"Convection" Example Sentences
1. Heat transfer by convection occurs when hot fluids transfer heat to cooler fluids.
2. Hot air rises due to convection, causing updrafts within the atmosphere.
3. Convection currents within the Earth's mantle drive plate tectonics.
4. The stove burner heats the pot through convection of heat from the hot coils.
5. Warm air rises due to convection, causing the hot-air balloon to lift off the ground.
6. Convection within the Sun's interior transports heat from the core to the surface.
7. Convection within the liquid outer core drives the earth's magnetic field.
8. The hot sand heats his feet through convection of heat from the ground.
9. The wind transports heat through convection of warm air from the equator to the poles.
10. Thermohaline circulation involves massive convection currents within ocean basins.
11. Convective precipitation occurs when air rises and cools within storm clouds.
12. The pan of boiling water illustrates convection currents within the liquid.
13. The simulation shows convection currents within the Earth's mantle.
14. Convection of heat within liquids occurs when warmer, less dense fluids rise and cooler, denser fluids sink.
15. The scientists studied convection within the Earth's lower mantle.
16. Convection dominates heat transfer within fluids like liquids and gases.
17. The flames illustrate convection as hot gases rise from the burning wood.
18. Convection currents carried heat throughout the house during the summer.
19. Convection is an important process for redistributing heat energy within and between Earth's spheres.
20. The liquid convects heat very efficiently through strong convection currents.
21. Strong solar heating drives powerful convection within the atmosphere.
22. Convection dominates heat transfer in fluids and plays a key role in atmospheric dynamics.
23. The pot has reached a steady state where convection currents are circulating heat efficiently.
24. Thermal convection plays an important role in the internal dynamics of stars.
25. Rayleigh–Bénard convection occurs when a fluid is heated from below.
26. The experiment investigated the effects of viscosity on convection within a liquid.
27. Convection within the asthenosphere drives plate tectonics at the Earth's surface.
28. Solar energy absorbed at the surface is transported into the interior through convection.
29. After heating, the fluid begins to exhibit natural convection currents.
30. The fluid exhibits laminar convection due to its high viscosity.
31. Convection occurs when density differences cause particles to move relative to each other.
32. Buoyancy drives convection currents within the fluid.
33. The heated fluid shows signs of turbulent convection as convection cells begin to break apart.
34. The hot liquid rises due to convection, creating space at the bottom for cooler liquid.
35. The bubbles form as convection currents bring hotter fluid to the surface.
36. Gas giants like Jupiter exhibit very strong convection within their outer atmospheres.
37. The model simulated convection within Earth's outer core and asthenosphere.
38. Strong winds occur due to convection within Earth's atmosphere.
39. Convective heat transfer depends on fluid properties like viscosity and thermal conductivity.
40. The fluid has reached a steady convective state with stable convection cells.
41. Moist convection occurs when rising air parcels become saturated and form clouds.
42. Free convection involves density differences within the fluid itself.
43. Forced convection occurs when external forces drive fluid motion and heat transfer.
44. The warm mat transfers heat to the floor through fluid convection.
45. The computer simulation modeled fluid convection within a spherical shell.
46. Solar energy absorbed at the surface is transported into Jupiter's interior through convection.
47. The weather balloon showed strong convective updrafts within the atmosphere.
48. Thermal convection within the Sun drives powerful magnetic storms at the surface.
49. Double-diffusive convection occurs when two constituents diffuse at different rates.
50. The scientist published research on natural convection heat transfer within fluids.
51. The hot liquid metal exhibits vigorous convection due to its low viscosity.
52. Mantle convection plays a vital role in plate tectonic motions and volcanism.
53. Buoyancy-driven convection within the liquid drove circulation and mixing.
54. Thermohaline convection occurs when salinity gradients drive fluid motion.
55. Winter storms often exhibit powerful convective updrafts and precipitation.
56. Solar convection mixes the solar atmosphere and transports energy outward.
57. The river current transfers heat from the water to the air through fluid convection.
58. Convection within the Earth's mantle transports heat outward toward the surface.
59. The atmosphere exhibits strong convective instability due to solar heating.
60. Atmospheric convection initiates the development of cumulonimbus storm clouds.
Common Phases
1. Heat transfer occurs by conduction,
convection, and radiation.
