Microfluid Mechanics
1st EditionISBN10: 0071443223
ISBN13: 9780071443227
Copyright: 2006
Instructors: choose ebook for fast access or receive a print copy.
Still Have Questions? Contact your Rep s
With the McGraw-Hill eBook, students can access their digital textbook on the web or go offline via the ReadAnywhere app for phones or tablets.
McGraw-Hill eBook Courses Include:
- Offline reading – study anytime, anywhere
- One interface for all McGraw-Hill eBooks
- Highlighting and note-taking
- Syncs across platforms, always up-to-date
- Available for Android and iOS
Rent Monthly
Purchase Options
Students, we’re committed to providing you with high-value course solutions backed by great service and a team that cares about your success. See tabs below to explore options and pricing. Don't forget, we accept financial aid and scholarship funds in the form of credit or debit cards.
Product
Out of stock
ISBN10: 0071443223 | ISBN13: 9780071443227
Purchase
$184.00
The estimated amount of time this product will be on the market is based on a number of factors, including faculty input to instructional design and the prior revision cycle and updates to academic research-which typically results in a revision cycle ranging from every two to four years for this product. Pricing subject to change at any time.
The estimated amount of time this product will be on the market is based on a number of factors, including faculty input to instructional design and the prior revision cycle and updates to academic research-which typically results in a revision cycle ranging from every two to four years for this product. Pricing subject to change at any time.
Program Details
Chapter 1: Introduction
Chapter 2: Basic Kinetic Theory
Chapter 3: Microfluid Properties
Chapter 4: Moment Method: Navier-Stokes and Burnett Equations
Chapter 5: Statistical Method: Direct Simulations Monte Carlo Method and Information Preservation Method
Chapter 6: Parallel Computing of DSMC
Chapter 7: Fluid/Solid Interface Mechanisms
Chapter 8: Development of Hybrid Continuum/Particle Method
Chapter 9: Low-Speed Microflows
Chapter 10: High-Speed Microflows
Chapter 11: Perturbation in Microflows
Chapter 3: Microfluid Properties
Chapter 4: Moment Method: Navier-Stokes and Burnett Equations
Chapter 5: Statistical Method: Direct Simulations Monte Carlo Method and Information Preservation Method
Chapter 6: Parallel Computing of DSMC
Chapter 7: Fluid/Solid Interface Mechanisms
Chapter 8: Development of Hybrid Continuum/Particle Method
Chapter 9: Low-Speed Microflows
Chapter 10: High-Speed Microflows
Chapter 11: Perturbation in Microflows
Chapter 5: Statistical Method: Direct Simulations Monte Carlo Method and Information Preservation Method
Chapter 6: Parallel Computing of DSMC
Chapter 7: Fluid/Solid Interface Mechanisms
Chapter 8: Development of Hybrid Continuum/Particle Method
Chapter 9: Low-Speed Microflows
Chapter 10: High-Speed Microflows
Chapter 11: Perturbation in Microflows
Chapter 7: Fluid/Solid Interface Mechanisms
Chapter 8: Development of Hybrid Continuum/Particle Method
Chapter 9: Low-Speed Microflows
Chapter 10: High-Speed Microflows
Chapter 11: Perturbation in Microflows
Chapter 9: Low-Speed Microflows
Chapter 10: High-Speed Microflows
Chapter 11: Perturbation in Microflows
Chapter 11: Perturbation in Microflows
Chapter 1: Introduction
Chapter 2: Basic Kinetic Theory
Chapter 3: Microfluid Properties
Chapter 4: Moment Method: Navier-Stokes and Burnett Equations
Chapter 5: Statistical Method: Direct Simulations Monte Carlo Method and Information Preservation Method
Chapter 6: Parallel Computing of DSMC
Chapter 7: Fluid/Solid Interface Mechanisms
Chapter 8: Development of Hybrid Continuum/Particle Method
Chapter 9: Low-Speed Microflows
Chapter 10: High-Speed Microflows
Chapter 11: Perturbation in Microflows
Chapter 3: Microfluid Properties
Chapter 4: Moment Method: Navier-Stokes and Burnett Equations
Chapter 5: Statistical Method: Direct Simulations Monte Carlo Method and Information Preservation Method
Chapter 6: Parallel Computing of DSMC
Chapter 7: Fluid/Solid Interface Mechanisms
Chapter 8: Development of Hybrid Continuum/Particle Method
Chapter 9: Low-Speed Microflows
Chapter 10: High-Speed Microflows
Chapter 11: Perturbation in Microflows
Chapter 5: Statistical Method: Direct Simulations Monte Carlo Method and Information Preservation Method
Chapter 6: Parallel Computing of DSMC
Chapter 7: Fluid/Solid Interface Mechanisms
Chapter 8: Development of Hybrid Continuum/Particle Method
Chapter 9: Low-Speed Microflows
Chapter 10: High-Speed Microflows
Chapter 11: Perturbation in Microflows
Chapter 7: Fluid/Solid Interface Mechanisms
Chapter 8: Development of Hybrid Continuum/Particle Method
Chapter 9: Low-Speed Microflows
Chapter 10: High-Speed Microflows
Chapter 11: Perturbation in Microflows
Chapter 9: Low-Speed Microflows
Chapter 10: High-Speed Microflows
Chapter 11: Perturbation in Microflows
Chapter 11: Perturbation in Microflows
Shipping Options
- Standard
- Next day air
- 2nd day air
- 3rd day air
Rent Now
You will be taken to our partner Chegg.com to complete your transaction.
After completing your transaction, you can access your course using the section url supplied by your instructor.