Big Idea #1 “ Atoms, Elements and the Building Blocks of Matter” Basic concepts covered: Chemical elements are fundamental building blocks of matter. Matter.

Slides:

Advertisements

Similar presentations

The Modern Atomic Model After Thomson: Bohr, Placnk, Einstein, Heisenberg, and Schrödinger.

Advertisements

Electrons. Wave model – scientist say that light travels in the form of a wave.

Chapter 7 Quantum Theory of the Atom Copyright © Houghton Mifflin Company. All rights reserved. What are the electrons doing in the atom? Why do atoms.

Electromagnetic Radiation

Matter and Atoms Ms. Sunday.

Chapter 5 Electrons In Atoms.

Chapter 7: Quantum Theory and Atomic Structure

ELECTROMAGNETIC RADIATION AND THE NEW ATOMIC MODEL.

L 35 Modern Physics [1] Introduction- quantum physics Particles of light  PHOTONS The photoelectric effect –Photocells & intrusion detection devices The.

Atoms and the Periodic Table. Atom Nucleus located in center of atom is small, dense and positively charged. Contains protons and neutrons Region outside.

 SPECTROSCOPY 101 Arkansas 2-Day October 2013 Lisa McGaw OSU

Spectroscopy for AP Chemistry Photoelectron Spectroscopy (PES) Provides data for ionization energy trends and applications Mass Spectrometry Provides atomic/molar.

What Are Some Types of Spectroscopy ?

Atoms RPI - ERTH 2330 The Basis of All Materials.

© 2010 Pearson Education, Inc. Light and Matter: Reading Messages from the Cosmos.

Big Idea #1 “ Atoms, Elements and the Building Blocks of Matter”

Chapter 2 The composition and Structure of the Atom Denniston Topping Caret 4 th Edition Copyright  The McGraw-Hill Companies, Inc. Permission required.

Chapter 3 The Structure of the Atom In order to explain much of what is observed in chemistry, we need to adopt a model for the atom where the atom has.

Atomic Structure Objectives: History of an Atom Atomic Models

Chemistry ATOMIC STRUCTURE Session Objectives 1.Dalton’s theory 2.Discovery of fundamental particles 3.Thomson’s model of an atom 4.Rutherford’s model.

Chapter 2: The Atom Atom: The smallest unit of an element that retains the chemical properties of the element.

Atomic Structure.

Many scientists found Rutherford’s Model to be incomplete  He did not explain how the electrons are arranged  He did not explain how the electrons were.

Light & Quantized Energy Questions about the Atom.

Introduction to Spectrochemical Methods

Chapter 10: Modern atomic theory Chemistry 1020: Interpretive chemistry Andy Aspaas, Instructor.

Chapter 5 in your textbook pp Wave Nature of Light  In the early 1900s scientists observed that certain elements emitted visible light when.

TOPIC D: SPECTROMETRY AND SPECTROSCOPY. Mass spectrometry is used to detect isotopes. mass spectrometer uses an ionizing beam of electrons to analyze.

© 2003 Mark S. Davis Chapter 2 Atomic Structure. © 2003 Mark S. Davis Law of Conservation of Mass Mass can be neither created nor destroyed in chemical.

Light and the Electromagnetic Spectrum. Light Phenomenon Isaac Newton ( ) believed light consisted of particles. By 1900, most scientists believed.

Electromagnetic Spectrum

 Unit 4 The Arrangement of Electrons Ch. 4. Exam 4 Analysis  Averages  The Atom+/25(%)  Measurement+/15(%) up from %  Phases/KMT+/10(82%) down from.

A.P. Exam Review Regular Review Day 1. Big Idea #1 The chemical elements are fundamental building materials of matter, and all matter can be understood.

Chapter 2 Atomic Structure. Law of Conservation of Mass Mass can be The total mass of the.

Quantum Theory, Periodicity and Experimental Techniques (Mass Spec/PES/Spectrophotometry)

Introduction to Spectrochemical Methods

CHAPTER 1 QUANTITATIVE CHEMISTRY LOOK AT EACH LEARNING GOAL AND WATCH THE TUTORIAL VIDEOS FOR THE GOALS YOU NEED WORK ON.

Chapter 5 Electrons in Atoms Chemistry Section 5.1 Light and Quantized Energy At this point in history, we are in the early 1900’s. Electrons were the.

Chapter 7. Electromagnetic Radiation  aka. Radiant energy or light  A form of energy having both wave and particle characteristics  Moves through a.

CONTENT OBJECTIVE understand the electromagnetic spectrum and the mathematical relationships between energy, frequency, and wavelength of light. WHAT.

