An astronaut stands upright inside a capsule on the moon's surface. What is the difference between the blood pressure at the lower part of his anterior tibial artery and the average blood pressure in his heart, that derives from the height differen 1.30 m shown in the illustration? Take the density of blood to be 1060 kg/m3 and acceleration due to gravity on the moon to be 1.62 m/s2. Beam Attenuation What happens to the uitr Allemasta As the ultraund beam tra Cnerge. The inteEty and th ndwave decras ia pr Aviriete of tieP ressure = P, Aorta 1.35 m Anterior tibial artery essure - P 8140 N/m2 6360 N/m2 2320 N/m2 2230 N/m2 7110 N/m2

An astronaut stands upright inside a capsule on the moon's surface. What is the difference between the blood pressure at the lower part of his anterior tibial artery and the average blood pressure in his heart, that derives from the height differen 1.30 m shown in the illustration? Take the density of blood to be 1060 kg/m3 and acceleration due to gravity on the moon to be 1.62 m/s2. Beam Attenuation What happens to the uitr Allemasta As the ultraund beam tra Cnerge. The inteEty and th ndwave decras ia pr Aviriete of tieP ressure = P, Aorta 1.35 m Anterior tibial artery essure - P 8140 N/m2 6360 N/m2 2320 N/m2 2230 N/m2 7110 N/m2

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Description: Not sure 2320 or 2230 An astronaut stands upright inside a capsule on the moon's surface. What is thedifference between the blood pressure at the lower part of his anterior tibial arteryand the average blood pressure in his heart, that derives from t

University Physics Volume 1

18th Edition

ISBN:9781938168277

Author:William Moebs, Samuel J. Ling, Jeff Sanny

Publisher:William Moebs, Samuel J. Ling, Jeff Sanny

Chapter14: Fluid Mechanics

Section: Chapter Questions

Problem 114AP: The left ventricle of a resting adult's heart pumps blood at a flow rate of 83.0 cm3/s , increasing...

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