Ge 1
Earth and Environment
9 units (3-3-3)
|
third term
An introduction to the ideas and approaches of earth and planetary sciences, including both the special challenges and viewpoints of these kinds of science as well as the ways in which basic physics, chemistry, and biology relate to them. In addition to a wide-ranging lecture-oriented component, there will be a required field trip component (two weekend days). The lectures and topics cover such issues as solid Earth structure and evolution, plate tectonics, oceans and atmospheres, climate change, and the relationship between geological and biological evolution. Not offered on a pass/fail basis. Satisfies the menu requirement of the Caltech core curriculum.
Instructor:
Asimow
Ge 10
Frontiers in Geological and Planetary Sciences
2 units (2-0-0)
|
second term. The course may be taken multiple times
Weekly seminar by a member of the Division of Geological and Planetary Sciences or a visitor to discuss a topic of his or her current research at an introductory level. The course is designed to introduce students to research and research opportunities in the division and to help students find faculty sponsors for individual research projects. Graded pass/fail.
Instructor:
Clayton
Ge 11 a
Introduction to Earth and Planetary Sciences: Earth as a Planet
9 units (3-3-3)
|
first term
Systematic introduction to the physical and chemical processes that have shaped Earth as a planet over geological time, and the observable products of these processes - rock materials, minerals, land forms. Geophysics of Earth. Plate tectonics; earthquakes; igneous activity. Metamorphism and metamorphic rocks. Rock deformation and mountain building. Weathering, erosion, and sedimentary rocks. The causes and recent history of climate change. The course includes an overnight field trip and a weekly laboratory section focused on the identification of rocks and minerals and the interpretation of topographic and geological maps. Although Ge 11 abcd is designed as a sequence, any one term may be taken as a standalone course.
Instructor:
Farley
Ge 11 b
Introduction to Earth and Planetary Sciences: Earth and the Biosphere
9 units (3-3-3)
|
second term
Prerequisites: Ch 1 a.
Systematic introduction to the origin and evolution of life and its impact on the oceans, atmosphere, and climate of Earth. Topics covered include ancient Earth surface environments and the rise of atmospheric oxygen. Microbial and molecular evolution, photosynthesis, genes as fossils. Banded iron stones, microbial mats, stromatolites, and global glaciation. Biological fractionation of stable isotopes. Numerical calibration of the geological timescale, the Cambrian explosion, mass extinctions, and human evolution. The course usually includes one major field trip and laboratory studies of rocks, fossils, and geological processes. Although Ge 11 abcd is designed as a sequence, any one term may be taken as a standalone course. Biologists biologists are particularly welcome.
Instructors:
Fischer, Kirschvink
Ge/Ay 11 c
Introduction to Earth and Planetary Sciences: Planetary Sciences
9 units (3-0-6)
|
third term
Prerequisites: Ma 1 ab, Ph 1 ab.
A broad introduction to the present state and early history of the solar system, including terrestrial planets, giant planets, moons, asteroids, comets, and rings. Earth-based observations, observations by planetary spacecraft, study of meteorites, and observations of extrasolar planets are used to constrain models of the dynamical and chemical processes of planetary systems. Although Ge 11 abcd is designed as a sequence, any one term may be taken as a standalone course. Physicists and astronomers are particularly welcome.
Instructor:
Brown
Ge 11 d
Introduction to Earth and Planetary Sciences: Geophysics
9 units (3-0-6)
|
second term
Prerequisites: Ch 1, Ma 2 a, Ph 2 a.
An introduction to the geophysics of the solid earth; formation of planets; structure and composition of Earth; interactions between crust, mantle, and core; surface and internal dynamics; mantle convection; imaging of the interior; seismic tomography. Although Ge 11 abcd is designed as a sequence, any one term can be taken as a standalone course.
Instructors:
Clayton, Gurnis
FS/Ge 16
Freshman Seminar: Earthquakes
6 units (2-0-4)
|
first term
Earthquakes and volcanic eruptions constitute some of the world's major natural hazards. What is the science behind prediction and/or rapid response to these events? We will review the current understanding of the science, the efforts that have been made in earthquake and volcano forecasting, and real-time response to these events. We will learn about advances in earthquake preparation in Southern California, and volcanic eruption forecasting and hazard mitigation elsewhere. There is a required field trip to visit faults and volcanoes somewhere in southern California. Freshmen only; limited enrollment.
Instructor:
Stock
Ge 40
Special Problems for Undergraduates
Units to be arranged
|
any term
This course provides a mechanism for undergraduates to undertake honors-type work in the geologic sciences. By arrangement with individual members of the staff. Graded pass/fail.
Ge 41 abc
Undergraduate Research and Bachelor's Thesis
Units to be arranged
|
first, second, third terms
Guidance in seeking research opportunities and in formulating a research plan leading to preparation of a bachelor's thesis is available from the GPS option representatives. Graded pass/fail.
Ge 101
Introduction to Geology and Geochemistry
9 units (3-0-6)
|
first term
Prerequisites: graduate standing or instructor's permission.
A broad, high-level survey of geology and geochemistry with emphasis on quantitative understanding. Historical deduction in the geological and planetary sciences. Plate tectonics as a unifying theory of geology. Igneous and metamorphic processes, structural geology and geomorphology; weathering and sedimentary processes. Nucleosynthesis and chemical history of the solar system; distribution of the elements in the earth; isotopic systems as tracers and clocks; evolution of the biosphere; global geochemical and biogeochemical cycles; geochemical constraints on deep Earth structure. One mandatory overnight field trip, selected laboratory exercises, and problem sets.
Instructor:
Farley
Ge 102
Introduction to Geophysics
9 units (3-0-6)
|
second term
Prerequisites: Ma 2, Ph 2, or Ge 108, or equivalents.
