Photon diffusion in a homogeneous medium bounded externally or internally by an infinitely long circular cylindrical applicator. III. Synthetic study of continuous-wave photon fluence rate along unique spiral paths.

This is Part III of the work that examines photon diffusion in a scattering-dominant medium enclosed by a "concave" circular cylindrical applicator or enclosing a "convex" circular cylindrical applicator. In Part II of this work Zhang et al. [J. Opt. Soc. Am. A, 66 (2011)] predicted that, on the tissue-applicator interface of either "concave" or "convex" geometry, there exists a unique set of spiral paths, along which the steady-state photon fluence rate decays at a rate equal to that along a straight line on a planar semi-infinite interface, for the same line-of-sight source-detector distance. This phenomenon of steady-state photon diffusion is referred to as "straight-line-resembling-spiral paths" (abbreviated as "spiral paths"). This Part III study develops analytic approaches to the spiral paths associated with geometry of a large radial dimension and presents spiral paths found numerically for geometry of a small radial dimension. This Part III study also examines whether the spiral paths associated with a homogeneous medium are a good approximation for the medium containing heterogeneity. The heterogeneity is limited to an anomaly that is aligned azimuthally with the spiral paths and has either positive or negative contrast of the absorption or scattering coefficient over the background medium. For a weak-contrast anomaly the perturbation by it to the photon fluence rate along the spiral paths is found by applying a well-established perturbation analysis in cylindrical coordinates. For a strong-contrast anomaly the change by it to the photon fluence rate along the spiral paths is computed using the finite-element method. For the investigated heterogeneous-medium cases the photon fluence rate along the homogeneous-medium associated spiral paths is macroscopically indistinguishable from, and microscopically close to, that along a straight line on a planar semi-infinite interface.

[1]  Lihong V. Wang,et al.  Biomedical Optics: Principles and Imaging , 2007 .

[2]  Sergio Fantini,et al.  Semi-infinite-geometry boundary problem for light migration in highly scattering media: a frequency-domain study in the diffusion approximation , 1994 .

[4]  Daqing Piao,et al.  Photon diffusion in a homogeneous medium bounded externally or internally by an infinitely long circular cylindrical applicator. V. Steady-state fluorescence. , 2013, Journal of the Optical Society of America. A, Optics, image science, and vision.

[5]  M. Schweiger,et al.  A finite element approach for modeling photon transport in tissue. , 1993, Medical physics.

[6]  Hamid Dehghani,et al.  Near infrared optical tomography using NIRFAST: Algorithm for numerical model and image reconstruction. , 2009, Communications in numerical methods in engineering.

[7]  Simon R. Arridge,et al.  Reconstruction methods for infrared absorption imaging , 1991, Photonics West - Lasers and Applications in Science and Engineering.

[8]  R. Reuben,et al.  The Effect of Pressure Modulation on the Flow of Gas through a Solid Membrane: Permeation and Diffusion of Hydrogen through Nickel , 1984 .

[9]  T. Tsuda,et al.  Viscosity waves and thermal‐conduction waves as a cause of “specular” reflectors in radar studies of the atmosphere , 1991 .

[10]  R. Alcouffe,et al.  Comparison of finite-difference transport and diffusion calculations for photon migration in homogeneous and heterogeneous tissues. , 1998, Physics in medicine and biology.

[11]  John Satterly Steady-State Theory , 1959 .

[12]  S L Jacques,et al.  Experimental tests of a simple diffusion model for the estimation of scattering and absorption coefficients of turbid media from time-resolved diffuse reflectance measurements. , 1992, Applied optics.

[13]  D. Boas,et al.  Experimental images of heterogeneous turbid media by frequency-domain diffusing-photon tomography. , 1995, Optics letters.

[14]  Brian W Pogue,et al.  Photon diffusion in a homogeneous medium bounded externally or internally by an infinitely long circular cylindrical applicator. I. Steady-state theory. , 2010, Journal of the Optical Society of America. A, Optics, image science, and vision.

[15]  Gang Yao,et al.  Photon diffusion in a homogeneous medium bounded externally or internally by an infinitely long circular cylindrical applicator. II. Quantitative examinations of the steady-state theory. , 2011, Journal of the Optical Society of America. A, Optics, image science, and vision.

[16]  Eugene P. Wigner,et al.  The Physical Theory of Neutron Chain Reactors , 1958 .

[17]  Harry L. Graber,et al.  Model For 3-D Optical Imaging Of Tissue , 1990, 10th Annual International Symposium on Geoscience and Remote Sensing.

[18]  A. Mandelis Diffusion-wave fields : mathematical methods and Green functions , 2001 .

[19]  S R Arridge,et al.  The theoretical basis for the determination of optical pathlengths in tissue: temporal and frequency analysis. , 1992, Physics in medicine and biology.

[20]  F. J. Smith,et al.  Thermal Diffusion in Gases , 1966 .

[21]  L. Felsen,et al.  Radiation and scattering of waves , 1972 .

[22]  W. Jost Diffusion and Electrolytic Conduction in Crystals (Ionic Semiconductors) , 1933 .

[23]  A Ishimaru,et al.  Diffusion of light in turbid material. , 1989, Applied optics.