1 which element contains 21 protons
play

1 Which element contains 21 protons? Slide 2 / 64 2 Which element - PowerPoint PPT Presentation

Jun 08, 2023 •162 likes •812 views

Slide 1 / 64 1 Which element contains 21 protons? Slide 2 / 64 2 Which element contains 11 protons? Slide 3 / 64 3 Which element contains 104 protons? Slide 4 / 64 4 How many protons are in Carbon? Slide 5 / 64 5 How many protons are

  1. Slide 1 / 64 1 Which element contains 21 protons?

  2. Slide 2 / 64 2 Which element contains 11 protons?

  3. Slide 3 / 64 3 Which element contains 104 protons?

  4. Slide 4 / 64 4 How many protons are in Carbon?

  5. Slide 5 / 64 5 How many protons are in Tungsten?

  6. Slide 6 / 64 6 How many protons are in Indium?

  7. Slide 7 / 64 7 Which element contains 35 protons?

  8. Slide 8 / 64 8 Which element contains 19 protons?

  9. Slide 9 / 64 9 Which element contains 84 protons?

  10. Slide 10 / 64 10 How many protons are in Magnesium?

  11. Slide 11 / 64 11 How many protons are in Gold?

  12. Slide 12 / 64 12 How many protons are in Silver?

  13. Slide 13 / 64 144 X Sm 13 For the following isotope: A What is the atomic number? What is the mass number? B Solve for how many of each of the following a single atom C of the above isotope has i. Protons: ii. Neutrons: iii. Electrons:

  14. Slide 14 / 64 31 X P 14 For the following isotope: A What is the atomic number? What is the mass number? B Solve for how many of each of the following a single atom C of the above isotope has i. Protons: ii. Neutrons: iii. Electrons:

  15. Slide 15 / 64 56 X Fe 15 For the following isotope: A What is the atomic number? What is the mass number? B Solve for how many of each of the following a single atom C of the above isotope has i. Protons: ii. Neutrons: iii. Electrons:

  16. Slide 16 / 64 For the following isotope: 39 X 16 19 A What is the element’s atomic symbol? B What is the atomic number? C What is the mass number? D Solve for how many of each of the following a single atom of the above isotope has i. Protons: ii. Neutrons: iii. Electrons:

  17. Slide 17 / 64 33 X 17 For the following isotope: 16 A What is the element’s atomic symbol? B What is the atomic number? C What is the mass number? D Solve for how many of each of the following a single atom of the above isotope has i. Protons: ii. Neutrons: iii. Electrons:

  18. Slide 18 / 64 102 Ru 18 For the following isotope: X A What is the atomic number? B What is the mass number? C Solve for how many of each of the following a single atom of the above isotope has i. Protons: ii. Neutrons: iii. Electrons:

  19. Slide 19 / 64 75 X As 19 For the following isotope: A What is the atomic number? B What is the mass number? C Solve for how many of each of the following a single atom of the above isotope has i. Protons: ii. Neutrons: iii. Electrons:

  20. Slide 20 / 64 59 Co 20 For the following isotope: X A What is the atomic number? B What is the mass number? C Solve for how many of each of the following a single atom of the above isotope has i. Protons: ii. Neutrons: iii. Electrons:

  21. Slide 21 / 64 14 X 21 For the following isotope: 6 A What is the element’s atomic symbol? B What is the atomic number? C What is the mass number? D Solve for how many of each of the following a single atom of the above isotope has i. Protons: ii. Neutrons: iii. Electrons:

  22. Slide 22 / 64 20 X 22 For the following isotope: 9 A What is the element’s atomic symbol? B What is the atomic number? C What is the mass number? D Solve for how many of each of the following a single atom of the above isotope has i. Protons: ii. Neutrons: iii. Electrons:

  23. Slide 23 / 64 23 Given the data below, the average atomic mass of Mercury (Hg) is _________ amu. Isotope % Abund. Atomic Mass Hg-196 0.146% 195.965813 Hg-198 10.01% 197.966760 Hg-199 16.84% 198.968268 Hg-200 23.13% 199.968316 Hg-201 13.22% 200.970293 Hg-202 29.81% 201.970632 Hg-204 6.844% 203.973481

  24. Slide 24 / 64 24 Calculate the atomic mass of Oxygen if its abundance in nature is: % Abund. Atomic Mass Isotope 99.75% 15.994916 oxygen-16 00.04% 16.999132 oxygen-17 00.21% 17.999153 oxygen-18

