Explanation: Sea stacks are geological landforms primarily formed through the process of wave erosion, not by the deposition of sediment.

Explanation: The term 'stack' can also be loosely applied to isolated, steep-sided rocky oceanic islets of volcanic origin, not exclusively to erosional coastal features.

Explanation: A stack, or sea stack, is fundamentally defined as a steep, often vertical column of rock located in the sea near a coast, primarily formed by wave erosion.

Explanation: Beyond purely erosional coastal features, isolated, steep-sided rocky oceanic islets of volcanic origin are also sometimes broadly referred to as stacks.

Explanation: Hydraulic action contributes to stack formation through the physical force of water crashing against rock, eroding and weakening cracks, rather than through chemical dissolution.

Explanation: Stacks can form even without the continuous presence of water, as sub-aerial processes like wind erosion can cause the collapse of natural arches, leaving behind a stack.

Explanation: The initial step in stack formation involves the sea exploiting existing lines of weakness, such as geological joints or fault zones, within a cliff face.

Explanation: The process of stack formation begins with the sea attacking lines of weakness in a cliff, which enlarge into sea caves. These sea caves then continue to erode, eventually wearing through the headland to form natural arches.

Explanation: Sub-aerial processes, such as wind erosion, are weathering and erosional processes occurring on land that can cause the collapse of natural arches, leading to the formation of a stack.

Explanation: Geological joints and fault zones are areas of inherent weakness in rock that the sea exploits, initiating erosion and contributing to stack formation, rather than protecting cliffs from it.

Explanation: The primary natural agents responsible for the formation of geological stacks are wind and water, which cause erosion of coastal landforms.

Explanation: Hydraulic action contributes to sea stack formation by the powerful force of water crashing against a headland, eroding and weakening cracks within the rock.

Explanation: Stacks can form through the collapse of a natural arch, which can be caused by sub-aerial processes like wind erosion, even without the continuous presence of water.

Explanation: The very first step in stack formation involves the sea attacking existing lines of weakness, such as joints or fault zones, within a cliff face.

Explanation: Initial weaknesses in a cliff face, such as joints or fault zones, gradually enlarge over time due to continuous erosion, eventually developing into sea caves.

Explanation: When a sea cave continues to erode and wears completely through a headland, it forms a natural arch.

Explanation: The collapse of a natural arch due to further erosion directly leads to the emergence of a free-standing stack, as the remaining rock pillar becomes isolated from the coast.

Explanation: Sub-aerial processes are weathering and erosional processes that occur on land, exposed to the atmosphere, and can contribute to stack formation by causing the collapse of natural arches.

Explanation: Stacks commonly form in horizontally bedded sedimentary or volcanic rocks, such as limestone, because their medium hardness provides a balanced resistance to erosion, allowing for their gradual shaping.

Explanation: Cliffs made of claystone or highly jointed rock are generally unsuitable for stack formation because they erode too quickly and slump, preventing the stable isolation of a rock column.

Explanation: Harder rocks like granite are less likely to form stacks than medium-hard rocks because their greater resistance or different structural properties lead to the formation of alternative landforms under coastal erosion.

Explanation: A capstone is a more resistant layer of rock that forms on top of a stack, which can slow down its erosion, rather than being a less resistant layer at the base that accelerates erosion.

Explanation: Sedimentary rocks are ideal for stack formation due to their characteristic horizontally bedded structure and medium hardness, not a random, unlayered structure or extreme hardness.

Explanation: Volcanic rocks, when horizontally bedded and of medium hardness, are indeed suitable for stack formation through coastal erosion, similar to sedimentary rocks.

Explanation: The horizontally bedded nature of rocks is crucial for stack formation, as it allows the sea to exploit weaknesses along these planes, which helps carve out the characteristic steep, vertical column shape.

Explanation: Stacks typically form in horizontally bedded sedimentary or volcanic rocks of medium hardness, as these properties provide a balanced resistance to erosion for their gradual shaping.

Explanation: Rock types like claystone or highly jointed rock are unsuitable for stack formation because their rapid erosion and tendency to slump prevent the stable, gradual shaping required to isolate a column.

Explanation: Harder rocks like granite are less likely to form stacks because their superior resistance and distinct structural properties result in different landforms when subjected to coastal erosion, unlike the gradual shaping seen in medium-hard rocks.

Explanation: In the context of stack formation, a capstone is a more resistant layer of rock that can form on top of a stack, potentially slowing its erosion.

Explanation: Sedimentary rocks are formed from accumulated particles and are commonly associated with stack formation due to their horizontally bedded structure and medium hardness, which are ideal for gradual erosion.

Explanation: Limestone cliffs are common locations for stack formation because limestone possesses specific characteristics, such as medium hardness and a tendency to form horizontally bedded cliffs, which are ideal for the erosional processes involved.

Explanation: The final stage of a stack's life cycle is its collapse into a stump, which is a small rock island often submerged by high tide, not a large, permanent island.

Explanation: As erosion continues, a stack will eventually collapse, forming a stump, which is a small rock island often submerged by high tide, representing the final stage of its geological life cycle.

Explanation: Geological stacks are ecologically significant as nesting sites for seabirds and are also popular recreational destinations for rock climbing.

Explanation: The Twelve Apostles stacks are located in Victoria, Australia, not New Zealand, as indicated by the source material.

Explanation: Dún Briste at Downpatrick Head in Ireland showcases 350 million years of geological history, not 350,000 years.

Explanation: Ball's Pyramid is notable for being the tallest sea stack in the world, not the deepest underwater sea stack.

Explanation: Geological stacks serve as important nesting sites for seabirds and are also popular recreational areas for rock climbing.

Explanation: The Twelve Apostles stacks are located in Victoria, Australia, as stated in the provided image caption.

Explanation: According to the image caption, Dún Briste is the geological feature highlighted at Downpatrick Head in County Mayo, Ireland.

Explanation: Ball's Pyramid is significant as it is recognized as the tallest sea stack in the world.

Explanation: The geological history visible at Dún Briste, Downpatrick Head, spans 350 million years, as indicated by its clear horizontal bedding.

Explanation: Coastal geomorphology is the specific field of study that examines the origin and evolution of landforms along coastlines, including the processes involved in the formation of geological stacks.

Explanation: A headland is a piece of land that projects out into the sea and is subject to erosion, rather than receding from the sea and protecting the coast.

Explanation: Erosion is a geological process that involves the wearing away and transport of rock and soil by natural forces, rather than the building up of landforms through volcanic activity.

Explanation: Coastal geomorphology is the scientific discipline that studies the origin and evolution of landforms along coastlines, including the erosional processes by wind and water that lead to stack formation.

Explanation: Erosion is defined as the geological process where natural forces like wind and water wear away and transport rock and soil, which is fundamental to shaping landforms such as stacks.