in the numerator of the exponent due to the size of atoms being proportional to h2. This extra h2 makes the exponent proportional to h for electron tunneling instead of proportional to 1/h for strong and weak decay—shifting the annual oscillation for E & M tunnel current by 180 deg. Radioactive decay had a maximum around January-February of each year and a minimum around July-August of each year. Tunnel current (the equivalent to radioactive decay rate) had the opposite—a minimum around January of each year and a maximum around July of each year. This predicted and observed sign flip in the temporal variations between radioactive decay and electron tunneling provides strong evidence that h variations across the Earth’s orbit are the cause of these annual cycles. In this paper we take the next step by verifying whether the Sun and a potential more distant cosmic source radiate the vacuum E & M field, just as all stars generate massive amounts of regular E & M radiation. We reprocessed two years of data, 6 million data points, from our tunnel diode experiment to search for day-night oscillations in tunnel current. Here we assume that the Earth would block the radiated vacuum field half of each day. Sun-locked signals have 365 cycles per year and cosmos locked signals have 366 cycles per year. With our two years of data, these two signals are separated by a null-signal, which is not locked to the Earth or to the cosmos—allowing us to clearly distinguish the solar and cosmic sources. 1) We found sun-locked variations in the vacuum field, peaking around local noon with 10-13 probability of false alarm. Other potential causes are carefully examined and ruled out. 2) We also found cosmos-locked variations in the vacuum field, peaking at the right ascension of the red super-giant star Betelgeuse with 10-7 probability of false alarm. Cosmos locked sources are easily distinguished from the solar source because they have one extra cycle per year, two extra cycles during the two years of the experiment. They are thus independent Fourier components, easily separated by a Fourier transform. 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引用次数: 1

摘要

本文扩展了先前关于普朗克常数h和真空场的实验工作,真空场的光谱由h决定。特别是它增加了额外的实验证据,支持真空场的时空变化,包括太阳作为13西格玛确定性的源。真空场长期以来一直是物理学的一个谜,它具有由普朗克常数h确定的巨大理论强度,但没有明显的物理效应。1948年,亨德里克·卡西米尔首次提出这种形式的电磁辐射是真实存在的,并提出了一个实验来证实它的存在。从那时起,超过50个实验已经证实了这种真空辐射是真实的,是一种电磁辐射,在我们的实验室里,与标准的量子辐射光谱相比,它在时间和空间上的变化超过10:1。另外两位作者发现,精细结构常数α(与1/h成正比)在整个宇宙中以高达4.2西格玛的确定性变化。所有这些结果表明,真空场(以及h)随时间和空间的变化而变化。在之前的一篇论文中,我们报告了我们的隧道二极管实验结果以及其他六个组织(包括德国,俄罗斯和美国国家实验室)的结果。这6个组织报告了8种放射性核素的衰减率在20年期间呈1000 - 3000 ppm(峰谷)的正弦年变化,包括β衰变(弱相互作用)和α衰变(强相互作用)。所有的衰变率在1 - 2月达到顶峰,在7 - 8月降到最低,没有任何可能的原因。我们通过验证Esaki隧道二极管电流的类似变化,证实了普朗克常数是原因,这是纯电磁的。先前强、弱衰变的综合数据加上我们自己的E & M隧道数据显示,强、弱和E & M相互作用的幅度和时间相位相似,除了隧道二极管的时间变化与我们预测的相差180度。这个180度相移的逻辑很简单。放射性衰变和电子隧穿在隧穿指数的分母中都有h,但由于原子的大小与h2成正比,隧道二极管在指数的分子中也有h2。这个额外的h2使得电子隧穿的指数与h成正比,而不是与强和弱衰变成正比的1/h -将E & M隧道电流的年振荡移动了180度。放射性衰变在每年的1 - 2月左右达到最大值,在每年的7 - 8月左右达到最小值。隧道电流(相当于放射性衰变率)的情况正好相反,在每年的1月左右最小,在7月左右最大。在放射性衰变和电子隧穿之间的时间变化中,这种预测和观察到的符号翻转提供了强有力的证据,证明地球轨道上的h变化是这些年周期的原因。在这篇论文中,我们下一步将验证太阳和一个潜在的更遥远的宇宙源是否会辐射真空电磁场,就像所有的恒星都会产生大量的常规电磁辐射一样。我们重新处理了两年的数据,600万个数据点,从我们的隧道二极管实验中寻找隧道电流的昼夜振荡。这里我们假设地球每天有一半的时间阻挡辐射真空场。太阳锁定信号每年有365个周期,宇宙锁定信号每年有366个周期。根据我们两年的数据,这两个信号被一个零信号分开,这个零信号既不锁定在地球上,也不锁定在宇宙中,这使我们能够清楚地区分太阳和宇宙的来源。1)我们发现真空场的太阳锁定变化,在当地中午左右达到峰值,假警报的概率为10-13。其他潜在的原因被仔细检查并排除。2)我们还发现了真空场的宇宙锁定变化,在红超巨星参宿四的赤经处达到峰值,假警报的概率为10-7。宇宙锁定源很容易与太阳源区分开来,因为它们每年有一个额外的周期,在两年的实验中有两个额外的周期。因此它们是独立的傅里叶分量,很容易通过傅里叶变换分离。这两种高概率探测都支持真空场光谱可能在空间和时间上发生变化,并因恒星源而增强。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Detection of Casimir Radiation from Our Sun
