Devices, systems and methods for determining depth of interaction in positron emission tomography detectors

What is claimed is: 1. A positron emission tomography (PET) detector being configured to identify a depth of a photon gamma interaction, comprising: a crystal array including a plurality of crystal elements, the plurality of crystal elements being arranged along a first direction and a second direction so as to define a plurality of crystal groups along the first direction, each of the plurality of crystal groups including at least two crystal elements of the plurality of crystal elements, each of the plurality of crystal elements including a first end and a second end and extending along a third direction from the first end to the second end, and a photon-sensor array optically coupled with the crystal array, wherein at least one pair of neighboring crystal groups of the plurality of crystal groups include: a first optical separator of a first length located between the crystal groups of the at least one pair of neighboring crystal groups, the first length being along the third direction; and a second optical separator of a second length located between two neighboring crystal elements of a crystal group of the at least one pair of neighboring crystal groups, the second length being along the third direction, wherein the first length of the first optical separator is equal to a length of at least one of the two neighboring crystal elements between which the first optical separator is located, and the second length of the second optical separator is shorter than a length of at least one of the two neighboring crystal elements between which the second optical separator is located. 2. The PET detector of claim 1 , wherein the photon-sensor array forms a single-end read-out structure, and the photon-sensor array includes a plurality of photon-sensors configured to receive photons emitted from the first ends of the plurality of crystal elements. 3. The PET detector of claim 2 , wherein each photon-sensor of the photon-sensor array is optically coupled with one or more crystal elements of the plurality of crystal elements. 4. The PET detector of claim 1 , wherein: the detector further comprises one or more third optical separators, each of the one or more third optical separators being located between two neighboring crystal elements along the second direction. 5. The PET detector of claim 4 , wherein at least one of the first optical separator, the second optical separator, or the one or more third optical separators includes at least one of a reflective film, a reflective foil, or a reflective coating. 6. The PET detector of claim 1 , wherein: the second length of the second optical separator is equal to or greater than a half of a length of at least one of the two neighboring crystal elements between which the second optical separator is located, the length of the crystal element being along the third direction. 7. The PET detector of claim 1 , wherein: at least one of the first optical separator or second optical separator extends, along the third direction, from the first end of at least one of two neighboring crystal elements between which the at least one of the first or second optical separator is located. 8. The PET detector of claim 1 , wherein in at least one crystal group of the plurality of crystal groups, the second ends of the at least two crystal elements are integrated into a single end. 9. The PET detector of claim 1 , wherein the plurality of crystal elements forms a plurality of detector rings arranged along an axial direction of the detector. 10. A method for determining photon gamma interaction positions implemented on a computing machine having one or more processors and one or more storage devices, the method comprising: obtaining output information of at least two photon-sensors, the at least two photon-sensors being optically single-end-coupled with a crystal group of a PET detector according to claim 1 ; and determining, based on the output information, a position of the photon gamma interaction within the crystal group. 11. The method of claim 10 , wherein the determining the position of the photon gamma interaction within the crystal group comprises: identifying, in the crystal group, a target crystal element in which the photon gamma interaction occurs based on the output information. 12. The method of claim 11 , further comprising: determining, based on the output information, a depth of the photon gamma interaction within the target crystal element. 13. The method of claim 10 , wherein the output information of the at least two photon-sensors comprises an energy detected by each of the at least two photon-sensors, and the determining the position of the photon gamma interaction within the crystal group comprises: determining, based on the energy detected by each of the at least two photon-sensors, a total energy detected by the at least two photon-sensors; and determining, based on the energy detected by each of the at least two photon-sensors and the total energy, the position of the photon gamma interaction within the crystal group. 14. The method of claim 10 , wherein the PET detector including a plurality of crystal groups, the method further comprising: determining, based on the output information, a plurality of candidate positions of the photon gamma interaction in the plurality of crystal groups, each of the plurality of candidate positions corresponding to one of the plurality of crystal groups and including a candidate depth of the photon gamma interaction within the corresponding crystal group; determining, based on the output information, that an inter crystal scatter (ICS) occurs within the plurality of crystal groups; and designating, among the plurality of candidate positions, the candidate position with the smallest candidate depth as a position of the photon gamma interaction. 15. A positron emission tomography (PET) detector being configured to identify a depth of a photon gamma interaction, comprising: a crystal array including a plurality of crystal elements, the plurality of crystal elements being arranged along a first direction and a second direction so as to define a plurality of crystal groups along the first direction, each of the plurality of crystal groups including at least two crystal elements of the plurality of crystal elements, each of the plurality of crystal elements including a first end and a second end and extending along a third direction from the first end to the second end, and a single-end read-out structure including a photon-sensor array optically coupled with the crystal array, wherein at least one crystal group of the plurality of crystal groups includes: an optical window configured to allow a light transmission between the at least two crystal elements of the at least one crystal group, so that a photon excited by an photon gamma interaction in a first crystal element of the at least one crystal group can travel into a second crystal element of the at least one crystal group through the second end of the first crystal element, the optical window, and the second end of the second crystal element. 16. The PET detector of claim 15 , wherein the optical window of the at least one crystal group includes: for each of the at least two crystal elements of the at least one crystal group, an optical separator mounted on each side surface of the crystal element that faces an neighboring crystal element of the crystal element along the first direction, a length of the optical separator equal to a length of at least one of the crystal element or the neighboring crystal element, the length of the optical separator