This book is written for anybody who is curious about nature and motion. Curiosity about how people, animals, things, images and empty space move leads to many adven- tures. This volume presents the best of them in the domains of relativity and cosmology. In the study of motion – physics – special and general relativity form two important building blocks.

Special relativity is the exploration of the energy speed limit c. General relativity is the exploration of the force limit c4/4G. The text shows that in both domains, all equations follow from these two limit values. This simple, intuitive and unusual way of learning relativity should reward the curiosity of every reader – whether student or professional.

The present volume is the second of a six-volume overview of physics that arose from a threefold aim that I have pursued since 1990: to present motion in a way that is simple, up to date and captivating.

Table of Contents
1 Maximum Speed, Observers At Rest And Motion Of Light
2 Relativistic Mechanics
3 Special Relativity In Four Sentences
4 Simple General Relativity: Gravitation, Maximum Speed And Maximum Force
5 How Maximum Speed Changes Space, Time And Gravity
6 Open Orbits, Bent Light And Wobbling Vacuum
7 From Curvature To Motion
8 Why Can We See The Stars? – Motion In The Universe
9 Black Holes – Falling Forever
10 Does Space Differ From Time?
11 General Relativity In A Nutshell – A Summary For The Layman

This book is written for anybody who is curious about nature and motion. Have you ever asked: Why do people, animals, things, images and space move? The answer leads to many adventures; this volume presents those due to the discovery that there is a smallest change value in nature. This smallest change value, the quantum of action, leads to what is called quantum physics. In the structure of modern physics, quantum physics covers three points; this volume covers the introduction to the point in the lower right: the foundations of quantum theory.

Table of Contents
1 Minimum Action – Quantum Theory For Poets
2 Light – The Strange Consequences Of The Quantum Of Action
3 Motion Of Matter – Beyond Classical Physics
4 The Quantum Description Of Matter And Its Motion
5 Permutation Of Particles – Are Particles Like Gloves?
6 Rotations And Statistics – Visualizing Spin
7 Superpositions And Probabilities – Quantum Theory Without Ideology
8 Colours And Other Interactions Between Light And Matter
9 Quantum Physics In A Nutshell

This book is written for anybody who is intensely curious about nature and motion. Have you ever asked: Why do people, animals, things, images and empty space move? The answer leads to many adventures, and this book presents one of the best of them: the search for a precise, unified and final description of all motion.

Table of Contents
1 From Millennium Physics To Unification
2 Physics In Limit Statements
3 General Relativity Versus Quantum Theory
4 Does Matter Differ From Vacuum?
5 What Is The Difference Between The Universe And Nothing?
6 The Shape Of Points – Extension In Nature
7 The Basis Of The Strand Model
8 Quantum Theory Of Matter Deduced From Strands
9 Gauge Interactions Deduced From Strands
10 General Relativity Deduced From Strands
11 The Particle Spectrum Deduced From Strands
12 Particle Properties Deduced From Strands
13 Experimental Predictions Of The Strand Model
14 The Top Of Motion Mountain

This book is written for anybody who is curious about nature and motion. Curiosity about how bodies, images and empty space move leads to many adventures. This volume presents the best adventures about the motion inside people, inside animals, and inside any other type of matter – from the largest stars to the smallest nuclei.

Table of Contents
1 Motion For Enjoying Life
2 Changing The World With Quantum Effects
3 Quantum Electrodynamics – The Origin Of Virtual Reality
4 Quantum Mechanics With Gravitation – First Steps
5 The Structure Of The Nucleus – The Densest Clouds
6 The Sun, The Stars And The Birth Of Matter
7 The Strong Interaction – Inside Nuclei And Nucleons
8 The Weak Nuclear Interaction And The Handedness Of Nature
9 The Standard Model Of Particle Physics – As Seen On Television
10 Dreams Of Unification
11 Bacteria, Flies And Knots
12 Quantum Physics In A Nutshell – Again

Boundary layers as rational approximations to the solutions of exact equations of fluid motion. Physical parameters influencing laminar and turbulent aerodynamic flows and transition. Effects of compressibility, heat conduction, and frame rotation. Influence of boundary layers on outer potential flow and associated stall and drag mechanisms. Numerical solution techniques and exercises. The major focus of 16.13 is on boundary layers, and boundary layer theory subject to various flow assumptions, such as compressibility, turbulence, dimensionality, and heat transfer. Parameters influencing aerodynamic flows and transition and influence of boundary layers on outer potential flow are presented, along with associated stall and drag mechanisms. Numerical solution techniques and exercises are included.