This paper extends the previous experimental work on Planck’s constant h and the vacuum field, whose spectrum is determined by h. In particular it adds additional experimental evidence supporting temporal and spatial variations in the vacuum field, including the Sun as a source at 13 sigmas of certainty. The vacuum field has long been a mystery of physics, having enormous theoretical intensity set by Planck’s constant h and yet no obvious physical effect. Hendrick Casimir first proposed that this form of E & M radiation was real in 1948 and suggested an experiment to verify its existence. Over 50 experiments since then have confirmed that this vacuum radiation is real, is a form of electro-magnetic radiation, and varies in time and space over 10:1 in our laboratory compared to its standard QM spectrum. Two other authors have found the fine structure constant α (proportional to 1/h) is varying across the cosmos at up to 4.2 sigma certainty. All these results suggest that the vacuum field (and thus h) varies in time and space. In a previous paper we reported our tunnel diode experimental results as well as the results of six other organizations (including German, Russian and US national labs).The six organizations reported sinusoidal annual variations of 1000 - 3000 ppm (peak-to-valley) in the decay rates of 8 radionuclides over a 20-year span, including beta decay (weak interaction) and alpha decay (strong interaction). All decay rates peaked in January-February and minimized in July-August without any candidate cause suggested. We confirmed that Planck’s constant was the cause by verifying similar variations in Esaki tunnel diode current, which is purely electromagnetic. The combined data from previous strong and weak decays plus our own E & M tunnel data showed similar magnitude and time phasing for strong, weak and E & M interactions, except that the tunnel diode temporal variations were 180 deg out of phase—as we predicted. The logic for this 180 deg phase shift was straight forward. Radioactive decay and electron tunneling both have h in the denominator of the tunneling exponent, but tunnel diodes also have h2 in the numerator of the exponent due to the size of atoms being proportional to h2. This extra h2 makes the exponent proportional to h for electron tunneling instead of proportional to 1/h for strong and weak decay—shifting the annual oscillation for E & M tunnel current by 180 deg. Radioactive decay had a maximum around January-February of each year and a minimum around July-August of each year. Tunnel current (the equivalent to radioactive decay rate) had the opposite—a minimum around January of each year and a maximum around July of each year. This predicted and observed sign flip in the temporal variations between radioactive decay and electron tunneling provides strong evidence that h variations across the Earth’s orbit are the cause of these annual cycles. In this paper we take the next step by verifying whether the Sun and a potential more distant cosmic source radiate the vacuum E & M field, just as all stars generate massive amounts of regular E & M radiation. We reprocessed two years of data, 6 million data points, from our tunnel diode experiment to search for day-night oscillations in tunnel current. Here we assume that the Earth would block the radiated vacuum field half of each day. Sun-locked signals have 365 cycles per year and cosmos locked signals have 366 cycles per year. With our two years of data, these two signals are separated by a null-signal, which is not locked to the Earth or to the cosmos—allowing us to clearly distinguish the solar and cosmic sources. 1) We found sun-locked variations in the vacuum field, peaking around local noon with 10-13 probability of false alarm. Other potential causes are carefully examined and ruled out. 2) We also found cosmos-locked variations in the vacuum field, peaking at the right ascension of the red super-giant star Betelgeuse with 10-7 probability of false alarm. Cosmos locked sources are easily distinguished from the solar source because they have one extra cycle per year, two extra cycles during the two years of the experiment. They are thus independent Fourier components, easily separated by a Fourier transform. Both of these high probability detections support that the vacuum field spectrum may vary in space and time and be enhanced by stellar sources.
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