Opposites Thylakoid Move INTO the cell Carbon Dioxide Grana Calvin Cycle Sun Semipermeable D Water Cuticle Stomata Cellular Respiration Carbon Dioxide & Water To Make Glucose Swell Hypotonic Lose Water & Shrink Producing Glucose Roots Glucose & Oxygen Gas Exchange Stroma Osmosis Cell Membrane ATP Out of the Cell 2 Side B Photosynthesis Animal & Plant Cells Heterotrophs Capture & Transfer Energy A-- >B High to Low Autotrophs Glucose 1 Sugar Chlorophyll Flow in and out Equally Hypertonic Chloroplast Plants Mitochondria Oxygen Opposites Thylakoid Move INTO the cell Carbon Dioxide Grana Calvin Cycle Sun Semipermeable D Water Cuticle Stomata Cellular Respiration Carbon Dioxide & Water To Make Glucose Swell Hypotonic Lose Water & Shrink Producing Glucose Roots Glucose & Oxygen Gas Exchange Stroma Osmosis Cell Membrane ATP Out of the Cell 2 Side B Photosynthesis Animal & Plant Cells Heterotrophs Capture & Transfer Energy A-- >B High to Low Autotrophs Glucose 1 Sugar Chlorophyll Flow in and out Equally Hypertonic Chloroplast Plants Mitochondria Oxygen
(Print)
Opposites
Thylakoid
Move INTO the cell
Carbon Dioxide
Grana
Calvin Cycle
Sun
Semipermeable
D
Water
Cuticle
Stomata
Cellular Respiration
Carbon Dioxide & Water
To Make Glucose
Swell
Hypotonic
Lose Water & Shrink
Producing Glucose
Roots
Glucose & Oxygen
Gas Exchange
Stroma
Osmosis
Cell Membrane
ATP
Out of the Cell
2
Side B
Photosynthesis
Animal & Plant Cells
Heterotrophs
Capture & Transfer Energy
A-->B
High to Low
Autotrophs
Glucose
1
Sugar
Chlorophyll
Flow in and out Equally
Hypertonic
Chloroplast
Plants
Mitochondria
Oxygen
