Reversible recording medium based on optical storage of information, method of reversible recording on such a medium

The invention claimed is: 1. A process for reading out a recording medium based on optical storage of at least one piece of information within a layer of a support material, said recording medium comprising: base molecules (M) having a first collective state (EC 1 ) of molecules in a local zone that are able to generate a first second harmonic signal (SH 1 ) that is characteristic of the first collective state (EC 1 ) of molecules when the molecules are excited by electromagnetic reading radiation; a portion of the base molecules (M) having the first collective state (EC 1 ) of molecules being transformed into dimerized molecules (M′) by two-photon absorption thus making the molecules that have the first collective state (EC 1 ) of molecules pass into a second collective state (EC 2 ) of molecules; the molecules having the second collective state (EC 2 ) of molecules being able to generate a second harmonic signal (SH 2 ) that is characteristic of this second collective state (EC 2 ) of molecules when the molecules are excited by the electromagnetic reading radiation; said process comprising the following step: applying an electromagnetic reading radiation over said recording medium with a wavelength able to generate a second harmonic signal (SH 2 ) that is characteristic of the second collective state (EC 2 ) of the molecules, wherein the base molecules (M) have a molecular structure that is based on a coumarin skeleton according to: where: k, n and m are positive numbers, and R and R 2 are substituents. 2. A process for reversible recording on and reading out a recording medium based on optical storage of at least one piece of information within a layer of a support material comprising: making base molecules (M) take on a first collective state (EC 1 ) of molecules in a local zone; with the molecules having the first collective state (EC 1 ) of molecules in the local zone being able to generate a first second harmonic signal (SH 1 ) that is characteristic of the first collective state (EC 1 ) of molecules when the molecules are excited by electromagnetic reading radiation; selectively applying electromagnetic writing radiation focused in a writing zone that forms a micro-volume of said local zone using a two-photon absorption, thereby transforming a portion of the base molecules (M) of said micro-volume having the first collective state (EC 1 ) of molecules into dimerized molecules (M′) thus making the molecules that have the first collective state (EC 1 ) of molecules pass into a second collective state (EC 2 ) of molecules; with the molecules having the second collective state (EC 2 ) of molecules being able to generate a second harmonic signal (SH 2 ) that is characteristic of this second collective state (EC 2 ) of molecules when the molecules are excited by the electromagnetic reading radiation; applying an electromagnetic reading radiation over said recording medium with a wavelength able to generate a second harmonic signal (SH 2 ) that is characteristic of the second collective state (EC 2 ) of the molecules, wherein the base molecules (M) have a molecular structure that is based on a coumarin skeleton according to: where: k, n and m are positive numbers, and R and R 2 are substituents. 3. The process for reading out a recording medium according to claim 1 , wherein: R is a methyl (CH 3 ) or a butyl (n-C 4 H 9 ); k is equal to 2 or 6; and n/m has a value of between 1/1 to 1/5. 4. The process for reading out a recording medium according to claim 1 , wherein the R 2 is a methyl group or a hydrogen atom. 5. The process for reversible recording on and reading out a recording medium according to claim 4 , wherein: R is a methyl (CH 3 ) or a butyl (n—C 4 H 9 ); k is equal to 2 or 6; and n/m has a value of between 1/1 to 1/5. 6. The process for reversible recording on and reading out a recording medium according to claim 4 , wherein the electromagnetic writing radiation has a wavelength that is greater than 300 nm in such a way as to generate a photo-induced dimerization of the base molecules (M). 7. The process for reversible recording on and reading out a recording medium according to claim 4 , wherein the base molecules (M) have, in a local zone, a collective state of molecules (M) among n collective states (EC n ) of molecules, with n being an integer that is greater than or equal to 2, with the process comprising: selectively applying several forms of specific electromagnetic writing radiation focused in the writing zones that form micro-volumes, using a two-photon absorption, thereby making said base molecules (M) of the first collective state (EC 1 ) of molecules pass into dimerized molecules (M′) to make each writing zone of the first collective state (EC 1 ) of molecules pass to one of the n collective states of molecules in the writing zone; such that the molecules of each of the n−1 collective states (EC n−1 ) of molecules (M) are able to generate an n−1 th second harmonic signal (SH n−1 ) that is characteristic of the collective state (EC n−1 ) of molecules (M) when the molecules (M) are excited by an electromagnetic reading radiation. 8. The process for reversible recording on and reading out a recording medium according to claim 4 , further comprising: selectively applying electromagnetic erasing radiation at least one erasing zone, with the electromagnetic erasing radiation transforming at least a portion of the dimerized molecules (M′) into base molecules (M). 9. The process for reversible recording on and reading out a recording medium according to claim 4 , further comprising: applying in a generalized way an electromagnetic erasing radiation at the dimerized molecules (M′), with the electromagnetic erasing radiation transforming the dimerized molecules (M′) into base molecules (M). 10. The recording process according to claim 9 , wherein the electromagnetic erasing radiation is UV radiation. 11. The process for reversible recording on and reading out a recording medium according to claim 4 , wherein the R 2 is a methyl group or a hydrogen atom.