Underneath a place where the sea floor is disappearing into a deep ocean trench, one expects there to be A a rising convection current in the Earth's mantle. B a descending convection current in the Earth's mantle. C a horizontal current in the Earth's mantle. D a bubble in the Earth's mantle. E a magnetic domain in the Earth's core.

(B) a descending convection current in the Earth's mantle

Explanation:

The connection between the sea floor and ocean produces a conventional current due to its waves

(b) a descending convection current in the Earth's mantle.

Explanation:

We cannot see the deep interior of Earth, but we know from a variety of observations that it is in continuous motion. This is because the mantle convects. This fundamental planetary process has profoundly influenced the character and evolution of Earth.

Mantle convection is the main way heat from Earth's interior is transported to its surface, and this heat escapes principally through mid-ocean ridges. In fact, the connected mid-ocean ridge system is in essence a 80,000 km long volcano.

Heat in the mantle comes from the Earth's molten outer core, decay of radioactive elements and, in the upper mantle, friction from descending tectonic plates. The heat in the outer core results from residual energy from the Earth's formative events and the energy generated by decaying radioactive elements. This heat warms the base of the mantle to an estimated 7,230°F. At the mantle-crust boundary. the mantle's temperature is an estimated 392°F.