Deck 4: The Microscope

A)the 100× objective lens should be closest to the stage
B)the condenser should be removed and stored in its compartment
C)use both hands to hold it by the base
D)the cord should be secured

A)Low-power lens
B)Scanning lens
C)Oil-immersion lens
D)High-power lens

A)all three threads should be in clear focus
B)you are ready to rotate the ocular lens
C)neither the middle nor the bottom-most thread will be in clear focus
D)the middle thread will also be in clear focus

A)space between the slide and specimen and the objective lens
B)space between the ocular and objective lens
C)space between the condenser and ocular lens
D)space between your eye and the ocular lens

A)0)01 μm
B)10 μm
C)100 μm
D)0)1 μm

A)Fine adjustment knob
B)Condenser
C)Substage light
D)Iris diaphragm

A)objective lens
B)revolving nosepiece
C)arm
D)ocular lens

A)Fine adjustment knob
B)Mechanical stage control
C)Iris diaphragm
D)Aperture

A)Ocular lens
B)Objective lens
C)Revolving nosepiece
D)Condenser

A)Low-power
B)Scanning
C)Oil-immersion
D)High-power

A)condenser
B)substage light
C)iris diaphragm
D)revolving nosepiece

A)Coarse adjustment knob
B)Substage light
C)Fine adjustment knob
D)Iris diaphragm lever

A)0)04 μm
B)0)004 μm
C)4000 μm
D)400 μm

A)0)623 mm
B)62300 mm
C)6230 mm
D)0)0623 mm

A)Aperture
B)Arm
C)Iris diaphragm
D)Ocular lens

A)Stage
B)Base
C)Arm
D)Head

A)Distance between the ocular and objective lenses
B)Distance between the slide and the objective lens
C)Another term for field diameter
D)Thickness of a specimen when in focus

A)fine adjustment knob
B)light control
C)coarse adjustment knob
D)substage light

A)condenser; stage
B)head; base
C)arm; base
D)stage; arm

A)10 mm
B)1)25 mm
C)20 mm
D)0)8 mm

A)stays the same
B)decreases
C)increases

A)0)75 μm
B)750 μm
C)0)0075 μm
D)75 μm

A)its motor and light are warm and a student could get injured
B)it is easier to clean when cool
C)it will extend the life of the expensive bulb
D)it will prevent the motor from burning out

A)Base
B)Revolving nosepiece
C)Arm
D)Stage

A)Distance between the stage and light source
B)Distance between the slide and structure and the objective lens
C)Distance between the objective and ocular lenses
D)Distance between the human eye and ocular lens

A)Same as with the naked eye
B)Sideways and right to left
C)Upside down and backward
D)Upside down, but still left to right

A)lens cleaner
B)disinfectant
C)water
D)oil

A)The lens is closer to the specimen and less of the specimen can be illuminated.
B)Increasing magnification decreases the working distance rather than the field diameter.
C)Using the oil-immersion lens limits the ability to illuminate a specimen at high power.
D)Parfocal microscopes gain the ability to stay in focus when changing objective lenses.

A)500 μm
B)0)005 μm
C)50 μm
D)0)05 μm

A)245,000 mm
B)0)245 mm
C)0)0245 mm
D)2)45 mm

A)Divide the ocular lens magnification by the objective lens magnification
B)Multiply magnification of the ocular lens times that of the objective lens
C)Add together the ocular and objective magnifications
D)Divide the objective lens magnification by the ocular lens magnification

A)Scanning objective
B)Low power
C)High power
D)Oil-immersion

A)40X
B)4X
C)100X
D)400X

A)less than
B)equal to
C)greater than

A)2 mm
B)1)6 mm
C)10 mm
D)40 mm

A)The thickness of the specimen that is in sharp focus
B)How easily focused the specimen is between two different magnifications
C)The length of the specimen when viewed with the scanning objective lens
D)How wide the view is through the lens

A)Condensers narrow the beam of light but do not change the amount of light.
B)Both can be changed by using the iris diaphragm.
C)Both can be used to concentrate the light passing through the specimen.
D)You do not need to condense the light if you use the iris diaphragm correctly.

A)400×
B)40×
C)1000×
D)100×

A)decreases
B)stays the same
C)increases

A)Field diameter
B)Total magnification.
C)Both field diameter and total magnification
D)Neither field diameter nor total magnification