An introduction to the physics of the earth. The present internal structure and dynamics of the earth are considered in light of constraints from the gravitational and magnetic fields, seismology, and mineral physics. The fundamentals of wave propagation in earth materials are developed and applied to inferring Earth structure. The earthquake source is described in terms of seismic and geodetic signals. The following are also considered: the contributions that heat-flow, gravity, paleomagnetic, and earthquake mechanism data have made to our understanding of plate tectonics, the driving mechanism of plate tectonics, and the energy sources of mantle convection and the geodynamo.
Instructors:
Clayton, Gurnis
Ge 103
Introduction to the Solar System
9 units (3-0-6)
|
third term
Prerequisites: instructor's permission.
Formation and evolution of the solar system. Interiors, surfaces, and atmospheres. Orbital dynamics, chaos, and tidal friction. Cratering. Comets and asteroids. Extrasolar planetary systems.
Instructor:
Brown
Ge 104
Introduction to Geobiology
9 units (3-0-6)
|
second term
Prerequisites: instructor's permission.
Lectures about the interaction and coevolution of life and Earth surface environments. We will cover essential concepts and major outstanding questions in the field of geobiology, and introduce common approaches to solving these problems. Topics will include biological fractionation of stable isotopes; history and operation of the carbon and sulfur cycles; evolution of oxygenic photosynthesis; biomineralization; mass extinctions; analyzing biodiversity data; constructing simple mathematical models constrained by isotope mass balance; working with public databases of genetic information; phlyogenetic techniques; microbial and molecular evolution.
Instructors:
Fischer, Kirschvink
Bi/Ge/ESE 105
Evolution
12 units (3-4-5)
|
second term
Prerequisites: Completion of Core Curriculum Courses. Maximum enrollment: 15, by application only.
The theory of evolution is arguably biology's greatest idea and serves as the overarching framework for thinking about the diversity and relationships between organisms. This course will present a broad picture of evolution starting with discussions of the insights of the great naturalists, the study of the genetic basis of variation, and an introduction to the key driving forces of evolution. Following these foundations, we will then focus on a number of case studies including the following: evolution of oxygenic photosynthesis, origin of eukaryotes, multicellularity, influence of symbiosis, the emergence of life from the water (i.e. fins to limbs), the return of life to the water (i.e. limbs to fins), diversity following major extinction events, the discovery of Archaea, insights into evolution that have emerged from sequence analysis, and finally human evolution and the impact of humans on evolution (including examples such as antibiotic resistance). A specific focus for considering these issues will be the island biogeography of the Galapagos. Given in alternate years; not offered 2016-17.
Instructors:
Phillips, Orphan
Ge 106
Introduction to Structural Geology
9 units (3-0-6)
|
second term
Prerequisites: Ge 11 ab.
Description and origin of main classes of deformational structures. Introduction to continuum mechanics and its application to rock deformation. Interpretation of the record of deformation of the earth's crust and upper mantle on microscopic, mesoscopic, and megascopic scales. Introduction to the tectonics of mountain belts.
Instructor:
Avouac
Ge 108
Applications of Physics to the Earth Sciences
9 units (3-0-6)
|
first term
Prerequisites: Ph 2 and Ma 2 or equivalent.
An intermediate course in the application of the basic principles of classical physics to the earth sciences. Topics will be selected from: mechanics of rotating bodies, the two-body problem, tidal theory, oscillations and normal modes, diffusion and heat transfer, wave propagation, electro- and magneto-statics, Maxwell's equations, and elements of statistical and fluid mechanics.
Instructor:
Brown
Ge 109
Oral Presentation
5 units (2-0-3)
|
third term
Practice in the effective organization and delivery of reports before groups. Successful completion of this course is required of all candidates for degrees in the division. Graded pass/fail.
Instructors:
Bikle, Rossman
Ge 110
Geographic Information System for Geology and Planetary Sciences
3 units (0-3-0)
|
first term
Formal introduction to modern computer-based geospatial analysis. Covers methods and applications of Geographic Information Systems (GIS) in Earth and planetary sciences in the form of practical lab exercises using the ArcGIS software package and a variety of geo-referenced data (Digital Elevation Models, geodetic measurements, satellite images, geological maps). Not offered 2016-17.
Ge 111 ab
Applied Geophysics Seminar and Field Course
6 units (3-3-0)
|
second term
Prerequisites: instructor's permission. 9 units (0-3-6); spring break, third term. Prerequisite: Ge 111 a.
An introduction to the theory and application of basic geophysical field techniques consisting of a comprehensive survey of a particular field area using a variety of methods (e.g., gravity, magnetic, electrical, GPS, seismic studies, and satellite remote sensing). The course will consist of a seminar that will discuss the scientific background for the chosen field area, along with the theoretical basis and implementation of the various measurement techniques. The 4-5-day field component will be held in spring break, and the data analysis component is covered in Ge 111 b. May be repeated for credit with an instructor's permission.
Instructors:
Clayton, Simons
Ge 112
Sedimentology and Stratigraphy
12 units (3-5-4)
|
first term
Prerequisites: Ge 11 ab.
Systematic analysis of transport and deposition in sedimentary environments and the resulting composition, texture, and structure of both clastic and chemical sedimentary rocks. The nature and genesis of sequence architecture of sedimentary basins and cyclic aspects of sedimentary accumulation will be introduced. Covers the formal and practical principles of definition of stratigraphic units, correlation, and the construction of a geologic timescale. Field trip and laboratory exercises. Given in alternate years; not offered 2016-17.
Instructor:
Grotzinger
Ge 114 a
Mineralogy
9 units (3-4-2)
|
first term
Atomic structure, composition, physical properties, occurrence, and identifying characteristics of the major mineral groups. The laboratory work involves the characterization and identification of important minerals by their physical and optical properties.
Instructor:
Rossman
Ge 114 b
Mineralogy Laboratory
3 units (0-2-1)
|
first term
Prerequisites: concurrent enrollment in Ge 114 a or instructor's permission.
Additional laboratory studies of optical crystallography and the use of the petrographic microscope.
Instructor:
Rossman
Ge 115 a
Petrology and Petrography: Igneous Petrology
9 units (3-3-3)
|
second term
Prerequisites: Ge 114 ab.