These courses, produced by the Massachusetts Institute of Technology, introduce the fundamental concepts and approaches of aerospace engineering, highlighted through lectures on aeronautics, astronautics, and design. MIT˘ď‹ď_s Aerospace and Aeronautics curriculum is divided into three parts: Aerospace information engineering, Aerospace systems engineering, and Aerospace vehicles engineering. Visitors to this site will find undergraduate and graduate courses to fit all three of these areas, from Exploring Sea, Space, & Earth: Fundamentals of Engineering Design to Bio-Inspired Structures

This book began as lecture notes for an Oregon State University course in fluid mechanics, designed for beginning graduate students in physical oceanography. Because of its fundamental nature, this course is often taken by students outside physical oceanography, e.g., atmospheric science, civil engineering, physics and mathematics.
In later courses, the student will discover esoteric fluid phenomena such as internal waves that propagate through the sky, water phase changes that govern clouds, and planetary rotation effects that control large-scale winds and ocean currents. In contrast, this course concerns phenomena that we have all been familiar with since childhood: flows you see in sinks and bathtubs, in rivers, and at the beach. In this context, we develop the mathematical techniques and scientific reasoning skills needed for higher-level courses and professional research. Prerequisites are few: basic linear algebra, differential and integral calculus and Newton’s laws of motion. As we go along we discover the need for the more advanced tools of tensor analysis.

Is climate change real? Yes, it is! And technologies to reduce Greenhouse Gas (GHG) emissions are being developed. One type of technology that is imperative in the short run is biofuels; however, biofuels must meet specifications for gasoline, diesel, and jet fuel, or catastrophic damage could occur. This course will examine the chemistry of technologies of bio-based sources for power generation and transportation fuels. We'll consider various biomasses that can be utilized for fuel generation, understand the processes necessary for biomass processing, explore biorefining, and analyze how biofuels can be used in current fuel infrastructure.

This class analyzes complex biological processes from the molecular, cellular, extracellular, and organ levels of hierarchy. Emphasis is placed on the basic biochemical and biophysical principles that govern these processes. Examples of processes to be studied include chemotaxis, the fixation of nitrogen into organic biological molecules, growth factor and hormone mediated signaling cascades, and signaling cascades leading to cell death in response to DNA damage. In each case, the availability of a resource, or the presence of a stimulus, results in some biochemical pathways being turned on while others are turned off. The course examines the dynamic aspects of these processes and details how biochemical mechanistic themes impinge on molecular/cellular/tissue/organ-level functions. Chemical and quantitative views of the interplay of multiple pathways as biological networks are emphasized. Student work will culminate in the preparation of a unique grant application in an area of biological networks.

Analytical chemistry is the branch of chemistry dealing with measurement, both qualitative and quantitative. This discipline is also concerned with the chemical composition of samples. In the field, analytical chemistry is applied when detecting the presence and determining the quantities of chemical compounds, such as lead in water samples or arsenic in tissue samples. It also encompasses many different spectrochemical techniques, all of which are used under various experimental conditions. This branch of chemistry teaches the general theories behind the use of each instrument as well analysis of experimental data. Upon successful completion of this course, the student will be able to: Demonstrate a mastery of various methods of expressing concentration; Use a linear calibration curve to calculate concentration; Describe the various spectrochemical techniques as described within the course; Use sample data obtained from spectrochemical techniques to calculate unknown concentrations or obtain structural information where applicable; Describe the various chromatographies described within this course and analyze a given chromatogram; Demonstrate an understanding of electrochemistry and the methods used to study the response of an electrolyte through current of potential. (Chemistry 108)

Analytical chemistry spans nearly all areas of chemistry but involves the development of tools and methods to measure physical properties of substances and apply those techniques to the identification of their presence (qualitative analysis) and quantify the amount present (quantitative analysis) of species in a wide variety of settings.

Analytical chemistry is more than a collection of analytical methods and an understanding of equilibrium chemistry; it is an approach to solving chemical problems. Although equilibrium chemistry and analytical methods are important, their coverage should not come at the expense of other equally important topics. The introductory course in analytical chemistry is the ideal place in the undergraduate chemistry curriculum for exploring topics such as experimental design, sampling, calibration strategies, standardization, optimization, statistics, and the validation of experimental results. Analytical methods come and go, but best practices for designing and validating analytical methods are universal. Because chemistry is an experimental science it is essential that all chemistry students understand the importance of making good measurements.

