Explanation: Spalling is a broader term encompassing fragment detachment from a solid body, not exclusively limited to projectile impacts. It can result from various mechanical, thermal, and chemical processes.

Explanation: This statement accurately defines spalling as a process of surface failure where fragments are shed from a larger solid mass.

Explanation: Spalling is not limited to metallic materials; it can occur in ceramics, rocks, concrete, and other solid substances under appropriate conditions.

Explanation: Spalling is fundamentally a process of material *removal* or fragmentation from the surface, not the formation of a protective layer. Protective layer formation is characteristic of passivation.

Explanation: Spalling is a phenomenon observed across a wide range of materials, including ceramics, concrete, polymers, and biological tissues, not solely geological materials and metals.

Explanation: Spalling is a form of material degradation and failure, characterized by the loss of fragments. It weakens a material rather than strengthening it.

Explanation: Spalling is fundamentally a process of material removal, involving the detachment and shedding of fragments from a surface, not material addition.

Explanation: A 'spall' is defined as a fragment that detaches from a larger solid body, representing the outcome of a surface failure process.

Explanation: Both 'spalling' and 'spallation' refer to the process where fragments detach from the surface of a solid material.

Explanation: Mechanical spalling in ball bearings is a consequence of stress concentrations. The maximum shear stress, which drives this failure mode, is typically located slightly below the surface, not directly on it.

Explanation: Plate impact spalling occurs when compression waves generated by impact reflect off free surfaces. This reflection can create a zone of high tensile stress within the material, leading to the detachment of a spall.

Explanation: Cavitation causes spalling not by dissolving material, but by the rapid collapse of vapor bubbles, which generates intense, localized high pressures capable of causing surface damage and fragment detachment.

Explanation: High rolling pressures in bearings can induce subsurface stresses that exceed the material's shear strength, leading to the formation and ejection of spalls.

Explanation: The visual evidence from high-speed photography demonstrates that spallation can occur as a result of impact stresses, even if the projectile does not fully breach the material's thickness.

Explanation: Spalling due to unloading occurs when pressure on a rock mass *decreases* rapidly, causing expansion and tensile stress at the surface.

Explanation: The implosion of cavitation bubbles creates localized shock waves and high pressures that can cause material fatigue and spalling on adjacent surfaces.

Explanation: The failure mechanism in mechanical spalling of bearings involves shear stresses that peak slightly below the surface, leading to material detachment.

Explanation: While cavitation, corrosion, and projectile impact are identified as causes of spalling, sublimation (the direct transition of a substance from solid to gas) is not presented as a mechanism for spalling in this material.

Explanation: The critical stress concentration for mechanical spalling in ball bearings occurs slightly beneath the surface, leading to subsurface shear failure.

Explanation: When compression waves reflect off a free surface, they can convert into tensile waves. The superposition of these tensile waves can create localized regions of high tensile stress, leading to spalling.

Explanation: The violent collapse, or implosion, of cavitation bubbles generates micro-jets and shock waves that produce extremely high localized pressures, capable of causing material fatigue and spalling.

Explanation: When overlying pressure is removed from rock masses (unloading), the rock expands. If this release is rapid, it generates tensile stresses at the surface, leading to spalling.

Explanation: The implosion of cavitation bubbles creates localized pressure spikes that can induce fatigue and material removal, leading to spalling on component surfaces.

Explanation: The image provides visual evidence that spallation can occur as a consequence of impact stresses, even if the projectile does not fully penetrate the target material.

Explanation: Mechanical weathering encompasses several processes that can lead to spalling, such as the expansion of ice within rock pores during freeze-thaw cycles and the pressure exerted by crystallizing salts within porous materials.

Explanation: Exfoliation weathering is caused by *differential* thermal expansion and contraction between the surface layers and the underlying rock, not uniform cycles. This stress leads to the peeling of surface layers.

Explanation: Extreme temperature changes, like those from fires, cause rapid surface heating and expansion. This differential thermal stress between the surface and interior can lead to the detachment of rock fragments, a process known as spalling.

Explanation: Salt spalling occurs when dissolved salts crystallize *near the surface* of porous materials as water evaporates. The expansion of these crystals exerts pressure, causing surface fragments to break off.

