Fig 1.
Absorption spectra and Band gap analysis of CG100.
(A) The absorption spectra of diluted CG100 exposed to a magnetic field were fitted by the equations for direct band-gap transitions and (B) the inset shows (αE-photo) 2 versus photon energy for several magnetic fields for CG100 oligonucleotide DNA.
Table 1.
Comparison of the Eg values of CG100 determined versus several strengths of magnetic field.
Fig 2.
Gel electrophoresis image and analysis.
(A) shows the gel electrophoresis image of five samples of CG100 after exposure to the magnetic field (0, 250, 500, 750, and 1000 mT) based on their displacement (d1, d2, d3, d4, and d5), respectively, and Fig 2B shows the analysis of CG100 displacement in the gel by evaluation of the intensity of the lane and lane position.
Fig 3.
Raman spectra of CG100 obtained using a 514 nm laser, before magnetic field exposure (B = 0) and after magnetic field (B = 250 mT, B = 500 mT, B = 700 mT and B = 1000 mT) exposure.
Fig 4.
(a) Diagram shows the Lorentz force F defined in terms of acting on a charge q that moves in a magnetic field with a velocity v. The F direction is the opposite for a positive charge versus a negative charge. Fig 4(b) meanwhile illustrates the interaction of DNA and the nucleophile hydroxide.
Fig 5.
DNA is placed inside the magnetic field.
Prepared oligonucleotide DNA sample is placed inside the magnetic field. Components include (a) electromagnet, (b) thermometer, (c) multimeter, (d) timer, (e) Gauss meter, (f) electromagnet power supply and (g) DNA sample. Sub Fig reflects a schematic aspect of prepared set up.
Fig 6.
Magnetic field effect temperature and magnetic field of DNA.
Localized temperature variation in various magnetic fields for CG100 oligonucleotide DNA (A) Graphs demonstrate the resistivity variation in various magnetic fields for CG100 oligonucleotide DNA (B).