Unit 2: Atoms and Bonding 2.62 Unit 2: Atoms and Bonding 2.62 Photons and Energy Textbook ch 6.2 and ch 6.3.

C-4 Atomic Structure The nucleus and the moving electrons.

Elemental Analysis using Atomic Absorption and Emission Spectroscopy Bodhisatwa Das.

Differentiate between physical and chemical changes and properties.[CHE.4A] October 2014Secondary Science - Chemistry.

1.1 What’s electromagnetic radiation

 Is a measure of the pull of gravity on an object.

Unit 2: Atoms and Bonding 2.61 Light Textbook ch 6.1.

Chemical Composition … Moles Chemistry Mr. Lentz.

Electrons in Atoms Chapter Wave Nature of Light  Electromagnetic Radiation is a form of energy that exhibits wavelike behavior as it travels through.

Models, Waves, and Light Models of the Atom Many different models: – Dalton-billiard ball model (1803) – Thompson – plum-pudding model (1897) – Rutherford.

Unit 2: Atoms and Bonding 2.66 Photoelectron Spectroscopy (PES) Not found in Textbook.

How do we know? Spectroscopy: Experimental Evidence.

Light, Quantitized Energy & Quantum Theory CVHS Chemistry Ch 5.1 & 5.2.

E LECTRONS IN A TOMS Chapter 5. L IGHT AND Q UANTIZED E NERGY Nuclear atom and unanswered questions Scientists found Rutherford’s nuclear atomic model.

Organic Analysis (2). What is light? 1. Light as a continuous wave 1. Light as a continuous wave 2. Light as a stream of discrete energy particles (photons).

© 2009, Prentice-Hall, Inc. The Nature of Energy Another mystery in the early 20th century involved the emission spectra observed from energy emitted by.

Atomic Structure Powerpoint #2.

Chemistry I Objectives Unit 2 Chapter 4

Spectroscopy © 2009, Prentice-Hall, Inc..

Atomic Structure.

Spectroscopy Chem honors.

Physics and the Quantum Mechanical Model

Review Big Idea 1.

Chapter 5 Electrons in Atoms.

WHAT THE HECK DO I NEED TO BE ABLE TO DO?

Light and Matter Main Concept:

Atomic structure.

Presentation transcript:

Big Idea #1 “ Atoms, Elements and the Building Blocks of Matter” Basic concepts covered: Chemical elements are fundamental building blocks of matter. Matter can be understood in terms of arrangement of atoms. Atoms retain their identity in chemical reactions.

Atomic Structure: Scientists and their contributions Atomic Structure Electromagnetic radiation Electron configuration Bohr Model Periodic Trends Spectroscopy Chemical composition (percent composition, empirical and molecular formula) Mole (and applications ex. Gases & solutions)

© 2009, Prentice-Hall, Inc. Electromagnetic Radiation All electromagnetic radiation travels at the same velocity: the speed of light (c), 3.00  10 8 m/s. The spectral regions of the electromagnetic spectrum vary according to frequency and wavelength.

Mass Spectrometry Operates by separating and detecting particles by their mass. Useful for identifying the number of isotopes for a given element. More sophisticated analysis will allow of interpretation of molecular structure.

Masses of Isotopes determined with a mass spectrometer

The mass spectrometer gives information on the mass and relative abundance of each element’s isotopes. Each isotope is represented by a Relative Abundance. Isotope Abundance

Interpreting Mass Spectra Calculate the Average atomic mass for Si: amu

Photoelectron Spectroscopy (PES) High energy beams (x-rays) used to eject electrons off the surface of a material, usually a solid. Understanding the binding energy of the electrons support the understanding of electron configuration and ionization energy. Applications include understanding valence energy levels and chemical bonding.

Interpretation of Photoelectron Spectra

Coulomb's Law States the amount of energy that an electron has depends on its distance from the nucleus of the atom. F= Energy, k= Coulomb’s constant, q 1 (q+)= magnitude of positive charge (nucleus) q 2 (q-)= magnitude of negative charge (electron), r= distance between the charges

UV-Visible Spectra Spectroscopy is the study of the interaction of energy with a sample for analysis. UV-Vis spectroscopy specifically addresses the absorbance or transmittance of a material at a specific wavelength within the UV/visible portion of the electromagnetic spectrum. Almost every material in existence absorbs light of one wavelength or another. Materials will absorb light of one wavelength and not absorb light of a different wavelength. The absorption of specific wavelengths of light can be measured using a spectrophotometer. This information can be used to understand sample composition and concentration.

Interpretation of Beer’s Lambert Law: Describes the linear relationship between solution concentration and absorbance

Example: Calibration Curve