  25. Slide 25 / 64 25 Given the data below, the average atomic mass of Neon is _________ amu. Isotope % Abund. Atomic Mass Neon-20 90.62% 19.992439 Neon-21 0.26% 20.993845 Neon-22 9.12% 21.991384

  26. Slide 26 / 64 48 +2 22 Ti 26 For the following ion: A What is the atomic number? What is the mass number? B Solve for how many of each of the following a single atom C of the above isotope has i. Protons: ii. Neutrons: iii. Electrons:

  27. Slide 27 / 64 108 + 47 Ag 27 For the following ion: A What is the atomic number? What is the mass number? B Solve for how many of each of the following a single atom C of the above isotope has i. Protons: ii. Neutrons: iii. Electrons:

  28. Slide 28 / 64 32 -2 16 S 28 For the following ion: A What is the atomic number? What is the mass number? B Solve for how many of each of the following a single atom C of the above isotope has i. Protons: ii. Neutrons: iii. Electrons:

  29. Slide 29 / 64 209 +5 83 Bi 29 For the following ion: A What is the atomic number? What is the mass number? B Solve for how many of each of the following a single atom C of the above isotope has i. Protons: ii. Neutrons: iii. Electrons:

  30. Slide 30 / 64 226 +2 88 Ra 30 For the following ion: A What is the atomic number? What is the mass number? B Solve for how many of each of the following a single atom C of the above isotope has i. Protons: ii. Neutrons: iii. Electrons:

  31. Slide 31 / 64 193 +3 77 Ir 31 For the following ion: A What is the atomic number? What is the mass number? B Solve for how many of each of the following a single atom C of the above isotope has i. Protons: ii. Neutrons: iii. Electrons:

  32. Slide 32 / 64 235 +6 92 U 32 For the following ion: A What is the atomic number? What is the mass number? B Solve for how many of each of the following a single atom C of the above isotope has i. Protons: ii. Neutrons: iii. Electrons:

  33. Slide 33 / 64 33 Draw the energy level diagram for Iron.

  34. Slide 34 / 64 34 Draw the energy level diagram for Sulfur.

  35. Slide 35 / 64 35 Draw the energy level diagram for Argon

  36. Slide 36 / 64 36 Draw the energy level diagram for Neon.

  37. Slide 37 / 64 37 Using what you know about electrons and energy levels, do you think that Sulfur will gain or lose electrons to achieve a noble gas configuration? Explain your answer using your energy level diagrams.

  38. Slide 38 / 64 38 Draw the energy level diagram for Titanium.

  39. Slide 39 / 64 39 Draw the energy level diagram for Strontium.

  40. Slide 40 / 64 40 Draw the energy level diagram for Krypton.

  41. Slide 41 / 64 41 Draw the energy level diagram for Xenon.

  42. Slide 42 / 64 42 Using what you know about electrons and energy levels, do you think that Calcium will gain or lose electrons to achieve a noble gas configuration? Explain your answer using your energy level diagrams.

  43. Slide 43 / 64 43 What is the electron configuration of Iron?

  44. Slide 44 / 64 44 What is the electron configuration of Bromine?

  45. Slide 45 / 64 45 What is the electron configuration of Lithium?

  46. Slide 46 / 64 46 What is the electron configuration of Strontium?

  47. Slide 47 / 64 47 What is the electron configuration of Nickel?

  48. Slide 48 / 64 48 What is the electron configuration of Francium?

  49. Slide 49 / 64 49 What is the electron configuration in noble gas notation of Tin?

  50. Slide 50 / 64 50 What is the electron configuration in noble gas notation of Germanium?

  51. Slide 51 / 64 51 What is the electron configuration in noble gas notation of Iodine?

  52. Slide 52 / 64 52 What is the electron configuration in noble gas notation of Uranium?

  53. Slide 53 / 64 53 What is the electron configuration in noble gas notation of Cesium?

  54. Slide 54 / 64 54 What is the electron configuration in noble gas notation of Bismuth?

  55. Slide 55 / 64 55 What is the electron configuration in noble gas notation of Aluminum?

  56. Slide 56 / 64 56 What is the electron configuration in noble gas notation of Palladium?

  57. Slide 57 / 64 57 What is the electron configuration in noble gas notation of Titanium?

  58. Slide 58 / 64 58 What is the electron configuration in noble gas notation of Silicon?

  59. Slide 59 / 64 59 Explain why Chromium’s electron configuration is different than that of the predicted configuration.

