Compression fossil
A compression fossil is a type of fossil preservation in which an organism or its parts, such as leaves, insects, or soft tissues, are flattened between layers of fine-grained sediment, resulting in a two-dimensional carbonized residue that captures the external morphology and sometimes microscopic details of the original structure.[1] This process, often involving carbonization, occurs when organic material is rapidly buried in environments like lakes or floodplains, where low oxygen levels slow decay, and subsequent pressure from overlying sediments squeezes out volatile compounds, concentrating carbon into a thin black or brown film.[2] Unlike mere impressions, which are hollow imprints lacking organic residue, compressions retain this carbonaceous layer, making them valuable for studying ancient ecosystems, particularly in Paleozoic and Mesozoic plant and insect records.[1] Notable examples include Eocene crane flies from Florissant Fossil Beds National Monument and Eocene sycamore leaves from John Day Fossil Beds National Monument, where the preserved films reveal details like venation and wing patterns.[1][3] Compression fossils differ from three-dimensional molds or casts by their planar nature and organic preservation, though they can be fragile and prone to degradation in older rocks due to the instability of the carbon film.[4]Overview
Definition
A compression fossil is formed by the physical compression of organic remains into fine-grained sedimentary rock, resulting in a flattened impression where some original organic material may be preserved, often chemically altered into a thin carbon film.[1] This process creates a two-dimensional representation of the organism, with the side retaining more organic residue termed the "part" and the corresponding mold on the opposing rock surface called the "counterpart."[2] Compression fossils are particularly common among plant remains due to the inherently flat and soft nature of plant structures, such as leaves and stems, which compress readily under sediment overburden without significant resistance.[2] In contrast, they are rarer in animals, as the distortion of three-dimensional body forms, especially those with hard parts like shells or bones, typically prevents clear preservation through this mechanism unless the organisms are small or soft-bodied.[2] The term "compression" specifically denotes pressure-induced flattening of the actual organic material, distinguishing it from mere casting, where a mold is filled by minerals to replicate the shape without retaining the original remains.[5]Distinction from Other Fossils
Compression fossils differ from impression fossils primarily in the retention of organic material. While both types result from the flattening of organisms under sedimentary pressure, impressions form as mere external molds or prints on rock surfaces without any preserved organic residue, capturing only the shape and texture of the organism's exterior. In contrast, compression fossils preserve a thin film of carbonized organic matter, often derived from the distillation or carbonization of the original tissues, which provides additional chemical and structural information beyond mere morphology.[6][2][7] Unlike permineralized fossils, which involve the infiltration of minerals such as silica or calcite into the organism's pores and tissues, filling them to create a three-dimensional preservation of the original structure and internal details, compression fossils undergo external flattening without significant mineralization of internals. This process preserves the overall outline and some surface details but results in a two-dimensional representation, as the original volume is lost to compaction. Permineralization, by preserving both external form and internal anatomy in 3D, allows for detailed study of cellular structures, whereas compression emphasizes flattened external features.[8][9][7] Compression fossils also contrast with those preserved in amber or as casts. Amber entrapment encases organisms in hardened resin, maintaining three-dimensional integrity and often soft tissues without flattening or compression, primarily seen in insects, and occasionally in small vertebrates such as lizards and frogs. Cast fossils, formed when sediment fills a mold left by a decayed organism and hardens into a replica, replicate the external shape in 3D but lack original material entirely. Compression, occurring in sedimentary contexts without encasement or molding, focuses on the partial degradation and flattening of organic remains in fine-grained sediments.[10][2][8]| Fossil Type | Preservation Method | Retained Structures | Common Taxa |
|---|---|---|---|
| Compression | Flattening under sediment with carbonization | 2D outline, carbon film, some surface details | Plants (e.g., leaves, ferns) |
| Impression | External molding without organics | 2D shape and texture only | Plants, invertebrates |
| Permineralized | Mineral infiltration into tissues | 3D form, internal anatomy | Plants (wood), some animals |
| Amber | Encase in resin | 3D unaltered, soft tissues | Insects, occasionally small vertebrates |
| Cast | Sediment filling of mold | 3D external replica | Shells, vertebrates, tracks |