Study of the origin, occurrence, tectonic significance and evolution of igneous rocks with emphasis on use of phase equilibria and geochemistry. Given in alternate years; not offered 2016-17.
Instructor:
Stolper
Ge 115 b
Petrology and Petrography: Metamorphic Petrology
9 units (3-3-3)
|
second term
Prerequisites: Ge 114 ab.
The mineralogic and chemical composition, occurrence, and classification of metamorphic rocks; interpretation of mineral assemblages in the light of chemical equilibrium and experimental studies. Discussion centers on the use of metamorphic assemblages to understand tectonic, petrologic, and geochemical problems associated with convergent plate boundaries and intrusion of magmas into the continental crust. May be taken before Ge 115 a. Given in alternate years; offered 2016-17.
Instructor:
Eiler
Ge 116
Analytical Techniques Laboratory
9 units (1-4-4)
|
second term
Prerequisites: Ge 114 a or instructor's permission.
Methods of quantitative laboratory analysis of rocks, minerals, and fluids in geological and planetary sciences. Consists of five intensive two-week modules covering scanning electron microscopy (imaging, energy-dispersive X-ray spectroscopy, electron backscatter diffraction); the electron microprobe (wavelength-dispersive X-ray spectroscopy); X-ray powder diffraction; optical, infrared, and Raman spectroscopy; and plasma source mass spectrometry for elemental and radiogenic isotope analysis. Satisfies the Institute core requirement for an additional introductory laboratory course.
Instructors:
Asimow, Jackson, Rossman, staff
Ge/Ay 117
Statistics and Data Analysis
9 units (3-0-6)
|
second term
Prerequisites: CS 1 and instructors permission..
In modern fields of planetary science and astronomy, vast quantities of data are often available to researchers. The challenge is converting this information into meaningful knowledge about the universe. The primary focus of this course is the development of a broad and general tool set that can be applied to the student's own research. We will use case studies from the astrophysical and planetary science literature as our guide as we learn about common pitfalls, explore strategies for data analysis, understand how to select the best model for the task at hand, and learn the importance of properly quantifying and reporting the level of confidence in one's conclusions.
Instructor:
Knutson
Ge/ESE 118
Methods in Data Analysis
9 units (3-0-6)
|
first term
Prerequisites: Ma 1 or equivalent.
Introduction to methods in data analysis. Course will be an overview of different ways that one can quantitatively analyze data, and will not focus on any one methodology. Topics will include linear regression, least squares inversion, Fourier analysis, principal component analysis, and Bayesian methods. Emphasis will be on both a theoretical understanding of these methods and on practical applications. Exercises will include using numerical software to analyze real data.
Instructor:
Tsai
Ge 120 a
Field Geology: Introduction to Field Geology
6 units (1-5-0)
|
third term
Prerequisites: Ge 11 ab, Ge 106 (may be taken concurrently with Ge 106).
A comprehensive introduction to methods of geological field mapping in preparation for summer field camp. Laboratory exercises introduce geometrical and graphical techniques in the analysis of geologic maps. Field trips introduce methods of geological mapping.
Instructor:
Wernicke
Ge 120 b
Field Geology: Summer Field Camp
18 units (0-18-0)
|
summer
Prerequisites: Ge 120 a or instructor's permission.
Intensive three-week field course in a well-exposed area of the southwestern United States covering techniques of geologic field observation, documentation, and analysis. Field work begins immediately following Commencement Day in June.
Instructor:
Wernicke
Ge 121 abc
Advanced Field Geology
12 units (0-9-3)
|
first, second, third terms
Prerequisites: Ge 120 or equivalent, or instructor's permission.
Field mapping and supporting laboratory studies in topical problems related to the geology of the southwestern United States. Course provides a breadth of experience in igneous, metamorphic, or sedimentary rocks or geomorphology. Multiple terms of 121 may be taken more than once for credit if taught by different instructors.
Instructors:
Avouac (a), Kirschvink (b), Wernicke (c)
Ge 122 a
Field Geology Seminar
6 (1-3-2)
|
first term
Prerequisites: Ge 11ab or Ge 101, or instructor's permission.
Each term, a different field topic in Southern California will be examined in both seminar and field format. Relevant readings will be discussed in a weekly class meeting. During the 3-day weekend field trip we will examine field localities relevant to the topic, to permit detailed discussion of the observations. Fall term 2016 topic: supervolcano eruptions. Class can be taken more than once because the content is different each time. Graded pass/fail.
Instructor:
Stock
Ge 124 a
Paleomagnetism and Magnetostratigraphy
6 units (0-0-6)
|
third term
Application of paleomagnetism to the solution of problems in stratigraphic correlation and to the construction of a high-precision geological timescale. A field trip to the southwest United States or Mexico to study the physical stratigraphy and magnetic zonation, followed by lab analysis. Given in alternate years; offered 2016-17.
Instructor:
Kirschvink
Ge 124 b
Paleomagnetism and Magnetostratigraphy
9 units (3-3-3)
|
third term
Prerequisites: Ge 11 ab.
The principles of rock magnetism and physical stratigraphy; emphasis on the detailed application of paleomagnetic techniques to the determination of the history of the geomagnetic field. Given in alternate years; offered 2016-17.
Instructor:
Kirschvink
Ge 125
Geomorphology
12 units (3-5-4)
|
first term
Prerequisites: Ge 11 a or instructor's permission.
A quantitative examination of landforms, runoff generation, river hydraulics, sediment transport, erosion and deposition, hillslope creep, landslides and debris flows, glacial processes, and submarine and Martian landscapes. Field and laboratory exercises are designed to facilitate quantitative measurements and analyses of geomorphic processes. Given in alternate years; offered 2016-17.
Instructor:
Lamb
Ge 126
Topics in Earth Surface Processes
6 units (2-0-4)
|
second term
A seminar-style course focusing on a specific theme within geomorphology and sedimentology depending on student interest. Potential themes could include river response to climate change, bedrock erosion in tectonically active mountain belts, or delta evolution on Earth and Mars. The course will consist of student-led discussions centered on readings from peer-reviewed literature.