Explanation: Corrosion-induced spalling involves the shedding of poorly adhering corrosion products. This is distinct from passivation, where a stable, protective oxide layer forms.

Explanation: Desquamation, as seen on the dunite boulder, is a form of spalling involving the peeling of surface layers. While it is a weathering process, it is typically driven by physical factors like thermal stress or unloading, not solely chemical erosion.

Explanation: Exfoliation, or onion skin weathering, on granite domes involves the shedding of surface layers. This phenomenon is caused by differential thermal expansion and contraction, leading to the peeling of these layers.

Explanation: Freeze-thaw cycles are a significant driver of mechanical weathering, where water freezing and expanding within rock fissures creates stresses that lead to the detachment of surface fragments (spalling).

Explanation: Granite dome exfoliation, where layers peel away, is a classic example of onion skin weathering, driven by thermal stresses.

Explanation: Spalling in corrosion refers to the shedding of poorly adherent corrosion products, indicating a failure of surface integrity, unlike the protective layer formed during passivation.

Explanation: Exfoliation weathering involves the peeling of rock layers, a type of spalling, driven by the stresses induced by repeated expansion and contraction due to temperature fluctuations.

Explanation: Exfoliation weathering, also known as onion skin weathering, is characterized by the detachment of surface layers in sheets or flakes, driven by stresses from thermal expansion and contraction.

Explanation: Passivation creates a stable, protective oxide layer that inhibits further corrosion. Spalling, conversely, is a failure mechanism involving the detachment of loosely bound corrosion products, indicating a loss of surface integrity.

Explanation: Desquamation refers to the shedding or peeling of surface layers, which is a manifestation of spalling, often observed as a weathering process on rock surfaces.

Explanation: Exfoliation is the geological term for the process where rock layers peel away from the surface, driven by stresses from thermal expansion and contraction.

Explanation: Passivation results in the formation of a stable, protective surface layer, whereas spalling is a failure mechanism involving the detachment of material from the surface.

Explanation: Desquamation is a form of spalling observed in weathering where surface layers peel away, akin to shedding fragments from a rock.

Explanation: As water evaporates from porous materials, dissolved salts crystallize within the pores. The expansion of these crystals exerts pressure, causing surface fragments to detach.

Explanation: The dunite boulder image demonstrates desquamation, a type of spalling characterized by the peeling of surface layers, often a result of weathering processes.

Explanation: In particle physics applications, particularly in neutron scattering instrumentation, 'spall' refers to the neutrons that are generated when a target material is bombarded by a stream of atoms.

Explanation: HESH shells are designed to deform against armor and then detonate, creating a shock wave that causes spalling on the interior surface of the armor, rather than direct penetration.

Explanation: Kinetic energy penetrators, while designed for penetration, frequently cause significant spalling on the interior surfaces of armor, contributing to damage beyond the initial penetration hole.

Explanation: Spall liners are installed on the *interior* of armored vehicles. Their function is to absorb the energy of spalling fragments generated from the armor's inner surface, thereby protecting the crew.

Explanation: The Wz. 35 anti-tank rifle is recognized as an early weapon specifically designed to induce spallation effects within enemy armor, rather than relying solely on direct penetration.

Explanation: Depleted uranium and other actinide metals are hazardous due to their toxicity and their pyrophoric nature, meaning they can spontaneously ignite when exposed to air, often exacerbated by their tendency to spall.

Explanation: Due to their pyrophoric nature and other hazards, actinide metals are typically managed under controlled conditions, such as an inert atmosphere within a glovebox, to prevent ignition and minimize exposure.

Explanation: Spalling in refractory concrete is predominantly driven by internal factors such as thermal strain and the pressure generated by escaping water vapor during rapid heating, rather than external impacts.

Explanation: Explosive spalling events in refractory concrete can be hazardous, characterized by the ejection of large fragments (often weighing 1-10 kg) over significant distances, posing risks to personnel and equipment.

Explanation: The process of knapping obsidian to create tools like arrowheads involves controlled spalling, where flakes are intentionally detached to form sharp edges and shape the artifact.

Explanation: The armor plating from HMS New Zealand, damaged during the Battle of Jutland, demonstrates spalling resulting from the impact of naval shells, not from corrosion.

