Applied Physics Topics 2

Similar documents
Simple Gas Laws. To facilitate comparison of gases, the following standards are used: STP: O C (273 K) and kpa. SATP: 25 C (298 K) and 101.

Ch. 14 The Behavior of Gases

States of Matter Review

Gases. Name: Class: Date: Matching

World of Chemistry Notes for Students [Chapter 13, page 1] Chapter 13 Gases

Honors Chemistry Unit 7 Gas Laws Notes

Chapter 13 Gases and Pressure. Pressure and Force. Pressure is the force per unit area on a surface. Force Area. Pressure =

AP TOPIC 6: Gases. Revised August General properties and kinetic theory

CHAPTER 31 IDEAL GAS LAWS

Expand to fill their containers, are highly compressible, have extremely low densities.

Gas Law Worksheets - WS: Boyle s and Charles Law

Chapter 10: Gases. Characteristics of Gases

BASIC PHYSICS APPLIED TO ANAESTHESIOLOGY

NOTES: Behavior of Gases

The Kinetic-Molecular Theory of Gases based on the idea that particles are always in motion

Chapter 11. Recall: States of Matter. Properties of Gases. Gases

Kinetic Molecular Theory Gases. Behavior of gases. Postulate two. Postulate one. Postulate three. Postulate four

THE GAS STATE. Unit 4. CHAPTER KEY TERMS HOME WORK 9.1 Kinetic Molecular Theory States of Matter Solid, Liquid, gas.

Unit 8: Gases and States of Matter

Chem 110 General Principles of Chemistry

4. Using the kinetic molecular theory, explain why a gas can be easily compressed, while a liquid and a solid cannot?

CP Chapter 13/14 Notes The Property of Gases Kinetic Molecular Theory

Worksheet 1.7: Gas Laws. Charles Law. Guy-Lassac's Law. Standard Conditions. Abbreviations. Conversions. Gas Law s Equation Symbols

Lecture Presentation. Chapter 10. Gases. John D. Bookstaver St. Charles Community College Cottleville, MO Pearson Education, Inc.

SCH3U7 Quantitative Chemistry

Gas Pressure. Pressure is the force exerted per unit area by gas molecules as they strike the surfaces around them.

CP Chapter 13/14 Notes The Property of Gases Kinetic Molecular Theory

Name Hour. The Behavior of Gases. Practice B

4.) There are no forces of attraction or repulsion between gas particles. This means that

Chapter 14-Gases. Dr. Walker

Chemistry Chapter 10 Test

Kinetic-Molecular Theory of Matter

Chapter 12. The Gaseous State of Matter

Section 10-1: The Kinetic-Molecular Theory of Matter. 1) How does the word kinetic apply to particles of matter?

Name Chemistry Pre-AP

2. Calculate the ratio of diffusion rates for carbon monoxide (CO) and carbon dioxide (CO2). υa = MB = 44 = 1.25

Example: 25 C = ( ) K = 298 K. Pressure Symbol: p Units: force per area 1Pa (Pascal) = 1 N/m 2

Kinetic Molecular Theory imaginary Assumptions of Kinetic Molecular Theory: Problems with KMT:

Elements that exist as gases at 25 o C and 1 atmosphere H 2, N 2, O 2, F 2, Cl 2, He, Ne, Ar, Kr, Xe, Rn

Chapter 5. Nov 6 1:02 PM

Unit 9 Packet: Gas Laws Introduction to Gas Laws Notes:

Anaesthesia. Update in. Gases and Vapours. Ben Gupta Correspondence Summary

Basic Concepts of Chemistry Notes for Students [Chapter 10, page 1] D J Weinkauff - Nerinx Hall High School. Chapter 10 Gases

Kinetic Molecular Theory

PROPERTIES OF GASES. [MH5; Ch 5, (only)]

CHEM1901/3 Worksheet 8: The Ideal Gas Law: PV = nrt

Gases. Edward Wen, PhD

THE BEHAVIOR OF GASES

8.1 Properties of Gases. Goal: Describe the Kinetic Molecular Theory of Gases and the units of measurement used for gases.

Gases Chapter 8. Chapter 8

Gases. Chapter 8. Chapter 8. Gases Properties of Gases. We are surrounded by gases, but we are often

Unit 8: Kinetic Theory Homework Packet (90 points)

You should be able to: Describe Equipment Barometer Manometer. 5.1 Pressure Read and outline 5.1 Define Barometer

In the name of Allah

temperature and pressure unchanging

Gilbert Kirss Foster. Chapter 10. Properties of Gases The Air We Breathe

Section 8.1 Properties of Gases Goal: Describe the kinetic molecular theory of gases and the units of measurement used for gases.

Chapter 5: Gases 5.1 Pressure Why study gases? An understanding of real world phenomena. An understanding of how science works.