Instructor:
Lamb
Ge/Ch 127
Nuclear Chemistry
9 units (3-0-6)
|
first term
Prerequisites: instructor's permission.
A survey course in the properties of nuclei, and in atomic phenomena associated with nuclear-particle detection. Topics include rates of production and decay of radioactive nuclei; interaction of radiation with matter; nuclear masses, shapes, spins, and moments; modes of radioactive decay; nuclear fission and energy generation. Given in alternate years; not offered 2016-17.
Instructor:
Burnett
Ge/Ch 128
Cosmochemistry
9 units (3-0-6)
|
third term
Prerequisites: instructor's permission.
Examination of the chemistry of the interstellar medium, of protostellar nebulae, and of primitive solar-system objects with a view toward establishing the relationship of the chemical evolution of atoms in the interstellar radiation field to complex molecules and aggregates in the early solar system that may contribute to habitability. Emphasis will be placed on identifying the physical conditions in various objects, timescales for physical and chemical change, chemical processes leading to change, observational constraints, and various models that attempt to describe the chemical state and history of cosmological objects in general and the early solar system in particular. Given in alternate years; not offered 2016-17.
Ge 131
Planetary Structure and Evolution
9 units (3-0-6)
|
third term
Prerequisites: instructor's permission.
A critical assessment of the physical and chemical processes that influence the initial condition, evolution, and current state of planets, including our planet and planetary satellites. Topics to be covered include a short survey of condensed-matter physics as it applies to planetary interiors, remote sensing of planetary interiors, planetary modeling, core formation, physics of ongoing differentiation, the role of mantle convection in thermal evolution, and generation of planetary magnetic fields.
Instructor:
Stevenson
Ge/Ay 132
Atomic and Molecular Processes in Astronomy and Planetary Sciences
9 units (3-0-6)
|
first term
Prerequisites: instructor's permission.
Fundamental aspects of atomic and molecular spectra that enable one to infer physical conditions in astronomical, planetary, and terrestrial environments. Topics will include the structure and spectra of atoms, molecules, and solids; transition probabilities; photoionization and recombination; collisional processes; gas-phase chemical reactions; and isotopic fractionation. Each topic will be illustrated with applications in astronomy and planetary sciences, ranging from planetary atmospheres and dense interstellar clouds to the early universe. Given in alternate years; offered 2016-17.
Instructor:
Blake
Ge/Ay 133
The Formation and Evolution of Planetary Systems
9 units (3-0-6)
|
first term
Review current theoretical ideas and observations pertaining to the formation and evolution of planetary systems. Topics to be covered include low-mass star formation, the protoplanetary disk, accretion and condensation in the solar nebula, the formation of gas giants, meteorites, the outer solar system, giant impacts, extrasolar planetary systems.
Instructors:
Knutson, Batygin
Ge 136 abc
Regional Field Geology of the Southwestern United States
3 units (1-0-2)
|
first, second, or third terms, by announcement
Prerequisites: Ge 11 ab or Ge 101, or instructor's permission.
Includes approximately three days of weekend field trips into areas displaying highly varied geology. Each student is assigned the major responsibility of being the resident expert on a pertinent subject for each trip. Graded pass/fail.
Instructor:
Kirschvink
Ge/Ay 137
Planetary Physics
9 units (3-0-6)
|
second term
Prerequisites: Ph 106 abc, ACM 95/100 ab.
A quantitative review of dynamical processes that characterize long-term evolution of planetary systems. An understanding of orbit-orbit resonances, spin-orbit resonances, secular exchange of angular momentum and the onset of chaos will be developed within the framework of Hamiltonian perturbation theory. Additionally, dissipative effects associated with tidal and planet-disk interactions will be considered.
Instructor:
Batygin
Ge/ESE 139
Introduction to Atmospheric Radiation
9 units (3-0-6)
|
second term
The basic physics of absorption and scattering by molecules, aerosols, and clouds. Theory of radiative transfer. Band models and correlated-k distributions and scattering by cloud and aerosol particles. Solar insolation, thermal emission, heating rates, and examples of applications to climate and remote sensing of Earth, planets and exoplanets. Given in alternate years; not offered 2016-17.
Ge 140 a
Stable Isotope Geochemistry
9 units (3-0-6)
|
second term
An introduction to the principles and applications of stable isotope systems to earth science, emphasizing the physical, chemical and biological processes responsible for isotopic fractionation, and their underlying chemical-physics principles. Topics include the kinetic theory of gases and related isotopic fractionations, relevant subjects in quantum mechanics and statistical thermodynamics, equations of motion of charged particles in electrical and magnetic fields (the basis of mass spectrometry), the photochemistry of isotopic species, and applications to the earth, environmental and planetary sciences. Taught in odd years; alternates with Ge 140b. Offered 2016-17.
Instructor:
Eiler
Ge 140 b
Radiogenic Isotope Geochemistry
9 units (3-0-6)
|
second term
An introduction to the principles and applications of radiogenic isotope systems in earth science. Topics to be covered include radioactive decay phenomena, geochronometry, isotopes as tracers of solar system and planetary evolution, extinct radioactivities, and cosmogenic isotopes. Taught in even years; alternates with Ge 140a. Not offered 2016-17.
Instructor:
Farley
Ge/ESE 140 c
Stable Isotope Biogeochemistry
9 units (3-0-6)
|
third term
Prerequisites: Ge 140a or equivalent.
An introduction to the use of stable isotopes in biogeochemistry, intended to give interested students the necessary background to understand applications in a variety of fields, from modern carbon cycling to microbial ecology to records of Ancient Earth. Topics include the principles of isotope distribution in reaction networks; isotope effects in enzyme-mediated reactions, and in metabolism and biosynthesis; characteristic fractionations accompanying carbon, nitrogen, and sulfur cycling; and applications of stable isotopes in the biogeosciences. Not offered 2016-17.
Instructor:
Sessions
Ge/ESE 143
Organic Geochemistry
9 units (3-2-4)
|
first term
Prerequisites: Ch 41 a or equivalent.