  60. Slide 60 / 64 60 Explain why Copper’s electron configuration is different than that of the predicted configuration.

  61. Slide 61 / 64 61 Consider the Alkali metals A What is the ending of the electron configuration of all Alkali Metals? B Based off of this electron configuration, do you think it is easier for Alkali Metals to gain or lose electron? Compared to the Alkaline Earth Metals, do you think the Alkali Metals are more or less reactive. Explain your answer using information about an alkali’s metals electron C configuration and energy level diagram. Two metals are placed in water. One bubbles a bit and corrodes. The other reacts violently and caused flames to erupt from the surface of the water. Which metal would D you predict is the Alkali Metal and which is the Alkaline Earth Metal. Explain your answer.

  62. Slide 62 / 64 62 A chemical supply company has run out of Chlorine for its customers. What other metal could they suggest to replace Beryllium and why?

Download Presentation
Download Policy: The content available on the website is offered to you 'AS IS' for your personal information and use only. It cannot be commercialized, licensed, or distributed on other websites without prior consent from the author. To download a presentation, simply click this link. If you encounter any difficulties during the download process, it's possible that the publisher has removed the file from their server.

Recommend

Slide 1 / 64 Slide 2 / 64 1 Which element contains 21 protons? 2 Which element contains 11

Slide 1 / 64 Slide 2 / 64 1 Which element contains 21 protons? 2 Which element contains 11

Slide 1 / 64 Slide 2 / 64 1 Which element contains 21 protons? 2 Which element contains 11 protons? Slide 3 / 64 Slide 4 / 64 3 Which element contains 104 protons? 4 How many protons are in Carbon? Slide 5 / 64 Slide 6 / 64 5 How many

341 views • 11 slides
Radiation Basic Model of a Neutral Atom Electrons(-) orbiting nucleus of protons(+) and

Radiation Basic Model of a Neutral Atom Electrons(-) orbiting nucleus of protons(+) and

Introduction to Ionizing Radiation Basic Model of a Neutral Atom Electrons(-) orbiting nucleus of protons(+) and neutrons. Same number of electrons as protons; net charge = 0. Atomic number (number of protons) determines element.

850 views • 54 slides
Measuring neutrons and protons in MINERvA Trackable Protons (Testbeam Protons) Countable Protons

Measuring neutrons and protons in MINERvA Trackable Protons (Testbeam Protons) Countable Protons

Measuring neutrons and protons in MINERvA Trackable Protons (Testbeam Protons) Countable Protons Trackable Neutrons Countable Neutrons (Geant4 Neutrons) Rik Gran, University of Minnesota Duluth nucleon detection workshop, Thursday 19 January

327 views • 15 slides
Class 19 : Where did the elements come from? 4/14/11 1 Notation we need some compact way of

Class 19 : Where did the elements come from? 4/14/11 1 Notation we need some compact way of

Class 19 : Where did the elements come from? 4/14/11 1 Notation we need some compact way of discussing nuclei Total number of nucleons = protons+neutrons Symbol for element Atomic number (set by atomic = number of protons number) 1

135 views • 11 slides
IBS (protons at store) as part of APEX during April 12, 2012 Protons at store: contribution from

IBS (protons at store) as part of APEX during April 12, 2012 Protons at store: contribution from

Alexei Fedotov 1 IBS (protons at store) as part of APEX during April 12, 2012 Protons at store: contribution from IBS 2 Purpose of this store was to measure polarization during the store without collisions. At the same time it

184 views • 7 slides
Nuclear Magnetic Resonance Indistinguishable protons What are the allowed transitions in the case

Nuclear Magnetic Resonance Indistinguishable protons What are the allowed transitions in the case

Nuclear Magnetic Resonance Indistinguishable protons What are the allowed transitions in the case of indistinguishable protons? Energy level diagram Molecular Spectroscopy CEM 484 2 Indistinguishable protons Transition moment

242 views • 5 slides
Systematics in nucleon matrix element calculations Jeremy Green NIC, DESY, Zeuthen The 36th

Systematics in nucleon matrix element calculations Jeremy Green NIC, DESY, Zeuthen The 36th

