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October 25 AR 1:34 – 1:49 pm 1.

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Presentation on theme: "October 25 AR 1:34 – 1:49 pm 1."— Presentation transcript:

1 October 25 AR 1:34 – 1:49 pm 1

2 Notebook due tomorrow Student Planner October 25
Place this in the proper place Notebook due tomorrow bacteriophage

3 Write the answer to answer October 24th Essential Question:
Where in the salt lab did the crystals grow the largest? 4

4 Write your summary in full sentences and list one thing you learned
Review of October 24th Completed the salt lab, then took notes on microscopes. Reviewed notebook checklist. Write your summary in full sentences and list one thing you learned 3

5 Topic/Objective: Name: Types of microscopes Class/Period: Date: Oct 25, 2016 Essential Question: What are the characteristics of different microscope types?

6

7 1. Looking at the chart, which situation is showing a chemical change after it was mixed with water?
Substance Unmixed Mixed with water A Blue solid Expanded to a blue solid B Powdery, white Mixed and then separated out C Cloudy and white color D Silver solid Powdery orange

8 2.The equation shows which type of process? H2O(L) H2O(S)
L= Liquid S= Solid Chemical Change Physical Change None of the above

9 A) .2 meters B) 5 meters C)10 meters D) 20 meters
3. The graph below shows the speed of a vehicle. How far did the vehicle travel during the first two seconds? V=D/T A) .2 meters B) 5 meters C)10 meters D) 20 meters Speed (m/s) 10 5 00 1 2 3 Time (seconds)

10 4. The graph below shows how the position of an object changes over time. What is the speed of the object during the time interval from 30 to 50 seconds? A) 2 m/s B) 5 m/s C) 2.5 m/s D) .5 m/s V=D/T 20 Position (m) 10 10 20 30 40 50 Time (s)

11 Answers 15

12 1. Looking at the chart, which situation is showing a chemical change after it was mixed with water?
Substance Unmixed Mixed with water A Blue solid Expanded to a blue solid B Powdery, white Mixed and then separated out C Cloudy and white color D Silver solid Powdery orange

13 1. Looking at the chart, which situation is showing a chemical change after it was mixed with water?
Substance Unmixed Mixed with water A Blue solid Expanded to a blue solid B Powdery, white Mixed and then separated out C Cloudy and white color D Silver solid Powdery orange

14 2.The equation shows which type of process? H2O(L) H2O(S)
L= Liquid S= Solid Chemical Change Physical Change None of the above

15 2.The equation shows which type of process? H2O(L) H2O(S)
L= Liquid S= Solid Chemical Change Physical Change None of the above

16 A) .2 meters B) 5 meters C)10 meters D) 20 meters
3. The graph below shows the speed of a vehicle. How far did the vehicle travel during the first two seconds? V=D/T A) .2 meters B) 5 meters C)10 meters D) 20 meters Speed (m/s) 10 5 00 1 2 3 Time (seconds)

17 A) .2 meters B) 5 meters C)10 meters D) 20 meters
3. The graph below shows the speed of a vehicle. How far did the vehicle travel during the first two seconds? V=D/T A) .2 meters B) 5 meters C)10 meters D) 20 meters Speed (m/s) 10 5 00 1 2 3 Time (seconds)

18 A) 2 m/s B) 5 m/s C) 2.5 m/s D) .5 m/s V=D/T
4. The graph below shows how the position of an object changes over time. What is the speed of the object during the time interval from 30 to 50 seconds? A) 2 m/s B) 5 m/s C) 2.5 m/s D) .5 m/s V=D/T 20 Position (m) 10 10 20 30 40 50 Time (s)

19 A) 2 m/s B) 5 m/s C) 2.5 m/s D) .5 m/s V=D/T
4. The graph below shows how the position of an object changes over time. What is the speed of the object during the time interval from 30 to 50 seconds? A) 2 m/s B) 5 m/s C) 2.5 m/s D) .5 m/s V=D/T 20 Position (m) 10 10 20 30 40 50 Time (s)

20 HOMEWORK Notebook due tomorrow. Microscope proficiency test Thursday. All triad 2 work due Friday 15

21 Today’s Work Microscope types - notes Microscope care

22 -Microscopes- Types Type notes here

23 Dissection Microscope
Type notes here

24 3-D (sterioscopic-binocular) $100-$500 cannot see cells
Characteristics: low power 3-D (sterioscopic-binocular) $100-$500 cannot see cells Type notes here

25 Compound Light Microscope Type notes here

26 Characteristics: Light powered to 1000x 2-D $150-$10,000
Type notes here

27 Confocal Microscope Type notes here

28 Characteristics: Laser light powered to 1000x 3-D, digitally enhanced
$20,000-$100,000 Type notes here

29 Type notes here

30 Scanning Electron Microscope
Type notes here

31 Characteristics: Reflected electrons 100,000x 3-D image
subject is gold coated $50k up into the millions Type notes here

32 Type notes here

33 Transmission Electron Microscope Type notes here

34 Type notes here

35 electrons pass thru specimen 200,000x 2-D image
Characteristics: electrons pass thru specimen 200,000x 2-D image $50k up into the millions Type notes here

36 The vast majority of other types are used in limited research institutes. Some of these are:

37 Scanning probe AFM: Atomic Force Microscopy BEEM: Ballistic Electron Emission Microscopy EFM: Electrostatic Force Microscope ESTM: Electrochemical Scanning Tunneling Microscope FMM: Force Modulation Microscopy KPFM: Kelvin Probe Force Microscopy MFM: Magnetic Force Microscopy MRFM: Magnetic Resonance Force Microscopy NSOM: Near-field Scannin Optical Microscopy PFM: Piezo Force Microscopy PSTM: Photon Scanning Tunneling Microscopy

38 PTMS: Photothermal Microspectroscopy/Microscopy
SAP: Scanning Atom Probe Microscopy SCM: Scanning capacitance Microscope SECM: Scanning ElectroChemical Microscopy SGM: Scanning Gate Microscopy SICM: Scanning Ion-Conductance Microscopy SPSM Spin Polarized Scanning tunneling Microscopy SThM: Scanning thermal Microscopy STM: Scanning Tunneling Microscopy SVM: Scanning Voltage Microscopy SHPM: Scanning Hall Probe Microscopy SSM: Scanning SQUID Microscope RTM: Recurrence Tracking Microscope SAM: Scanning acoustic microscope

39 Microscopes have many technological procedures which improve the results. Some of these include:
Bright Field Microscopy Dark Field Microscopy Digital Microscope Fluorescence interference contrast Microscopy Fluorescence Microscopy Laser Capture Micro dissection

40 Brightfield – light beamed from below

41 Dark field light hits object leaving back ground black.

42 Fluorescence Microscopy
Showing cheek cells stained with fluorescent dye.

43 Multifocal plane Microscopy
Phase contrast Microscopy New microscope technology is under constant development, thus the need for life long learning.

44 Tungsten crystal showing atoms at 2,700,000 x

45 Type notes here

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