GASES. Unit #8. AP Chemistry

Unit 14 Gas Laws Funsheets

Lab Dates. CRHS Academic Chemistry Unit 11 Gas Laws Notes

Chapter 10 Gases. Characteristics of Gases. Pressure. The Gas Laws. The Ideal-Gas Equation. Applications of the Ideal-Gas Equation

KINETIC THEORY OF GASES

Characteristics of Gases

Behavior of Gases. Gases are mostly The molecules in a gas are separate, very small and very

Date: Period: Gas Laws Worksheet #1 - Boyle s, Charles, Gay-Lussac s, and Combined Gas Law

Kinetic-Molecular Theory

Properties of any sample of gas. Unit 5: Gases. * All gases behave according to the Kinetic Molecular Theory pg 421

Practice Packet Unit 8: Gases

Chemistry 101 Chapter 5 GAS MIXTURES

Chapter 5. Pressure. Atmospheric Pressure. Gases. Force Pressure = Area

Section 8: Gases. The following maps the videos in this section to the Texas Essential Knowledge and Skills for Science TAC (c).

Unit 9: Gas Laws REGENTS CHEMISTRY

Chemistry A Molecular Approach. Fourth Edition. Chapter 5. Gases. Copyright 2017, 2014, 2011 Pearson Education, Inc. All Rights Reserved

CHAPTER 14. The Behavior of Gases Properties of Gases. Factors Affecting Gas Pressure

Chemistry Chapter 12. Characteristics of Gases. Characteristics of Gases 1/31/2012. Gases and Liquids

Problem Solving. Gas Laws

Gas volume and pressure are indirectly proportional.

Chapter 10. Physical Characteristics of Gases

To play movie you must be in Slide Show Mode CLICK HERE EXERCISE! EXERCISE! To play movie you must be in Slide Show Mode CLICK HERE

Chemistry HP Unit 6 Gases. Learning Targets (Your exam at the end of Unit 6 will assess the following:) 6. Gases

Behavior of Gases Chapter 12 Assignment & Problem Set

Chapter 13 Gases, Vapors, Liquids, and Solids

Name /74. MULTIPLE CHOICE. Choose the one alternative that best completes the statement or answers the question.

Chemistry 51 Chapter 7 PROPERTIES OF GASES. Gases are the least dense and most mobile of the three phases of matter.

Chapter 13: The Behavior of Gases

Name: Chapter 13: Gases

Boyle s Law Practice

Gas Laws Chapter 14. Complete the following pressure conversion. Be sure to show how units cancel.

CHAPTER 1 KINETIC THEORY OF GASES (PART A)

Under ideal conditions, the rates at which different gases diffuse (spread out) are proportional to their molar masses.

A. What are the three states of matter chemists work with?

To convert to millimeters of mercury, we derive a unit factor related to the equivalent relationship 29.9 in. Hg = 760 mm Hg.

Practice Packet Unit 8: Gases

Pressure. Pressure is the force exerted by a gas on a surface.

Chapter 5 Gases. AP CHEMISTRY Chapter 5 Scotch Plains-Fanwood High School Page 1

9A Gas volume and pressure are indirectly proportional.

Pressure of the atmosphere varies with elevation and weather conditions. Barometer- device used to measure atmospheric pressure.

Dalton s Law How is the total pressure of a mixture of gases related to the partial pressures of the component gases?

Chapter 13. Gases. Copyright Cengage Learning. All rights reserved 1

Transcription:

Applied Physics Topics 2 Dr Andrey Varvinskiy Consultant Anaesthetist Torbay Hospital, UK EDAIC Paper B Lead and Examiner

TOPICS 2 Gas Laws Other Laws: Dalton, Avogadro Critical temperature Critical pressure Solubility Diffusion

Boyle s Law (aka the Boyle-Mariotte law) PV=k1 Constant temp All gas laws use absolute temp For a fixed amount of an ideal gas kept at a fixed T, pressure and volume are inversely proportional (while one doubles, the other halves)

Cylinder content Air,O2,Helium, Heliox and Entonox: by pressure gauge as P is proportional to V N2O and CO2: by weight. Liquified under Pressure

Application of Boyle s Law for calculating a content of a cylinder p1 x V1 =p2 x V2 P1 = Gauge pressure of cylinder V1 = Physical volume of cylinder P2 = Atmospheric pressure V2 =Actual amount of gas stored in the cylinder For CD O 2 cylinder : 230 x 2 = 1 x V2 = 460 L

Charles Law or Gay-Lussac s Law of Volumes V/T = k2 Constant pressure Gases expand when heated

Charles Law Practical Application One way of heat loss from the body is that air next to the body surface gets warmer and moves up and thus patient loses heat this way (esp. important in paediatric anaesthesia).