Explanation: Behind-armour debris refers to fragments generated *inside* an armored vehicle, typically resulting from spalling of the interior armor surface after a projectile impact.

Explanation: During rapid heating, thermal expansion and the build-up of steam pressure within refractory concrete create internal stresses that lead to spalling.

Explanation: HESH shells induce spalling on the *interior* surface of armor due to shock wave reflection, not the exterior.

Explanation: In particle physics, particularly in the context of neutron sources, these terms refer to the process where neutrons are ejected from a target material when it is bombarded by atomic particles.

Explanation: Rapid heating causes thermal expansion and strain within refractory concrete. Coupled with internal water pressure, this leads to stresses that result in spalling.

Explanation: The primary function of spall liners is to absorb the kinetic energy of fragments that break off the inner surface of armor due to projectile impact, thus protecting the vehicle's occupants.

Explanation: The Wz. 35 rifle's design focused on causing internal damage through spalling rather than solely relying on direct penetration, marking an early development in anti-armor tactics.

Explanation: Knapping, the process of shaping stone tools like obsidian arrowheads, relies on controlled spalling to produce sharp cutting edges.

Explanation: In particle physics, 'spall' refers to the neutrons produced when a target material is bombarded by atomic particles.

Explanation: HESH shells are designed to create a localized shock wave that propagates through the armor. This wave reflects off the interior surface as a tensile wave, causing spall fragments to be ejected inward.

Explanation: Spall liners are installed internally to mitigate the threat posed by spalling fragments, absorbing their kinetic energy and preventing them from reaching the crew or critical components.

Explanation: Actinide metals like depleted uranium are noted for their pyrophoric nature, meaning they can ignite spontaneously in air, a hazard often associated with their surface properties and tendency to spall.

Explanation: The principal drivers of spalling in refractory concrete are thermal strain, induced by rapid heating, and internal pressures generated as water is expelled from the material.

Explanation: Knapping obsidian involves controlled spalling to detach flakes, thereby shaping the stone into tools and creating sharp edges.

Explanation: The damaged armor plating from HMS New Zealand serves as a historical example of spalling caused by the kinetic impact of naval artillery during combat.

Explanation: Explosive spalling can violently eject large fragments, creating a hazardous environment and compromising the structural integrity of the refractory lining.

Explanation: Spall liners are installed internally to intercept and absorb fragments that spall off the inner face of the armor after a projectile impact, thereby protecting the crew.

Explanation: Actinide metals like depleted uranium are highly hazardous due to their pyrophoric nature, meaning they can spontaneously ignite upon exposure to air, in addition to their toxicity.

Explanation: Explosive spalling can violently eject large fragments, creating a hazardous environment and compromising the structural integrity of the refractory lining.

Explanation: The Wz. 35 rifle was an early example of anti-tank weaponry designed to induce spallation within the target vehicle, causing internal damage through fragmentation.

Explanation: Blast-wave overpressure causes anatomical spalling in the human body at interfaces between tissues of *different* densities, where pressure gradients are most pronounced, such as between solid organs and gas-filled cavities.

Explanation: Blast injuries are primarily attributed to three distinct mechanisms: spalling, implosion, and shearing.

Explanation: Blast injuries result from multiple mechanisms, including spalling, implosion, and shearing, not solely from spalling.

Explanation: Blast waves create pressure gradients. Spalling occurs at the boundaries between tissues with differing densities (e.g., lung tissue and body cavities) where these pressure differentials are most significant.

Explanation: The three primary mechanisms responsible for blast injuries are spalling, implosion, and shearing. Implosion refers to the collapse of structures or tissues under pressure.

Explanation: Spalling, implosion, and shearing are recognized as the principal mechanisms through which blast waves inflict damage on biological tissues.

Explanation: The Misnay–Schardin effect is related to the fracture mechanics of materials under high-speed impact, often involving crack propagation and fragmentation, rather than a gain in material strength.

Explanation: While related to material failure, friability (tendency to crumble) and frangibility (tendency to shatter) are distinct concepts from spalling, which specifically refers to the shedding of fragments from a solid body due to surface failure.

Explanation: The Misnay–Schardin effect describes the complex fracture patterns observed in materials subjected to high-velocity impacts, often involving the generation of spalls.