Main topics include the analysis, properties, sources, and cycling of natural organic materials in the environment, from their production in living organisms to burial and decomposition in sediments and preservation in the rock record. Specific topics include analytical methods for organic geochemistry, lipid structure and biochemistry, composition of organic matter, factors controlling organic preservation, organic climate and CO2 proxies, diagenesis and catagenesis, and biomarkers for ancient life. A laboratory component (three evening labs) teaches the extraction and analysis of modern and ancient organic biomarkers by GC/MS. Class includes a mandatory one-day (weekend) field trip to observe the Monterey Formation. Taught in even-numbered years; offered 2016-17.
Instructor:
Sessions
Ge 145
Isotope-Ratio Mass Spectrometry
9 units (1-4-4)
|
first term
This class provides a hands-on introduction to the construction and operating principles of instrumentation used for isotope-ratio mass spectrometry. The class is structured as a 1-hour lecture plus 4-hour lab each week examining the major subsystems of an IRMS, including vacuum systems, ionization source, mass analyzer, and detector. Laboratories involve hands-on deconstruction and re-assembly of a retired IRMS instrument to examine its components. Course is limited to 6 students at the discretion of the instructor, with preference given to graduate students using this instrumentation in their research. Taught in odd-numbered years; not offered 2016-17.
Instructor:
Sessions
Ge/ESE 149
Marine Geochemistry
9 units (3-0-6)
|
third term
Prerequisites: ESE 102.
Introduction to chemical oceanography and sediment geochemistry. We will address the question "Why is the ocean salty?" by examining the processes that determine the major, minor, and trace element distributions of seawater and ocean sediments. Topics include river and estuarine chemistry, air/sea exchange, nutrient uptake by the biota, radioactive tracers, redox processes in the water column and sediments, carbonate chemistry, and ventilation. Given in alternate years; not offered 2016-17.
Ge/ESE 150
Planetary Atmospheres
9 units (3-0-6)
|
second term
Prerequisites: Ch 1, Ma 2, Ph 2, or equivalents.
Origin of planetary atmospheres, escape, and chemical evolution. Tenuous atmospheres: the moon, Mercury, and outer solar system satellites. Comets. Vapor-pressure atmospheres: Triton, Io, and Mars. Spectrum of dynamical regimes on Mars, Earth, Venus, Titan, and the gas giant planets.
Instructor:
Ingersoll
Ge 151
Planetary Surfaces
9 units (3-3-3)
|
first term
Exogenous (impact cratering, space weathering) and endogenous (tectonic, volcanic, weathering, fluvial, aeolian, and periglacial) processes shape the surfaces of planets. We will review the mechanisms responsible for the formation and modification of the surfaces of solar system bodies, studying both composition and physical processes.
Instructor:
Ehlmann
Ge/ESE 154
Readings in Paleoclimate
3 units (1-0-2)
|
second term
Prerequisites: instructor's permission.
Lectures and readings in areas of current interest in paleoceanography and paleoclimate.
Instructor:
Adkins
Ge/ESE 155
Paleoceanography
9 units (3-0-6)
|
third term
Prerequisites: ESE 102.
Evaluation of the data and models that make up our current understanding of past climates. Emphasis will be placed on a historical introduction to the study of the past ten thousand to a few hundred thousand years, with some consideration of longer timescales. Evidence from marine and terrestrial sediments, ice cores, corals, and speleothems will be used to address the mechanisms behind natural climate variability. Models of this variability will be evaluated in light of the data. Topics will include sea level and ice volume, surface temperature evolution, atmospheric composition, deep ocean circulation, tropical climate, ENSO variability, and terrestrial/ocean linkages. Given in alternate years; offered 2016-17.
Instructor:
Adkins
Ge 156
Topics in Planetary Surfaces
6 units (3-0-3)
|
Offered by announcement only
Reading about and discussion of current understanding of the surface of a selected terrestrial planet, major satellite, or asteroid. Important "classic" papers will be reviewed, relative to the data that are being returned from recent and current missions. May be repeated for credit.
Ge/EE/ESE 157 c
Remote Sensing for Environmental and Geological Applications
9 units (3-3-3)
|
third term
Analysis of electromagnetic radiation at visible, infrared, and radio wavelengths for interpretation of the physical and chemical characteristics of the surfaces of Earth and other planets. Topics: interaction of light with materials, spectroscopy of minerals and vegetation, atmospheric removal, image analysis, classification, and multi-temporal studies. This course does not require but is complementary to EE 157ab with emphasis on applications for geological and environmental problems, using data acquired from airborne and orbiting remote sensing platforms. Students will work with digital remote sensing datasets in the laboratory and there will be one field trip.
Instructor:
Ehlmann
Ge/Ay 159
Planetary Evolution and Habitability
9 units (3-0-6)
|
second term
Photochemistry of planetary atmospheres, comparative planetology, atmospheric evolution. What makes Earth habitable? Remote sensing of extrasolar planets, biosignatures. Given in alternate years; offered 2016-17.
Instructor:
Yung
Ae/Ge/ME 160 a
Continuum Mechanics of Fluids and Solids
9 units (3-0-6)
|
first term
Elements of Cartesian tensors. Configurations and motions of a body. Kinematics-study of deformations, rotations and stretches, polar decomposition. Lagrangian and Eulerian strain velocity and spin tensor fields. Irrotational motions, rigid motions. Kinetics-balance laws. Linear and angular momentum, force, traction stress. Cauchy's theorem, properties of Cauchy's stress. Equations of motion, equilibrium equations. Power theorem, nominal (Piola-Kirchoff) stress. Thermodynamics of bodies. Internal energy, heat flux, heat supply. Laws of thermodynamics, notions of entropy, absolute temperature. Entropy inequality (Clausius-Duhem). Examples of special classes of constitutive laws for materials without memory. Objective rates, corotational, convected rates. Principles of materials frame indifference. Examples: the isotropic Navier-Stokes fluid, the isotropic thermoelastic solid. Basics of finite differences, finite elements, and boundary integral methods, and their applications to continuum mechanics problems illustrating a variety of classes of constitutive laws.