3 rd Perfect Gas Law P/T = k3 Constant volume the absolute pressure of gas varies directly to its absolute temperature

3 rd Perfect Gas Law Practical Application Medical gases are stored in cylinders at constant volume and high pressures (138 Bar in a full O2 cylinder) At high T, pressure will rise causing explosions Molybdenum steel can withstand pressures to 210 Bar. Weakening of metal in damaged cylinders are at a greater risk of explosion due to rise in temperature.

The Universal Gas Law Combining all the gas laws together yields an important equation: the universal or ideal gas law. PV = nrt P Pressure of gas V - Volume n = the number of moles of the gas T Temperature of gas R = the universal gas constant

Standard Temperature and Pressure (s.t.p.) Volumes of gases are affected by T and P hence there is a need to specify those And to correct results 273.15 K (0 0 C) 101.325 kpa

Dalton's Law Of Partial Pressures in a mixture of gases the pressure exerted by each gas is equal to the pressure which would be exerted if that gas alone was present Pressure Total = Pressure 1 + Pressure 2...Pressure n

Dalton's Law Practical Application In anaesthesia the partial pressures of gases in a mixture are often of interest By applying Boyle s and Dalton s law the partial pressure of a gas in a mixture is obtained by multiplying the total pressure by the fractional concentration of the gas.

Dalton's Law Practical Application In a mixture of gases where 0.05% - CO 2, 20.9%- O 2 and 78.1% - N 2. If the total Pressure is 100kPa the pco 2 0.05kPa, po 2-20.9kPA, pn 2 78.1kPa If the total pressure doubles (200kPa) then the partial pressure of each gas doubles.

Avogadro's Hypothesis equal volumes of gases at the same temperature and pressure contain equal numbers of molecules

Avogadro's Hypothesis Because the molecular weights of gases differ, there will be a different mass of any gas in a given volume at the same temperature and pressure Therefore it is more convenient to express a quantity of a gas in terms of the number of molecules, rather than in terms of mass.

AVAGADRO and the MOLE A MOLE is the quantity of a substance containing the same number of particles as there are atoms in 0.012kg of carbon12 There are 6.022 x 10 23 atoms in 12 g of carbon 12. This is called Avagadro s Number One mole of any gas at s.t.p. occupies 22.4litres

The Mole THUS: 2g of Hydrogen 32g of Oxygen 44g of Carbon Dioxide All occupy 22.4 litres at s.t.p

Ideal Gas Law The most significant consequence of Avogadro's law is that the ideal gas constant has the same value for all gases

Critical Temperature Temp above which a substance cannot be liquefied however much pressure is applied N2O: 36.5C O2: -119C CO2: 31C Gas applies to a substance above it s CT Vapour is for a substance below it s CT

Critical Pressure Pressure needed to liquefy the gas at its critical temp N2O ~ 72 bar O2 50 bar CO2 73 bar

Filling Ratio mass of gas in a cylinder/mass of water which would fill the cylinder For N2O it s 0.75 in the UK, hotter climates 0.67 Necessary to prevent explosion in case of rise in temp So N2O cylinder contains a mixture of liquid and vapour

Solubility and Henry s Law At particular T the amount of a given gas dissolved in a given liquid is directly proportional to the partial pressure of the gas in equilibrium with the liquid different gases have different solubilities Overall: solubility of a gas depends on partial pressure, temp, gas and liquid concerned temp of liquid => dissolved gas

Partition Coefficients ratio of amount of a substance present in one phase as compared with another two phases must be of equal volume, specified temperature in equilibrium Tension is often used in place of partial pressure for gases in solution (don t mix with surface tension) Could be applied to 2 different liquids (blood-gas, oilgas)

Diffusion Movement of a substance from an area of high concentration t one of low concentration due to spontaneous random movement of its constituent particles Not an active process as no energy required

Fick s law of diffusion rate of diffusion of a substance across a membrane is proportional its concentration gradient and inversely proportional to the tissue thickness diffusion of gas across a membrane or into or out of a liquid is proportional to the gas s solubility in the liquid CO2 more soluble than O2 and so diffuses more rapidly across the alveolar membrane N2O more soluble than N2 - can diffuse into and expand closed cavities

Graham's Law Effect of molecular size Rate of diffusion of a gas is inversely proportional to the square root of the molecular weight Only applies to simple models and is inaccurate when dealing with complex biological membranes

Diffusion Summary Diffusion is proportional to the tension gradient D depends on area and thickness of membrane D is affected by molecular size (larger diffuse less rapidly) Liquids diffuse less rapidly than gases

QUESTIONS? Magee and Tooley Cross and Plunkett

2024 © sportdocbox.com Privacy Policy | Terms of Service | Feedback