This is a continuation of Freshman Organic Chemistry I (CHEM 125a), the introductory course on current theories of structure and mechanism in organic chemistry for students with excellent preparation in chemistry and physics. This semester treats simple and complex reaction mechanisms, spectroscopy, organic synthesis, and some molecules of nature.

Human-caused climate change represents one of the great environmental challenges of our time. As it is inextricably linked with issues of energy policy, a familiarity with the fundamentals of climate change is critical for those looking to careers in the energy field. To appreciate the societal, environmental, and economic implications of policies governing greenhouse gas emissions, one must understand the basic underlying science. METEO 469 serves to lay down the fundamental scientific principles behind climate change and global warming. A firm grounding in the science is then used as a launching point for exploring issues involving climate change impacts and mitigation.

This course focuses on three particularly interesting areas of astronomy that are advancing very rapidly: Extra-Solar Planets, Black Holes, and Dark Energy. Particular attention is paid to current projects that promise to improve our understanding significantly over the next few years. The course explores not just what is known, but what is currently not known, and how astronomers are going about trying to find out.

This course covers fundamentals of thermodynamics, chemistry, and transport applied to energy systems. Topics include analysis of energy conversion and storage in thermal, mechanical, chemical, and electrochemical processes in power and transportation systems, with emphasis on efficiency, performance, and environmental impact. Applications include fuel reforming and alternative fuels, hydrogen, fuel cells and batteries, combustion, catalysis, combined and hybrid power cycles using fossil, nuclear and renewable resources.

Do you want to know more about atmospheric science? This course is designed to give both Meteorology and non-Meteorology students a comprehensive understanding of atmospheric science and the quantitative analytical tools to apply atmospheric science to their own disciplines. Students are introduced to fundamental concepts and applications of atmospheric thermodynamics, radiative transfer, atmospheric chemistry, cloud microphysics, atmospheric dynamics, and the atmospheric boundary layer. These topics are covered broadly but in enough depth to introduce students to the methods atmospheric scientists use to describe and predict atmospheric phenomena. The course is designed to be taken by sophomore meteorology students as well as by students in related disciplines who have an adequate mathematical and physical background.

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ISBN: 978-1-998755-16-5

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This course focuses on the fundamentals of structure, energetics, and bonding that underpin materials science. It is the introductory lecture class for sophomore students in Materials Science and Engineering, taken with 3.014 and 3.016 to create a unified introduction to the subject. Topics include: an introduction to thermodynamic functions and laws governing equilibrium properties, relating macroscopic behavior to atomistic and molecular models of materials; the role of electronic bonding in determining the energy, structure, and stability of materials; quantum mechanical descriptions of interacting electrons and atoms; materials phenomena, such as heat capacities, phase transformations, and multiphase equilibria to chemical reactions and magnetism; symmetry properties of molecules and solids; structure of complex, disordered, and amorphous materials; tensors and constraints on physical properties imposed by symmetry; and determination of structure through diffraction. Real-world applications include engineered alloys, electronic and magnetic materials, ionic and network solids, polymers, and biomaterials.
This course is a core subject in MIT’s undergraduate Energy Studies Minor. This Institute-wide program complements the deep expertise obtained in any major with a broad understanding of the interlinked realms of science, technology, and social sciences as they relate to energy and associated environmental challenges.

This course explores the fundamentals of optical and optoelectronic phenomena and devices based on classical and quantum properties of radiation and matter culminating in lasers and applications. Fundamentals include: Maxwell’s electromagnetic waves, resonators and beams, classical ray optics and optical systems, quantum theory of light, matter and its interaction, classical and quantum noise, lasers and laser dynamics, continuous wave and short pulse generation, light modulation; examples from integrated optics and semiconductor optoelectronics and nonlinear optics.

Fundamentals of photoelectric conversion: charge excitation, conduction, separation, and collection. Lectures cover commercial and emerging photovoltaic technologies and cross-cutting themes, including conversion efficiencies, loss mechanisms, characterization, manufacturing, systems, reliability, life-cycle analysis, risk analysis, and technology evolution in the context of markets, policies, society, and environment.
This course is one of many OCW Energy Courses, and it is an elective subject in MIT’s undergraduate Energy Studies Minor. This Institute–wide program complements the deep expertise obtained in any major with a broad understanding of the interlinked realms of science, technology, and social sciences as they relate to energy and associated environmental challenges.

