Core catchers for coring tools and related coring tools and methods

What is claimed is: 1. A core catcher for a coring tool, comprising: a sleeve comprising a slit extending along at least a portion of a height of the sleeve; a crosspiece extending at least partially across the at least one slit and at least partially around a perimeter of the sleeve; and a track extending at least partially around the perimeter of the sleeve, the crosspiece being slidably engaged with the track; wherein the crosspiece and the track are configured to cooperatively delimit relative movement of portions of the sleeve on opposite sides of the slit as a width of the slit increases or decreases responsive to receipt of a core sample into the core catcher. 2. The core catcher of claim 1 , wherein the crosspiece and the track are configured to cooperatively delimit relative movement of the portions of the sleeve on opposite sides of the slit as the width of the slit increases or decreases such that a difference between a first distance, the first distance extending between a first surface of the sleeve defining the slit on a first side of the slit and a longitudinal axis of the sleeve, and a second distance, the second distance extending between a second surface of the sleeve defining the slit on a second, opposite side of the slit and the longitudinal axis, is less than a thickness of the sleeve, as measured in a direction perpendicular to the longitudinal axis. 3. The core catcher of claim 2 , wherein the crosspiece and the track are configured to cooperatively delimit relative movement of the portions of the sleeve on opposite sides of the slit as the width of the slit increases or decreases such that the difference between the first distance and the second distance is at least substantially zero. 4. The core catcher of claim 1 , wherein a distal end of the crosspiece is larger than a remainder of the crosspiece and wherein a height of an entrance to the track is less than a height of a remainder of track, such that the entrance to the track retains the distal end of the crosspiece within the track. 5. The core catcher of claim 1 , wherein the track comprises a recess and wherein the crosspiece comprises a complementary, cantilevered member extending into the recess to retain the crosspiece engaged with the track. 6. The core catcher of claim 1 , wherein the crosspiece extends at least partially around the perimeter of the sleeve in a first direction, further comprising another crosspiece extending at least partially across the at least one slit and at least partially around the perimeter of the sleeve in a second, opposite direction, and wherein the crosspiece and the other crosspiece at least partially overlap. 7. The core catcher of claim 1 , wherein the sleeve further comprises a plurality of openings extending radially between an inner surface and an outer surface of the sleeve. 8. The core catcher of claim 1 , wherein the crosspiece comprises at least one of an elastic deformable material, a spring, and a telescoping member. 9. The core catcher of claim 1 , wherein the sleeve and the crosspiece comprise an additive manufactured structure. 10. The core catcher of claim 1 , wherein the crosspiece is unfixed from the sleeve and wherein each distal end of the crosspiece is larger than a central portion of the crosspiece and wherein heights of entrances to the track on opposite sides of the slit are less than a height of a remainder of track, such that the entrances to the track retain the distal ends of the crosspiece within the track. 11. The core catcher of claim 1 , wherein the crosspiece is affixed to the sleeve and is cantilevered from the sleeve at least partially across the slit. 12. The coring tool of claim 1 , wherein each of the crosspiece and the track is integrally formed with the sleeve. 13. A coring tool for extracting a core of subterranean formation from a wellbore, comprising: a tubular member having a central bore configured to receive a sample of a subterranean formation; and a core catcher housed within the central bore of the tubular member and comprising: a sleeve comprising a slit extending along at least a portion of a height of the sleeve; a crosspiece extending at least partially across the at least one slit and at least partially around a perimeter of the sleeve; and a track extending at least partially around the perimeter of the sleeve, the crosspiece being slidably engaged with the track; wherein the crosspiece and the track are configured to cooperatively delimit relative movement of portions of the sleeve on opposite sides of the slit as a width of the slit increases or decreases responsive to receipt of a core sample into the core catcher. 14. The coring tool of claim 13 , wherein the crosspiece and the track are configured to cooperatively delimit relative movement of the portions of the sleeve on opposite sides of the slit as the width of the slit increases or decreases such that a difference between a first distance, the first distance extending between a first surface of the sleeve defining the slit on a first side of the slit and a longitudinal axis of the sleeve, and a second distance, the second distance extending between a second surface of the sleeve defining the slit on a second, opposite side of the slit and the longitudinal axis, is less than a thickness of the sleeve, as measured in a direction perpendicular to the longitudinal axis. 15. The coring tool of claim 14 , wherein the crosspiece and the track are configured to cooperatively delimit relative movement of the portions of the sleeve on opposite sides of the slit as the width of the slit increases or decreases such that the difference between the first distance and the second distance is at least substantially zero. 16. A method for extracting a core sample from a wellbore in a subterranean formation, comprising: cutting a core sample from a subterranean formation; receiving the core sample in a sleeve of a core catcher; responsive to receiving the core sample in the sleeve of the core catcher, expanding a slit extending along at least a portion of a height of the sleeve; sliding a crosspiece, the crosspiece extending at least partially across the at least one slit and at least partially around a perimeter of the sleeve, in a first direction relative to a track in which the crosspiece is slidably engaged responsive to expanding the slit; receiving the core catcher having the core therein within a central bore of a core shoe, and contracting the slit responsive to receiving the core catcher within the central bore of the core shoe; and sliding the crosspiece in a second, opposite direction relative to the track responsive to contracting the slit. 17. The method of claim 16 , further comprising delimiting relative movement of portions of the sleeve on opposite sides of the slit utilizing the crosspiece and the track responsive to expanding the slit. 18. The method of claim 16 , further comprising maintaining a difference between a first distance, the first distance extending between a first surface of the sleeve defining the slit on a first side of the slit and a longitudinal axis of the sleeve, and a second distance, the second distance extending between a second surface of the sleeve defining the slit on a second, opposite side of the slit and the longitudinal axis, less than a thickness of the sleeve, as measured in a direction perpendicular to the longitudinal axis, utilizing the crosspiece and the track. 19. The method of claim 18 , further comprising maintaining the difference between the first distance and the