Instructor:
Lapust
Ge 161
Plate Tectonics
9 units (3-0-6)
|
first term
Prerequisites: Ge 11 ab or equivalent.
Geophysical and geological observations related to plate tectonic theory. Instantaneous and finite motion of rigid plates on a sphere; marine magnetic and paleomagnetic measurements; seismicity and tectonics of plate boundaries; reference frames and absolute plate motions. Interpretations of geologic data in the context of plate tectonics; plate tectonic evolution of the ocean basins.
Instructor:
Stock
Ge 162
Seismology
9 units (3-0-6)
|
second term
Prerequisites: ACM 95/100 ab or equivalent.
Review of concepts in classical seismology. Topics to be covered: basic theories of wave propagation in the earth, instrumentation, Earth's structure and tomography, theory of the seismic source, physics of earthquakes, and seismic risk. Emphasis will be placed on how quantitative mathematical and physical methods are used to understand complex natural processes, such as earthquakes.
Instructors:
Clayton, Tsai, Zhan
Ge 163
Geodynamics
9 units (3-0-6)
|
third term
Prerequisites: Ae/Ge/ME 160 ab.
Quantitative introduction to the dynamics of the earth, including core, mantle, lithosphere, and crust. Mechanical models are developed for each of these regions and compared to a variety of data sets. Potential theory applied to the gravitational and geomagnetic fields. Special attention is given to the dynamics of plate tectonics and the earthquake cycle.
Instructor:
Gurnis
Ge 164
Mineral Physics
9 units (3-0-6)
|
second term
Prerequisites: Ge 11 ad or equivalent, or instructor's permission.
Introduction to the mineral physics of Earth's interior. Topics covered: mineralogy and phase transitions at high pressures and temperatures; elasticity and equations of state; vibrational, electronic, and transport properties; application of mineral physics data to Earth and planetary interiors.
Instructor:
Jackson
Ge 165
Geophysical Data Analysis
9 units (3-0-6)
|
third term
Prerequisites: basic linear algebra and Fourier transforms.
Introduction to modern digital analysis: discrete Fourier transforms, Z-transforms, filters, deconvolution, auto-regressive models, spectral estimation, basic statistics, 1-D wavelets, model fitting via singular value decomposition. Not offered 2016-17.
Ge 166
Hydrology
9 units (3-0-6)
|
third term
Prerequisites: Math 1 or equivalent.
Introduction to hydrology. Focus will be on how water moves on earth, including in groundwater, rivers, oceans, glaciers, and the atmosphere. Class will be based in fluid mechanics, which will be covered. Specific topics will include the Navier-Stokes equation, Darcy's law, aquifer flow, contaminant transport, turbulent flow, gravity waves, tsunami propagation, geostrophic currents, Ekman transport, glacier flow laws, and the Hadley circulation. Given in alternate years, not offered 2016-17.
Instructor:
Tsai
Ge 167
Tectonic Geodesy
9 units (3-0-6)
|
fall term
Prerequisites: a working knowledge of unix/linux or equivalent, linear algebra, and coursework in geophysics.
An introduction to the use of modern geodetic observations (e.g., GPS and InSAR) to constrain crustal deformation models. Secular velocity fields, coseismic and time-dependent processes; volcano deformation and seasonal loading phenomena. Basic inverse approaches for parameter estimation and basic temporal filtering algorithms. Given in alternate years; not offered 2016-17.
Instructor:
Simons
Ge 168
Crustal Geophysics
9 units (3-0-6)
|
third term
Prerequisites: ACM 95/100 or equivalent, or instructor's permission.
The analysis of geophysical data related to crust processes. Topics include reflection and refraction seismology, tomography, receiver functions, surface waves, and gravity. Not offered 2016-17.
Instructor:
Clayton
Ge 169 abcd
Readings in Geophysics
6 units (3-0-3)
|
first, second, third, fourth terms
Reading courses are offered to teach students to read critically the work of others and to broaden their knowledge about specific topics. Each student will be required to write a short summary of each paper that summarizes the main goals of the paper, to give an assessment of how well the author achieved those goals, and to point out related issues not discussed in the paper. Each student will be expected to lead the discussion on one or more papers. The leader will summarize the discussion on the paper(s) in writing. A list of topics offered each year will be posted on the Web. Individual terms may be taken for credit multiple times without regard to sequence.
Instructor:
Staff
Ge/ESE 170
Microbial Ecology
9 units (3-2-4)
|
third term
Prerequisites: Either ESE/Bi 166 or ESE/Bi 168.
Structural, phylogenetic, and metabolic diversity of microorganisms in nature. The course explores microbial interactions, relationships between diversity and physiology in modern and ancient environments, and influence of microbial community structure on biogeochemical cycles. Introduction to ecological principles and molecular approaches used in microbial ecology and geobiological investigations. Offered in alternate years, offered 2016-17.
Instructor:
Orphan
ESE/Ge/Ch 171
Atmospheric Chemistry I
9 units (3-0-6)
|
third term
Prerequisites: Ch 1 or equivalent.
A detailed course about chemical transformation in Earth's atmosphere. Kinetics, spectroscopy, and thermodynamics of gas-phase chemistry of the stratosphere and troposphere; sources, sinks, and lifetimes of trace atmospheric species; stratospheric ozone chemistry; oxidation mechanisms in the troposphere.
Instructors:
Seinfeld, Sanders
ESE/Ge/Ch 172
Atmospheric Chemistry II
3 units (3-0-0)
|
first term
Prerequisites: ESE/Ge/Ch 171 or equivalent.
A lecture and discussion course about active research in atmospheric chemistry. Potential topics include halogen chemistry of the stratosphere and troposphere; aerosol formation in remote environments; coupling of dynamics and photochemistry; development and use of modern remote-sensing and in situ instrumentation. Graded pass/fail. Not offered 2016-17.