Systematics in nucleon matrix element calculations Jeremy Green NIC, DESY, Zeuthen The 36th International Symposium on Latice Field Theory East Lansing, MI, USA July 2228, 2018 Motivation Three reasons for studying structure of protons and

1.23k views • 78 slides
The Promise of Protons The Economic Club of Florida, Tallahassee 2018 0813 The Promise of Protons

The Promise of Protons The Economic Club of Florida, Tallahassee 2018 0813 The Promise of Protons

The Economic Club of Florida Tallahassee August 13, 2018 Nancy P Mendenhall, MD The Promise of Protons The Economic Club of Florida, Tallahassee 2018 0813 The Promise of Protons Cancer and radiation therapy The promise of protons

466 views • 42 slides
A protons way from the Sun to Ume a Boris Lemmer 22th of October 2007 Boris Lemmer A

A protons way from the Sun to Ume a Boris Lemmer 22th of October 2007 Boris Lemmer A

Protons at home Hey proton, where are you going? Arriving earth A protons way from the Sun to Ume a Boris Lemmer 22th of October 2007 Boris Lemmer A protons way from the Sun to Ume a Protons at home Hey proton, where are you

391 views • 28 slides
Stopping Power of 0.5-1.5MeV Protons in Mylar Tinyiko S. Maluleke 1 Supervisors: C.

Stopping Power of 0.5-1.5MeV Protons in Mylar Tinyiko S. Maluleke 1 Supervisors: C.

Stopping Power of 0.5-1.5MeV Protons in Mylar Tinyiko S. Maluleke 1 Supervisors: C. Pineda-Vargas 2 M. Msimanga 2 V. Kuzmin 3 1 Stellenbosch University, 2 iThemba Labs, 3 JINR AIM To measure the experimental stopping power for protons

438 views • 10 slides
XQuery XML Example Mandatory statement Root element XML elements Element names Element

XQuery XML Example Mandatory statement Root element XML elements Element names Element

XQuery XML Example Mandatory statement Root element XML elements Element names Element content CMPT 354: Database I -- XQuery 2 Hierarchical Structure PersonList Student Title Contents Person Person Name: John Doe Name: Joe Public

478 views • 24 slides
Chapter 10 Section 2 By: Mrs. Sergent What Is An Atom Made Of? An atom is made up of protons,

Chapter 10 Section 2 By: Mrs. Sergent What Is An Atom Made Of? An atom is made up of protons,

Chapter 10 Section 2 By: Mrs. Sergent What Is An Atom Made Of? An atom is made up of protons, neutrons, and electrons . Protons are positively charged particles in the nucleus. The SI unit used to express the masses of particles in atoms is the

549 views • 18 slides
Lighter element primary process in neutrino-driven winds Almudena Arcones Helmholtz Young

Lighter element primary process in neutrino-driven winds Almudena Arcones Helmholtz Young

Lighter element primary process in neutrino-driven winds Almudena Arcones Helmholtz Young Investigator Group Neutrino-driven winds Neutrino Cooling and Neutrino R [km] neutrons and protons form alpha particles Driven Wind (t ~ 10s) 5

484 views • 27 slides
10Hz Spectral Lines Joschua Dilly 10Hz Spectral Lines 2 Introduction Ions 50cm Protons 30cm

10Hz Spectral Lines Joschua Dilly 10Hz Spectral Lines 2 Introduction Ions 50cm Protons 30cm

10Hz Spectral Lines Joschua Dilly 10Hz Spectral Lines 2 Introduction Ions 50cm Protons 30cm Protons 60/15cm flatoptics Protons at Injection Conclusion Summary 10Hz Spectral Lines 3 Introduction In the context of the luminosity problems

318 views • 30 slides
Slide 1 / 48 1 Elements Z and X are compared. Element Z is larger than Element X. Based on this

Slide 1 / 48 1 Elements Z and X are compared. Element Z is larger than Element X. Based on this

Slide 1 / 48 1 Elements Z and X are compared. Element Z is larger than Element X. Based on this you could say: A Element Z is further to the left side of the periodic table B Element X is closer to the top of the periodic table Element Z and

272 views • 16 slides
Radiation Where does Radiation Come from? Material Atom Nucleus Protons Neutrons

