Apparatus and methodology for measuring properties of microporous material at multiple scales

What is claimed is: 1. A method for characterizing properties of a manufactured rock sample, comprising: a) providing a first test apparatus including a sample holder and associated upstream and downstream pressure sensors, wherein the sample holder has a configuration that contains the manufactured rock sample under pressurized confinement and allows for a pulse of test fluid to flow through the manufactured rock sample contained within the sample holder, and wherein the pressure sensors of the first test apparatus have a configuration that measures pressure on the upstream and downstream sides of the manufactured rock sample as the pulse of test fluid flows through the manufactured rock sample contained within the sample holder; b) providing a second test apparatus including a sample cell and associated pressure sensor, wherein the sample cell has a configuration where the sample cell is filled with test fluid under pressure and isolated from other parts of the second test apparatus, and wherein the pressure sensor of the second test apparatus has a configuration that measures pressure of the sample cell when the sample cell is isolated from other parts of the second test apparatus; c) using the first test apparatus with the manufactured rock sample loaded within the sample holder to characterize bulk properties of the manufactured rock sample; d) using the second test apparatus with the manufactured rock sample loaded within the sample cell to characterize bulk properties of the manufactured rock sample; e) dividing the manufactured rock sample into a number of pieces of different sizes; f) partitioning the pieces of the manufactured rock sample resulting from e) into size-groups of different sizes; g) performing a sequence of operations for each given size-group of the pieces resulting from f), wherein the sequence of operations of g) includes g1) loading the one or more pieces of the given size-group into the sample cell of the second test apparatus, g2) subsequent to g1), configuring the second test apparatus to perform a sequence of test operations whereby the loaded sample cell is filled with test fluid under pressure and isolated from other parts of the test apparatus and the pressure sensor of the second test apparatus is used to measure and store pressure data that represents pressures measured by the pressure sensor over time, g3) using a data processing system to process the pressure data generated and stored in g2) in conjunction with a computational model that includes a set of pressure curves with a number of curve-related variables and associated values in order to identify a matching pressure curve, and g4) using the data processing system to process the values of the curve-related variables for the matching pressure curve identified in g3) in order to derive properties of the given size-group of pieces. 2. A method according to claim 1 , further comprising displaying properties of the manufactured rock sample as derived in c), d) and g4) for user visualization of the combined properties of the manufactured rock sample. 3. A method according to claim 1 , wherein the bulk properties of the manufactured rock sample derived in c) and d) are selected from the group consisting of bulk volume, bulk density, porosity, permeability, grain volume, grain density, and effective density-based porosity. 4. A method according to claim 1 , wherein the computational model is based on an analytical decay function that includes three parameters α, β and τ, where the parameter α is a storage coefficient that defines the ratio of pore volume to dead volume in the sample under test, the parameter β relates to the final pressure in the sample cell when pressure inside and outside of the pore volume of the sample under test has stabilized, and parameter τ is a relaxation time. 5. A method according to claim 4 , wherein the properties of the given size-group of pieces of the manufactured rock sample derived in g4) are selected from the group consisting of bulk volume based on value of the parameter β for the matching pressure curve, porosity based on value of the parameter α for the matching pressure curve, permeability based on the parameter τ for the matching pressure curve, grain volume based on the bulk volume and the porosity, bulk density based on bulk volume, grain density based on grain volume, and effective density-based porosity based on bulk and grain density. 6. A method according to claim 1 , wherein the processing of g3) derives corrected pressure values based on the pressure data generated and stored in g2) and matches the corrected pressure values to the set of pressure curves derived from the computational model in order to identify the matching pressure curve. 7. A method according to claim 1 , wherein the pieces resulting from e) are fragments of uncontrolled shape with sizes corresponding to the radius of such fragments. 8. A method according to claim 1 , wherein the pieces resulting from e) have a controlled shape with sizes corresponding to thickness of the controlled shape. 9. A method according to claim 8 , wherein the pieces of controlled shape are slices of a core sample with varying thickness. 10. A method according to claim 1 , wherein the manufactured rock sample comprises a core sample extracted from a geologic formation. 11. A method according to claim 1 , wherein the bulk properties of the manufactured rock sample derived in c) include fabric permeability k f based on an equation of the form k f = - slope · μ gas ⁢ C gas ⁢ L f 1 ⁢ A ⁡ ( 1 V 1 + 1 V 2 ) , where μ gas is viscosity of the test fluid, C gas is compressibility of the test fluid, L is length of the sample along the direction of test fluid flow, A is the cross-sectional area of the sample perpendicular to direction of test fluid flow, V 1 and V 2 are upstream and downstream volumes, f 1 =