Blackledge, J2022-08-032022-08-0320212021J. M. Blackledge10.1007/978-981-16-2450-6_4Infosys Science Foundation Series2364403610.1007/978-981-16-2450-6_4http://hdl.handle.net/10566/7668The paper introduces and discusses the evolution equation, and, based exclusively on this equation, considers random walk models for the time series available on the daily confirmed Covid-19 cases for different countries. It is shown that a conventional random walk model is not consistent with the current global pandemic time series data, which exhibits non-ergodic properties. A self-affine random walk field model is investigated, derived from the evolutionary equation for a specified memory function which provides the non-ergodic fields evident in the available Covid-19 data. This is based on using a spectral scaling relationship of the type 1/ωα where ω is the angular frequency and α ∈ (0, 1) conforms to the absolute values of a normalised zero mean Gaussian distribution. It is shown that α is a primary parameter for evaluating the global status of the pandemic in the sense that the pandemic will become extinguished as α → 0 for all countries. For this reason, and based on the data currently available, a study is made of the variations in α for 100 randomly selected countries. Finally, in the context of the Bio-dynamic Hypothesis, a parametric model is considered for simulating the three-dimensional structure of a spike protein which may be of value in the development of a vaccine.enEinstein’s Evolution equationSelf-Affine random walk fieldsPandemic time series analysisBio-dynamics hypothesisFractal geometry of spike proteinsArticle