Radiation Where does Radiation Come from? Material Atom Nucleus Protons Neutrons

Radiation Where does Radiation Come from? Material Atom Nucleus Protons Neutrons particles Example of disintegration Two protons Two neutrons Transformation Nucleus Nucleus Nucleus Radium226 Radon222 Nucleus

258 views • 10 slides
Tracing multiple sources of salinity to the Rio Grande with multiple isotope tracers (Uranium,

Tracing multiple sources of salinity to the Rio Grande with multiple isotope tracers (Uranium,

Tracing multiple sources of salinity to the Rio Grande with multiple isotope tracers (Uranium, Strontium, and Boron) PIs: Lin Ma, University of Texas at El Paso Jennifer McIntosh, University of Arizona Jerome Gaillardet, IPGP, France Anna

250 views • 5 slides
Nuclear resonant scattering of synchrotron radiation: a novel approach to the Mssbauer

Nuclear resonant scattering of synchrotron radiation: a novel approach to the Mssbauer

Nuclear resonant scattering of synchrotron radiation: a novel approach to the Mssbauer effect Johan Meersschaut Instituut voor Kern- en Stralingsfysica, Katholieke Universiteit Leuven, Belgium Johan.Meersschaut@fys.kuleuven.be C. Labb

866 views • 69 slides
Chemistry 1000 Lecture 1: Atoms Marc R. Roussel September 7, 2018 Marc R. Roussel Chemistry

Chemistry 1000 Lecture 1: Atoms Marc R. Roussel September 7, 2018 Marc R. Roussel Chemistry

Chemistry 1000 Lecture 1: Atoms Marc R. Roussel September 7, 2018 Marc R. Roussel Chemistry 1000 Lecture 1: Atoms September 7, 2018 1 / 21 Atoms and subatomic particles Atoms are mostly empty space. Protons and neutrons occupy small, dense

573 views • 21 slides
Strategies for Next Generation Neutrinoless Double-Beta Decay Experiments Frank Avignone

Strategies for Next Generation Neutrinoless Double-Beta Decay Experiments Frank Avignone

Strategies for Next Generation Neutrinoless Double-Beta Decay Experiments Frank Avignone University of South Carolina Neutrino-2004 College de France, Paris June 2004 General Theme I will not discuss the details of individual experiments.

623 views • 38 slides
Reactor Plutonium Utility in Nuclear Explosives* Bruce T. Goodwin, PhD Associate

Reactor Plutonium Utility in Nuclear Explosives* Bruce T. Goodwin, PhD Associate

Reactor Plutonium Utility in Nuclear Explosives* Bruce T. Goodwin, PhD Associate Director-at-Large for National Security & Policy Research November 6, 2015 *drawn from the work of Robert Selden LLNL-PRES-801535 This work was performed

448 views • 19 slides
Stable Water Isotopes Type MW % of total ppb 1 H 1 H 16 O 18 99.731 997,310,000 Hydrology

Stable Water Isotopes Type MW % of total ppb 1 H 1 H 16 O 18 99.731 997,310,000 Hydrology

CEE 680 Lecture #4 1/28/2020 Print version Updated: 28 January 2020 Lecture #4 Isotopes (cont); Kinetics and Thermodynamics: Fundamentals of water and Ionic Strength (Stumm & Morgan, pp.1 15 Brezonik & Arnold, pg 10 18)

217 views • 21 slides
Helium Isotopes with BESS-Polar II Nicolas PICOT-CLEMENTE for the BESS-Polar Collaboration

Helium Isotopes with BESS-Polar II Nicolas PICOT-CLEMENTE for the BESS-Polar Collaboration

ICRC 2017 Busan, July 13 th Precise Measurements of Hydrogen and Helium Isotopes with BESS-Polar II Nicolas PICOT-CLEMENTE for the BESS-Polar Collaboration Institute for Physical Science and Technology University of Maryland N. Picot-Clmente

381 views • 12 slides
rich Pd and Ag isotopes via optical spectroscopy Sarina Geldhof JYU. Since 1863. 7.10.2019 1

rich Pd and Ag isotopes via optical spectroscopy Sarina Geldhof JYU. Since 1863. 7.10.2019 1

Nuclear structure of neutron- rich Pd and Ag isotopes via optical spectroscopy Sarina Geldhof JYU. Since 1863. 7.10.2019 1 Outline Introduction Atomic spectra The IGISOL facility Motivation Neutron-rich Pd isotopes Overview

462 views • 23 slides

More recommend