CE/ME/Ge 173
Mechanics of Soils
9 units (3-0-6)
|
second term
Prerequisites: Continuum Mechanics - Ae/Ge/ME 160a.
Basic principles of stiffness, deformation, effective stress and strength of soils, including sands, clays and silts. Elements of soil behavior such as stress-strain-strength behavior of clays, effects of sample disturbance, anisotropy, and strain rate; strength and compression of granular soils; consolidation theory and settlement analysis; and critical state soil mechanics. Not offered 2016-17.
ME/CE/Ge 174
Mechanics of Rocks
9 units (3-0-6)
|
third term
Prerequisites: Ae/Ge/ME 160a.
Basic principles of deformation, strength, and stressing of rocks. Elastic behavior, plasticity, viscoelasticity, viscoplasticity, creep, damage, friction, failure mechanisms, shear localization, and interaction of deformation processes with fluids. Engineering and geological applications. Not offered 2016-17.
Ge 177
Active Tectonics
12 units (3-3-6)
|
third term
Prerequisites: Ge 112 and Ge 106 or equivalent.
Introduction to techniques for identifying and quantifying active tectonic processes. Geomorphology, stratigraphy, structural geology, and geodesy applied to the study of active faults and folds in a variety of tectonic settings. Relation of seismicity and geodetic measurements to geologic structure and active tectonics processes. Review of case studies of selected earthquakes. Offered in alternate years; not offered 2016-17.
Instructor:
Avouac
Ge 190
The Nature and Evolution of the Earth
Units to be arranged
|
Offered by announcement only
Advanced-level discussions of problems of current interest in the earth sciences. Students may enroll for any or all terms of this course without regard to sequence.
Instructor:
Staff
Ge 191
Special Topics in Geochemistry
Units to be arranged
|
Offered by announcement only
Advanced-level discussions of problems of current interest in geochemistry. Students may enroll for any or all terms of this course without regard to sequence.
Instructor:
Staff
Ge 192
Special Topics in the Geological Sciences
Units to be arranged
|
Offered by announcement only
Advanced-level discussions of problems of current interest in the geological sciences. Students may enroll for any or all terms of this course without regard to sequence.
Instructor:
Staff
Ge 193
Special Topics in Geophysics
Units to be arranged
|
Offered by announcement only
Advanced-level discussions of problems of current interest in geophysics. Students may enroll for any or all terms of this course without regard to sequence.
Instructor:
Staff
Ge 194
Special Topics in the Planetary Sciences
Units to be arranged
|
Offered by announcement only
Advanced-level discussions of problems of current interest in planetary sciences. Students may enroll for any or all terms of the course without regard to sequence.
Instructor:
Staff
Ge 195
Special Topics in Field Geology
Units to be arranged
|
Offered by announcement
Field experiences in different geological settings. Supporting lectures will usually occur before and during the field experience. This course will be scheduled only when special opportunities arise. Class may be taken more than once.
Instructor:
Staff
Ge 196
Special Topics in Atmospheres and Oceans
Units to be arranged
|
Offered by announcement only
Advanced-level discussions of problems of current interest in atmospheric and ocean sciences.
Instructor:
Staff
Ge 197
Special Topics in Geobiology: Concepts and Application of Aquatic Geochemistry in Geomicrobiology
9 units (3-0-6)
|
first term
Concepts of aquatic chemistry relevant to understanding microbe/environmental interactions. Topics include dissolved inorganic carbon and phosphate buffers, Henry's Law, redox equilibria, Eh-pH diagrams and measurements, adsorption, organic colloids, mineral precipitation, microbial life under extreme energy limitation, and clay mineral redox transformations.
Instructor:
Kappler
Ay/Ge 198
Special Topics in the Planetary Sciences
9 units (3-0-6)
|
third term
Topic for 2015-16 is Extrasolar Planets. Thousands of planets have been identified in orbit around other stars. Astronomers are now embarking on understanding the statistics of extrasolar planet populations and characterizing individual systems in detail, namely star-planet, planet-planet and planet-disk dynamical interactions, physical parameters of planets and their composition, weather phenomena, etc. Direct and indirect detection techniques are now completing the big picture of extra-solar planetary systems in all of their natural diversity. The seminar-style course will review the state of the art in exoplanet science, take up case studies, detail current and future instrument needs, and anticipate findings. Not Offered 2016-17.
Ge 211
Applied Geophysics II
Units to be arranged
Prerequisites: instructor's permission.
Intensive geophysical field experience in either marine or continental settings. Marine option will include participation in a student training cruise, with several weeks aboard a geophysical research vessel, conducting geophysical measurements (multibeam bathymetry, gravity, magnetics, and/or seismics), and processing and interpreting the data. Supporting lectures and problem sets on the theoretical basis of the relevant geophysical techniques and the tectonic background of the survey area will occur before and during the training cruise. The course might be offered in a similar format in other isolated situations. The course will be scheduled only when opportunities arise and this usually means that only six months' notice can be given. Auditing not permitted. Class may be taken more than once.
Instructors:
Stock, Clayton, Gurnis
Ge 212
Thermodynamics of Geological Systems
9 units (3-0-6)
|
first term
Prerequisites: Either Ch 21 abc, Ge 115 a, or equivalents.
Chemical thermodynamics as applied to geological and geochemical problems. Classical thermodynamics, including stability criteria, homogeneous and heterogeneous equilibria, equilibria subject to generalized constraints, equations of state, ideal and non-ideal solutions, redox systems, and electrolyte conventions. Brief discussion of statistical foundations and an introduction to the thermodynamics of irreversible processes. Given in alternate years; not offered 2016-17.
Instructor:
Asimow
Ge 214
Spectroscopy of Minerals
9 units (3-0-6)
|
third term
Prerequisites: Ge 114 a, Ch 21 ab, or instructor's permission.
An overview of the interaction of minerals with electromagnetic radiation from gamma rays to microwaves. Particular emphasis is placed on visible, infrared, Raman, and Mössbauer spectroscopies as applied to mineralogical problems such as phase identification, chemical analysis, site populations, and origin of color and pleochroism. Given in alternate years; offered 2016-17.
