Increasing atmospheric instability generally leads to:

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Discover the essentials of SAChE Atmospheric Dispersion Module 2. Study with questions, hints, and detailed explanations to boost your understanding and readiness. Prepare effectively for your exam now!

Multiple Choice

Increasing atmospheric instability generally leads to:

Explanation:
Increasing atmospheric instability means more turbulence and mixing in the air, which broadens a released plume. In Gaussian dispersion terms, sigma_y measures how spread out the plume becomes crosswind (horizontal), and sigma_z measures how tall the plume spreads (vertical). When instability rises, turbulent eddies are stronger and more efficient at mixing, so the plume spreads more in both directions. That’s why both sigma_y and sigma_z increase with instability. The other options imply less spreading, no change, or spreading only in one direction, which doesn’t fit the effect of enhanced turbulence on dispersion in both horizontal and vertical dimensions.

Increasing atmospheric instability means more turbulence and mixing in the air, which broadens a released plume. In Gaussian dispersion terms, sigma_y measures how spread out the plume becomes crosswind (horizontal), and sigma_z measures how tall the plume spreads (vertical). When instability rises, turbulent eddies are stronger and more efficient at mixing, so the plume spreads more in both directions. That’s why both sigma_y and sigma_z increase with instability. The other options imply less spreading, no change, or spreading only in one direction, which doesn’t fit the effect of enhanced turbulence on dispersion in both horizontal and vertical dimensions.

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