String theorists have proposed that multi-national collider experiments could provide evidence for strings. The scientific community generally has been more reserved, believing possible detections would be indirect at best. Based on the theoretical prediction that if in existence strings should have resonance frequencies, this paper shows a novel technique involving Hydrogen in a magnetic field that led to the first direct data for strings, particularly a picture of a multi-dimensional string D-brane. This paper introduces string experimentation, the ability to study strings directly in the laboratory.
String experimentation has begun thanks to a novel laboratory technique that permitted the visualization of a D-brane (Tahan, 2011). Observations in experiments suggested that gravitons and related superparticles emerged due to the method. This manuscript describes the innovative technique diagrammatically. The method is shown to be useful for making particle predictions and for experimentation, particularly permitting nuclear and particle physics work including studies beyond the Standard Model to be performed on the lab bench.
Strings have been recorded in the laboratory (Tahan 2011). The responsible string experimentation method involves a symmetry breaking that permits access to a fifth dimension of gravitons and superpartners (Tahan 2012(Tahan , 2013(Tahan , 2014. The symmetry breaking can be thought opposite to traditional understanding since it introduces superparticles to the Standard Model visible sector.
Superparticles including gravitons appearing in the laboratory due to a novel technique (Tahan, 2011(Tahan, , 2012 meant that the gravitino exists, concluded to have a low mass consequently requiring this affirmative presentation. A low mass gravitino would not have been problematic related to Big Bang Nucleosynthesis (BBN) and baryogenesis if understanding a correlation between inflation and gravitino abundance (Ellis, Linde, & Nanopoulos, 1982), particularly when considering the particle to be dark matter and the lightest supersymmetric particle or superparticle (LSP). Gravitinos--proposed by this paper to be in the fifth dimension as dark matter--subsist because of inflation. This manuscript is a first discussion of the gravitino based on experimentation.
String experimentation has allowed for the observation in the laboratory of a D-brane with an open string for visible light (Tahan 2011). Events in experiments when the best defined, largest D-brane appeared suggested the subsistence of a separate medium that was concluded to be spacetime since no other extra-dimensional environment in which light travels could be imagined. Specifically, a high gravitational area in the tube of the set-up rotating and consequently dragging the background in which the light existed causing deformation of the D-brane with the open string (Tahan 2011) triggered the idea of an additional setting. The observation was in addition to an initial pushing influence that was later concluded to have affected the medium thereby exposing the D-brane and open string by seemingly stopping the laser light in place, rather than having influenced the light directly. This manuscript discusses environmental conditions in experiments that substantiated existence of a distinct medium. Understanding spacetime as a particular extra-dimensional environment does not require the altering of Special or General Relativity since related laws do not change. This paper is not reintroducing the classical, absolute aether but is expressing the existence of a general relativity aether or spacetime; the same explanations for mass influencing spacetime particularly for gravity do not change. This work simply proposes spacetime to be a tangible environment to which properties can be transferred.
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