Cement evaluation using neutron tool

What is claimed is: 1. A method for evaluating cement in a cased wellbore in a geological formation, the method comprising: placing a downhole tool into the cased wellbore, wherein the cased wellbore has been cased using a cement that contains a particular material; emitting neutrons using the downhole tool, wherein the neutrons interact with an environment of the wellbore including the geological formation and the particular material, wherein the neutrons: interact via inelastic scattering or capture of neutrons with the particular material resulting in the emission of prompt gamma ray radiation, wherein an energy spectrum of the prompt gamma ray radiation is characteristic of the particular material and/or cause activation of the particular material resulting in the delayed emission of gamma ray radiation, wherein an energy spectrum of the delayed gamma ray radiation is characteristic of the activated particular material; and using the downhole tool to measure the gamma ray radiation, wherein measuring the radiation comprises: detecting a first radiation signal representing radiation detected at a first depth of investigation using a first radiation detector; detecting a second radiation signal representing radiation detected at a second depth of investigation greater than the first depth of investigation using a second radiation detector; and detecting a third radiation signal representing radiation detected at a third depth of investigation greater than the second depth of investigation using a third radiation detector; wherein the measurement of radiation enables a thickness of the cement to be estimated based at least in part on a relationship between the first radiation signal, the second radiation signal and the third radiation signal, wherein the relationship is the following: R DS DM = Deep Shallow Late ( Deep Medium Total ) 3 wherein Deep Shallow Late  is a ratio between a late count of the third radiation signal and the first radiation signal and Deep Medium Total  is a ratio between a time integral of a count of the third radiation signal and of the third second radiation signal, wherein a late count is a count after 200 microseconds. 2. The method of claim 1 , comprising generating a well log illustrating an estimate of a thickness of the cement over well depth based at least in part on the detected radiation. 3. The method of claim 1 , comprising generating an azimuthal image illustrating an image of the entire borehole. 4. A downhole logging system, comprising: a downhole neutron tool configured to be moved into a wellbore in a geological formation, wherein the downhole acquisition tool comprises: one or more neutron generators for emitting neutrons into the formation; one or more radiation detectors, each configured to perform a measurement of radiation including a measurement of an energy spectrum of the radiation, wherein the radiation includes prompt gamma ray radiation resulting from interaction with neutrons via inelastic scattering or capture of neutrons delayed gamma ray radiation resulting from activation of the environment of the tool; and one or more non-transitory, tangible computer-readable media storing instructions to: receive one or more measurements of radiation obtained by the downhole neutron tool over a depth interval of a well, wherein the one or more measurements of radiation are measurements of: a first radiation signal representing radiation detected at a first depth of investigation using a first radiation detector; and a second radiation signal representing radiation detected at a second depth of investigation greater than the first depth of investigation using a second radiation detector; a third radiation signal representing radiation detected at a third depth of investigation greater than the second depth of investigation using a third radiation detector; estimate a thickness of cement surrounding a casing in the depth interval of the well based on the one or more measurements of radiation based at least in part on a relationship between the first radiation signal, the second radiation signal and the third radiation signal, wherein the relationship is the following: R DS DM = Deep Shallow Late ( Deep Medium Total ) 3 wherein Deep Shallow Late  is a ratio between a late count of the third radiation signal and the first radiation signal and Deep Medium Total  is a ratio between a time integral of a count of the third radiation signal and of the third second radiation signal, wherein a late count is a count after 200 microseconds. 5. A method for evaluating cement in a cased wellbore in a geological formation, the method comprising: placing a downhole tool into the cased wellbore, wherein the cased wellbore has been cased using a cement that contains a particular material; emitting neutrons using the downhole tool, wherein the neutrons interact with an environment of the wellbore including the geological formation and the particular material, wherein the neutrons: interact via inelastic scattering or capture of neutrons with the particular material resulting in the emission of prompt gamma ray radiation, and/or cause activation of the particular material resulting in the delayed emission of gamma ray radiation; and using the downhole tool to: detect a first radiation signal representing thermal neutrons using a neutron detector at a first depth of investigation; detect a second radiation signal representing gamma rays detected at a second depth of investigation greater than the first depth of investigation using a first gamma ray detector; and detecting a third radia