This course provides a thorough introduction to the principles and methods of physics for students who have good preparation in physics and mathematics. Emphasis is placed on problem solving and quantitative reasoning. This course covers Newtonian mechanics, special relativity, gravitation, thermodynamics, and waves.

This is a continuation of Fundamentals of Physics, I (PHYS 200), the introductory course on the principles and methods of physics for students who have good preparation in physics and mathematics. This course covers electricity, magnetism, optics and quantum mechanics.

Conocer los fundamentos teóricos de la química inorgánica es esencial para comprender los conceptos y principios esenciales de esta rama de la química, que se enfoca en el estudio de los elementos y compuestos inorgánicos; proporcionando una base teórica sólida para el estudio de otras áreas de esta ciencia. "Fundamentos Teóricos de Química Inorgánica", además de temas clave de la química inorgánica, como la teoría del enlace de valencia y la química de los elementos, también cubre temas importantes como la estructura de la materia, la teoría cuántica, la estequiometría y la clasificación de las reacciones químicas. Asimismo, se destaca la inclusión de temas relacionados con la medición de las propiedades de la materia, la descripción de los sistemas dispersos, entre otros. El objetivo de este libro es brindar una base sólida de conocimientos en química inorgánica, que permita al lector comprender los principios y fundamentos teóricos que rigen esta disciplina, con un enfoque claro y didáctico. El libro proporciona un excelente recurso tanto para estudiantes como para docentes. Razón por la que, "Fundamentos Teóricos de Química Inorgánica" es una obra esencial para aquellos que deseen profundizar en el conocimiento de la química inorgánica y comprender mejor sus conceptos fundamentales.

Se establecen los principios bioquímicos fundamentales que rigen el desarrollo de las plantas, explorando la composición y estructura de sus células. Además, se aborda la fotosíntesis como un proceso metabólico esencial. El metabolismo de biomoléculas, que incluye el transporte de nutrientes y la síntesis de carbohidratos, lípidos, proteínas y otros compuestos, es analizado en profundidad. Asimismo, se abordan temáticas cruciales como la respiración celular en plantas, la biosíntesis de metabolitos secundarios y el papel de las hormonas vegetales en el crecimiento y desarrollo. La enzimología vegetal, con énfasis en la cinética enzimática, se presenta como un componente esencial del metabolismo vegetal. Además, se examinan los mecanismos de defensa de las plantas frente al estrés abiótico y biótico, abordando la morfogénesis y los desafíos que enfrentan las plantas en su entorno. El libro concluye con una visión hacia el futuro en la investigación de la bioquímica vegetal.

De transport- en overdrachtsprocessen van warmte, massa en impuls worden naar hun analogie behandeld. De processen worden beschreven met behulp van macro- en microbalansen die in veel gevallen leiden tot differentiaalvergelijkingen. Ook veel aspecten van stromingsleer komen op deze manier aan de orde en zo bereidt het boek ook voor op moderne Computational Fluid Dynamics technieken. Het doel van het boek is ook studenten te trainen in het oplossen van problemen waarbij transportverschijnselen centraal staan. Daartoe bevat het boek bijna 100 uitgewerkte vraagstukken.

This space collects OER materials on volcanoes and earthquakes and their associated hazards with a focus on the Pacific Northwest.

Course Description:GEO 212. Introduction to Meteorology (4 credit hour). Physical and chemical conditions that regulate global weather phenomena. Includes structure of the atmosphere, temperature, humidity, air pressure and winds, the development of weather systems, tornadoes and hurricanes, and the parameters that affect local and global climate. Laboratory includes image interpretation, field observation and prediction. This is formatted as an 8 week/module course.Learning Outcomes:1. Describe the origin and structure of the earth and its atmosphere. (1, 7)2. Use scientific reasoning to explain the relationship between the earth and sun and how solarand terrestrial radiation affects temperature, air pressure and wind patterns. (1, 2, 7, 8)3. Explain the role of heat, moisture and winds in generating clouds, precipitation and severeweather. (2-6, 8)4. Model major atmospheric circulation systems and oscillations. (1-8)5. Describe climatic regions and assess climate change predictions. (1-8)6. Interpret meteorological data to predict weather conditions. (1-8) 

Introductory course to Geospatial Science and GIS! Includes syllabus, modules, quizzes, labs, assignments, and activities for a 10-week course.

This course was originally designed as competency-based course and as such, it includes specific language related to CBE style instruction and is organized by competency so some terminology changes and course restructuring may be required in order to fit well into a quarterly schedule.

A Physical Geology Lab Manual for California Community Colleges by Branciforte and Haddad.