Instructor:
Rossman
Ge 215
Topics in Advanced Petrology
12 units (4-0-8)
|
first term
Prerequisites: Ge 115 ab or instructor's permission.
Lectures, readings, seminars, and/or laboratory studies in igneous or metamorphic petrology, paragenesis, and petrogenesis. The course may cover experimental, computational, or analytical methods. Format and content are flexible according to the needs of the students. Given in alternate years; offered 2016-17.
Instructor:
Asimow
Ge 217
Radiogenic Isotopes Seminar
6 units (3-0-3)
|
second term
Prerequisites: Ge 140 or permission of instructor.
The course deals with advanced topics in radiogenic isotope geochemistry and builds on Ge 140, addressing unconventional applications of radioisotopes as well as treating several conventional radiogenic systems in more detail. Each unit begins with a lecture on the history of the system followed by guided discussion of current developments. Special topics include the history of radiogenic isotope geochemistry at Caltech, U-series dating of sediments, high precision U-Pb and 40Ar/39Ar geochronology, and heavy noble gases. Given in alternate years; offered 2016-17.
Instructor:
Farley
Ge 218
Stable Isotopes Seminar
6 units (3-0-3)
|
second term
Prerequisites: Ge 140 or permission of instructor.
The course deals with advanced topics in stable isotope geochemistry and builds on Ge 140. The course will explore in depth the theory and applications of a subject in stable isotope geochemistry, selected by consensus of the enrolled students at or before the beginning of term. Example subjects could include: stable isotope thermometry; paleoclimate studies; paleoaltimetry; the early solar system; terrestrial weathering; photochemistry; or biosynthetic fractionations. The class will read and discuss classic papers in that subject area, supplemented with instructor lectures and broader background reading. All participants will lead discussions of papers and present one lecture on a relevant subject. Given in alternate years; not offered 2016-2017.
Instructor:
Eiler
CE/Ge/ME 222
Earthquake Source Processes, Debris Flows, and Soil Liquefaction: Physics-based Modeling of Failure in Granular Media
6 units (2-0-4)
|
third term
A seminar-style course focusing on granular dynamics and instabilities as they relate to geophysical hazards such as fault mechanics, debris flows, and liquefaction. The course will consist of student-led presentations of active research at Caltech and discussions of recent literature. Not offered 2016-2017.
Ge 232
Chemistry of the Solar System
9 units (3-0-6)
|
first term
Prerequisites: instructor's permission.
The isotopic and elemental compositions of extraterrestrial materials provide clues to conditions, events, and processes during the formation of the solar system. Specific topics include: solar elemental and isotopic compositions; chronology from short-lived nuclei; the unique role of volatile elements; pre-solar grains from meteorites; chondritic meteorite components as clues to solar nebula and asteroid evolution; interplanetary and comet coma dust; asteroidal igneous rocks; overview of lunar materials. Given in alternate years; offered 2016-17.
Instructor:
Burnett
Ge/Bi 244
Paleobiology Seminar
6 units (3-0-3)
|
third term
Critical reviews and discussion of classic investigations and current research in paleoecology, evolution, and biogeochemistry.
Instructor:
Kirschvink
Ge/Bi/ESE 246
Molecular Geobiology Seminar
6 units (2-0-4); second term
|
Recommended preparation: ESE/Bi 166
Critical reviews and discussion of classic papers and current research in microbiology and geomicrobiology. As the topics will vary from year to year, it may be taken multiple times.
Instructor:
Orphan
Ge 261
Advanced Seismology
9 units (3-0-6)
|
third term
Continuation of Ge 162 with special emphasis on particular complex problems; includes generalizations of analytical methods to handle nonplanar structures and methods of interfacing numerical-analytical codes in two and three dimensions; construction of Earth models using tomographic methods and synthetics. Requires a class project.
Instructors:
Helmberger, Zhan
Ge 263
Computational Geophysics
9 units (3-0-6); second term
|
Prerequisites: introductory class in geophysics, class in partial differential equations, some programming experience
Finite-difference, pseudo-spectral, finite-element, and spectral-element methods will be presented and applied to a number of geophysical problems including heat flow, deformation, and wave propagation. Students will program simple versions of methods. Given in alternate years; not offered 2016-17.
ME/Ge/Ae 266 ab
Dynamic Fracture and Frictional Faulting
9 units (3-0-6)
|
second, third terms
Prerequisites: Ae/AM/CE/ME 102 abc or Ae/Ge/ME 160 ab or instructor's permission.
Introduction to elastodynamics and waves in solids. Dynamic fracture theory, energy concepts, cohesive zone models. Friction laws, nucleation of frictional instabilities, dynamic rupture of frictional interfaces. Radiation from moving cracks. Thermal effects during dynamic fracture and faulting. Crack branching and faulting along nonplanar interfaces. Related dynamic phenomena, such as adiabatic shear localization. Applications to engineering phenomena and physics and mechanics of earthquakes.
Instructor:
Lapusta
Ge 270
Continental Tectonics
9 units (3-0-6)
|
third term
Prerequisites: ACM 95/100 or ACM 113; Ge 11 ab, Ge 106, Ge 162, or Ge 161.
The nature of nonplate, finite deformation processes in the evolution of the continental lithosphere, using the Alpine orogen as an example. Rheological stratification; isostatic and flexural response to near-vertical loads; rifting and associated basin development; collision and strike-slip tectonics; deep crustal processes. Given in alternate years; not offered 2016-17.
Instructor:
Wernicke
Ge 277
Active Tectonics Seminar
6 units (2-0-4)
|
second term
Discussion of key issues in active tectonics based on a review of the literature. The topic of the seminar is adjusted every year based on students' interest and recent literature.
Instructor:
Avouac
Ge 297
Advanced Study
Units to be arranged
Ge 299
Thesis Research
Original investigation, designed to give training in methods of research, to serve as theses for higher degrees, and to yield contributions to scientific knowledge.
Published Date:
July 28, 2022