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Submitted: August 10, 2024 | Approved: September 03, 2024 | Published: September 04, 2024

How to cite this article: Maksoed WH. Mesofractal Modeling of Biosystems & Organic Spintronics. Arch Biotechnol Biomed. 2024; 8(1): 034-035. Available from: https://dx.doi.org/10.29328/journal.abb.1001042.

DOI: 10.29328/journal.abb.1001042

Copyright License: © 2024 Maksoed WH. This is an open access article distributed under the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original work is properly cited.

Keywords: Meso fractals; Molecular spintronics; Optical engine; Control system; [PI(D)]

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Mesofractal Modeling of Biosystems & Organic Spintronics

Widastra Hidajatullah Maksoed1,2*

1Prodi of Physics, University of Indonesia, Depok 16424, Indonesia
2The Meso Fractals Initiative, Bandung 40122, Indonesia

*Address for Correspondence: Widastra Hidajatullah Maksoed, Prodi of Physics, University of Indonesia, Email: hidajatulahmaksoed@gmail.com

Mesoscopic modeling of complex systems involves thermodynamic nonequilibrium of discrete scaling. Further from quantum correlation on a chip retrieved quantum nonlinear optics with single photons enabled by strongly interacting atoms. Accompanied by mesofractals as the development of meso & micro size fractal structures is required to mimic various biological systems for various functions. Showed through fluorapatite in gelatin‐based nanocomposite, fractal in DNA knots driven by balance of fission & fusion in mtDNA/mitochondrial DNA mechanism, for optical engines for light energy detection described the proportional integral derivative [PI(D)]‐controller set in microbial cells to HCCI/Homogeneous Charge Compression Ignition.

Mesoscopic modeling of complex systems involves thermodynamics nonequilibrium of discrete scaling of entropy reduction + fluctuation, nonlinear dynamics & complexity of self‐organized spatiotemporal structure [1]. Electron exchange & electron‐ or photo‐triggered electron exchange are two central topics in related fields of molecular magnetism & molecular spintronics through control of external (optical, redox, and/or magnetic) properties in the use of several physics (spectroscopic, magnetic, electrochemical and/or photochemical) [2].

Obeys analytical studies of a common mechanism of previously named “spinterface” have been forecasted through “mesoscopic physics of electrons & photons” from E. Ackermans & Gilles Montambaux of e.g. the ability to control spin polarization [3] coincides with electromechanical coupling effect between electric polarization & mechanical strain gradient [to the mechanical disturbance that propagates in HF Olster, 1967]. Further from quantum correlation on a chip [Ranojoy Bose, et al. 2012] those were retrieved quantum linear optics with single photons enabled by strongly interacting atoms provided by Peyrone, there was to conclude above subject to mesoscopic entanglement [4].

Mesofractal and DNA

Accompanied by mesofractals as “development of meso & micro size fractal structures is required to mimic various biological systems for various functions. Meso & micro-sized fractals are fabricated by several processes in engineering” [5], where we have sought ‘mechanical stress mechanisms in the cell [6] flows & percolation accomplishes.

On extensive data sets of fractal fluctuations in Human DNA base CG concentration/10bp (base pairs), the predicted distribution is close to the Gaussian distribution for small‐scale fluctuations, but exhibits a fat long tail for large‐scale fluctuations [7]. Fractals in DNA knots are driven by the balance of fission & fusion in mitochondrial DNA. Fractal characteristics are also depicted in fluorapatite gelatin‐based nanocomposite.

Ever explained: “a useful concept for ecology & sustainability” of efficiency = 1 – [T(o)/T]: “the principles of sustainability to human activities ultimately must result in the scrutiny of all sectors activity to asses the changes required to provide for a high quality of life for future generations”[8].

Organic spintronics & PI(D)

Involve the CFD/Computational Fluid Dynamics and HCCI/Homogeneous Charge Compression Ignition, ever defined whereas “ignition model engine” popularly known as a model device diesel engine [9], retrieved the “Laser Doppler Velocimetry/LDV” we intend to compare to Linear Variable Differential Transducer/LVDT includes sensor technology as well as to PVDF.polyvynilidine fluoride comprise giant fluxoelectric in α‐phase of PVDF [10]. Further, we guided to properties depicted by linear variable differential with PID/the proportional integral derivative [PI(D)]‐ controller are set in such a using test the best comparison between rising time, overshoot & setting time obtained in the motor response. The control system being used on the FTU Plant is formed by a PXI EC‐based platform supervised to [11].

Also offered the spintronics using of “PI(D)‐controller, from Microbial Cell to the Motor Response in Plasma Heating”, spintronics themselves involved in the study of active control & manipulation of spin degrees of freedom in a solid‐state system, we comprise in weight spin relaxation & dephasing are a process that guides “equilibration [12].

We intended to accomplish the HCCI quoted in two & three characters seems twin‐compared Homogeneous Charge Compression Ignition viewed through the IceCube Document Project held since Oct 11, 2001 ever concluded as “saw none” so they can be followed the ITER/International Thermonuclear Experiment Reactors to IFMIF/International Fusion Materials Irradiation Facilities.

Refer to ”magnetic quantum‐dot cellular automata which are nonvolatile & lower power consist of nanomagnets. Since they are magnetically coupled, logic can be performed by switching an input nanomagnet which causes a chain reaction of switching on the other element in a domino fashion” [13].

For the disproportionation of H2O2, we also consider an electrokinetic mechanism that appears. So far, the more efficient micro/nanoscale motors are derived from biological systems [14]. Besides, a control experiment using three stripped Au/Pt/Au rods catalyzed the composition of H2O2 at a similar rate [15].

From a study of building meso fractals, the fractal & mesofractal application to organic spintronic if related to PI(D) has been extended, at least ranging from DNA knots in mitochondrial fission & fusion mechanism, with some explanation to organic magnetism, quantum optics & optical engine.

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