Abstract: An improvement is made to a non-Raman spectroscopy method and apparatus in which a quantum entangled transmission package formed in a quantum well in a laser is directed to a target and in which the apparatus receives emission packages from the target. A control circuit triggers the laser to emit a laser beam. The transmission package is sent via the laser beam by an emission fiber and the emission package is received by a collection fiber. The collection fiber and the transmission fiber may be included in a Raman probe. The collection fiber provides an input to a monochromator comprising a diffraction grating. The diffraction grating is constructed to permit selection of any of a wide range of wavelengths. A spectrometer receives an output from the diffraction grating. The spectrometer output is measured by a photomultiplier to provide an input to the control module. A number of different spectra are selectively generated.

Abstract: An extremely sensitive spectroscopy method utilizes a laser modified to an extremely low emission with an integrated control system, interfaced within a typical Raman platform to comprise low energy laser spectroscopy (LELS). LELS acquires and utilizes a quantum entangled state of photons and particles, including omnipresent cosmological dark matter particles (OCDM) and omnipresent cosmological dark energy (OCDE). The OCDM and OCDE matter has an affinity to particles of same OCDM and OCDE matter in target specimens, with same-time data results of high sensitivity. In a semiconductor light emitter, electron flow at a low energy level is provided to a quantum well to produce a quantum tunneling of electrons into an active region of the laser quantum well and creating sublasering. Sublasering allows OCDM and OCDE to become entangled with other particles and energies in the laser's quantum well and create a transmission package comprising quantum entangled fields, waves, wave packages, states and energies.

Abstract: An extremely sensitive spectroscopy method utilizes a laser modified to an extremely low emission with an integrated control system, interfaced within a typical Raman platform to comprise low energy laser spectroscopy (LELS). LELS acquires and utilizes a quantum entangled state of photons and particles, including omnipresent cosmological dark matter particles (OCDM) and omnipresent cosmological dark energy (OCDE). The OCDM and OCDE matter has an affinity to particles of same OCDM and OCDE matter in target specimens, with same-time data results of high sensitivity. In a semiconductor light emitter, electron flow at a low energy level is provided to a quantum well to produce a quantum tunneling of electrons into an active region of the laser quantum well and creating sublasering. Sublasering allows OCDM and OCDE to become entangled with other particles and energies in the laser's quantum well and create a transmission package comprising quantum entangled fields, waves, wave packages, states and energies.

Abstract: In a spectrophotometer and a method of operation, very low levels of energy are produced in a laser diode and directed to excite a sample. Energy is provided to a quantum well to bring the laser diode to a pre-lasing state. Another increment of energy causes the laser diode to emit energy at an energy level lower than a visible laser beam. The energy produced by the laser is collided with the sample. A stimulated emission from the sample includes signals from various entities in the sample. The return emission spectra from the sample comprise signatures used to identify compounds. Use of such very low energies collided with a sample elicit spectra not previously associated with respective analytes. A Raman spectroscopy platform is used for performance of the method.

Abstract: An extremely sensitive spectroscopy method utilizes a laser modified to an extremely low emission with an integrated control system, interfaced within a typical Raman platform to comprise low energy laser spectroscopy (LELS). LELS acquires and utilizes a quantum entangled state of photons and particles, including omnipresent cosmological dark matter particles (OCDM) and omnipresent cosmological dark energy (OCDE). The OCDM and OCDE matter has an affinity to particles of same OCDM and OCDE matter in target specimens, with same-time data results of high sensitivity. In a semiconductor light emitter, electron flow at a low energy level is provided to a quantum well to produce a quantum tunneling of electrons into an active region of the laser quantum well and creating sublasering. Sublasering allows OCDM and OCDE to become entangled with other particles and energies in the laser's quantum well and create a transmission package comprising quantum entangled fields, waves, wave packages, states and energies.