This book is based on the results of our interest in the ?eld of ultrashort laser pulses interaction with matter. The aim of our monograph was to build the balanced description of the thermal transport phenomena generated by laser pulses shorter than the characteristic relaxation time. In the book we explore the matter on the quark, nuclear as well atomic scales. Also on the cosmic scale (Planck Era) the thermal disturbance shorter than the Planck time creates the new picture of the Universe. The mathematics, especially PDE, are the main tool in the description of the ultrashort thermal phenomena. Two types of the PDE: parabolic and hyperbolic partial di?erential equations are of special interest in the study of the thermal processes. We assume a moderate knowledge of basic Fourier and d'Alembert eq- tions. The scope of the book is deliberately limited to the background of the quantum mechanics equations: Schr] odinger and Klein-Gordon. In this book the attosecond laser pulses are the main source of the dist- bance of the thermal state of the matter. Recently, the attosecond laser pulses constitute a novel tool for probing processes taking place on the time scale of electron motion inside atoms. The research presented in this book appears to provide the basic tools and concepts for attosecond thermal dynamics. Nevertheless much research is still needed to make this emerging ?eld routinely applicable for a broad range of processes on atomic and subatomic scales."

This book is based on the results of our interest in the ?eld of ultrashort laser pulses interaction with matter. The aim of our monograph was to build the balanced description of the thermal transport phenomena generated by laser pulses shorter than the characteristic relaxation time. In the book we explore the matter on the quark, nuclear as well atomic scales. Also on the cosmic scale (Planck Era) the thermal disturbance shorter than the Planck time creates the new picture of the Universe. The mathematics, especially PDE, are the main tool in the description of the ultrashort thermal phenomena. Two types of the PDE: parabolic and hyperbolic partial di?erential equations are of special interest in the study of the thermal processes. We assume a moderate knowledge of basic Fourier and d'Alembert eq- tions. The scope of the book is deliberately limited to the background of the quantum mechanics equations: Schr] odinger and Klein-Gordon. In this book the attosecond laser pulses are the main source of the dist- bance of the thermal state of the matter. Recently, the attosecond laser pulses constitute a novel tool for probing processes taking place on the time scale of electron motion inside atoms. The research presented in this book appears to provide the basic tools and concepts for attosecond thermal dynamics. Nevertheless much research is still needed to make this emerging ?eld routinely applicable for a broad range of processes on atomic and subatomic scales."

The evolution processes in nature are governed by natural laws. The origins of the laws are still debated. In the monograph, we will present the idea that the splitting of the forces in the Universe is the result of the special properties of gravity, which influences all interactions in the Universe. We will present the master equations for all interactions and sketch the solutions. All laws of nature influence matter in the same manner which is dependent only on the scale.

In this book, the authors study the mutual interaction of cancer and its host body. The authors present the point of view that this interaction is mediated by human consciousness. Although the term cancer refers to undisciplined and uncontrollable cellular growth, a basal cell carcinoma of the skin is quite different from adenocarcinoma of the lung, prostate, or breast, brain tumours, lymphomas, leukaemias, and other malignancies. These all differ markedly with respect to growth rates, metastatic tendencies, and sensitivity to neuroendocrine or immune system influences, particularly those that might be modulated by stress. There are critical concerns when it comes to determining exactly how long a cancer has been present. If a lump in the breast is found to be malignant, when did the cancer start? A month, six months, or years before clinical detection? Such information would be crucial to establish any temporal relationship with antecedent.

Recent developments in the ultra-short laser technology and physics, especially at the attosecond time scale, open up new research frontiers for attoscience. This book examines the theoretical model for attophysics. The interaction of the attosecond laser pulses with slices of matter-attosecond tomography enables the description of the motion of electrons in atoms, molecules and 1D medium-graphene. The standard theory of the laser pulse-matter interaction is based on the parabolic Schrodinger equation, which leads to unphysical, infinite velocity of the thermal energy propagation. In this book, the Schrodinger equation is generalised to hyperbolic partial differential equation with finite velocity.