As currently taught in the United States, introductory courses in analytical chemistryemphasize quantitative (and sometimes qualitative) methods of analysis along with a heavydose of equilibrium chemistry. Analytical chemistry, however, is much more than a collection ofanalytical methods and an understanding of equilibrium chemistry; it is an approach to solvingchemical problems. Although equilibrium chemistry and analytical methods are important, theircoverage should not come at the expense of other equally important topics.

The introductory course in analytical chemistry is the ideal place in the undergraduate chemistry curriculum forexploring topics such as experimental design, sampling, calibration strategies, standardization,optimization, statistics, and the validation of experimental results. Analytical methods comeand go, but best practices for designing and validating analytical methods are universal. Becausechemistry is an experimental science it is essential that all chemistry students understand theimportance of making good measurements.

My goal in preparing this textbook is to find a more appropriate balance between theoryand practice, between “classical” and “modern” analytical methods, between analyzing samplesand collecting samples and preparing them for analysis, and between analytical methods anddata analysis. There is more material here than anyone can cover in one semester; it is myhope that the diversity of topics will meet the needs of different instructors, while, perhaps,suggesting some new topics to cover.

Analytical Chemistry Lab includes nine experiments to guide students in basic laboratory techniques related to the topics in Analytical Chemistry. This resource is designed to support a sophomore level specialized science course intentionally designed for students who are chemistry majors, medical laboratory science majors, or those biology majors who are having chemistry as a minor degree.

Introduction to techniques and practices of analytical chemistry. Topics will include: statistics, gravimetry, equilibrium, titration, spectroscopy, electrochemistry, chromatography. This resource is designed to support a sophomore level specialized science course intentionally designed for students who are chemistry majors, medical laboratory science majors, or those biology majors who are having chemistry as a minor degree.

This is a laboratory course supplemented by lectures that focus on selected analytical facilities that are commonly used to determine the mineralogy, elemental abundance and isotopic ratios of Sr and Pb in rocks, soils, sediments and water.

This open course with a new set of ancillary materials for OpenStax Chemistry was created under a Round Eleven Mini-Grant for Ancillary Materials Creation and Revision. The materials created in order to support faculty implementing OpenStax Psychology in the classroom include:

Lecture Slides
Chapter Checklists
Practice Problems
Newly-Created Videos

Along with these resources, the open course also contains a laboratory section with new instructional videos, a laboratory notebook and a sample notebook with responses, and experiments for each course.

El presente manuscrito es resultado de investigaciones multidisciplinarias bajo diferentes perspectivas científicas-académicas, mediante la confrontación de criterios de diferentes autores bajo un enfoque descriptivo que señala la importancia de ética en varios escenarios actuales como son en la discriminación de la mujer en ambiente laboral, el manejo de los individuos dentro de las organizaciones, dentro de la agricultura al momento de producir y cultivar, como la ética afecta al clima organizacional y lagestión docente dentro del caso de estudio de una universidad, la ética y la responsabilidad social empresarial como reto de las empresas, la discriminación laboral como comportamiento poco ético en el área de recursos humanos, y por ultimo una contrastación de la ética en la publicidad de las empresas. Estos estudios se realizan desde una mirada científica y se la acerca a la realidad ecuatoriana.

Practical applications of the continuum concept for deformation of solids and fluids, emphasizing force balance. Stress tensor, infinitesimal and finite strain, and rotation tensors developed. Constitutive relations applicable to geological materials, including elastic, viscous, brittle, and plastic deformation. Solutions to classical problems in geodynamics.

This book was developed at Simon Fraser University for an upper-level physics course. Along with a careful exposition of electricity and magnetism, it devotes a chapter to ferromagnets. According to the course description, the topics covered were “electromagnetics, magnetostatics, waves, transmission lines, wave guides, antennas, and radiating systems.”

Table of Contents
1 Maxwell's Equations
2 Electrostatic Field (I)
3 Electrostatic Field (II)
4 The Magnetostatic Field (I)
5 The Magnetostatic Field (II)
6 Ferromagnetism
7 Time Dependent Electromagnetic Fields
8 E.M. Fields and Energy Flow
9 Plane Waves (I)
10 Plane Waves (II)
11 Transmission Lines
12 Waveguides