2.
Convection currents form in the liquid metal core, driving the Earth's magnetic field.
3. Warm air rises and cold air sinks in natural air circulation by
convection.
4. The hot water started rising to the surface due to
convection.
5. As the pan warms,
convection currents form within the batter, ensuring even cooking.
6. The heat from the fire causes
convection currents in the air.
7. In the boiling liquid,
convection transfers heat to the surface.
8. As the pan heats,
convection currents carry the excess heat away from the bottom surface.
9. Ocean currents are driven by
convection within the water.
10.
Convection carries the heat from the stove up to the pot and its contents.
11. The movement of warm and cool air masses drives global atmospheric
convection.
12.
Convection in lava lamps occurs when the wax warms and rises, then cools and falls.
13. Solar panels work best when installed at an angle to make use of
convection currents.
14. As the brick oven heated up, strong
convection currents carried the heat through the bread dough.
15. The magma rises through the crust due to
convection within the Earth's mantle.
16. As the burner heated the bottom of the pan,
convection currents formed within the liquid.
17. Air rises due to
convection and falls due to gravity and differences in density.
18. The source of heat initiates
convection currents that transfer the heat effectively.
19.
Convection currents in the Earth's mantle move the tectonic plates.
20. The heated pan transfers energy to the egg by conduction and
convection.
21. The rising hot air demonstrates the phenomenon of thermal
convection.
22. Flames move and dance due to
convection currents in the air.
23. The motion of molten rock within the mantle drives plate tectonics through
convection.
24. Furnaces transfer heat through the mechanisms of both conduction and
convection.
25. Warm air rises and cool air sinks in
convection currents within the atmosphere.
26. The liquid circulates in loops due to thermal
convection within the fluid.
27. The scientist studied the effects of
convection on heat transfer in the fluid.
28. The
convection cells within the mantle material carry heat towards the crust.
29. The fluid motion exhibits
convection caused by density differences.
30. Lava lamps work through the principles of
convection within a semi-viscous fluid.
31. The movement of magma in the Earth's mantle creates patterns of
convection.
32. The scientist studied fluid
convection using liquids of different viscosities.
33. Impurities tend to congregate at the edges of
convection cells within molten rock.
34. Heat rises due to the phenomenon of thermal
convection within the pot.
35. Metal objects cool faster when suspended from wires to maximize
convection.
36. Air within an oven rises due to
convection, maximizing heat transfer.
37.
Convection cookers ensure even cooking by circulating hot air around the food.
38. The scientist studied the effects of
convection currents on heat transfer in liquids.
39. As the water heated up, strong
convection currents formed within the fluid.
40.
Convection flutes form patterns within lava as it moves upwards through ducts.
41. The heated liquid exhibited strong
convection currents due to the temperature difference.
42. The flame dances as
convection moves the gases within the fire.
43. The natural circulation of fluids due to density differences is known as free
convection.
44. The warmth from the candles creates
convection currents in the still air.
45. The pan sits on a bed of coals, heating via conduction and
convection.
46. The liquid carried heat to the surface through convective loops and eddies.
47. Fluid movement occurs through both diffusion and
convection.
48. The rising hot bubbles demonstrate
convection within the liquid.
49. As the pan cooked the eggs,
convection transferred heat to their surfaces.
50. Forced
convection uses fans or pumps to accelerate heat transfer.
51.
Convection currents formed within the liquid as it heated on the stove.
52. The hot liquid rose due to thermal
convection within the beaker.
53. The fluid motion demonstrates
convection caused by the heat source below.
54. The lava rose violently through the vent due to powerful
convection currents.
55. The flames twist and turn due to
convection currents in the air.
56. The heated pot circulates warm air through
convection.
57. The molten iron in the Earth's outer core drives the magnetic field through
convection.
58.
Convection in the mantle moves the tectonic plates across Earth's surface.
59. The liquid cooled quickly due to strong
convection currents within the fluid.
60.
Convection transfers heat from a hot surface to cooler layers of fluid.