[1] BURWELL JR. R L. Manual of symbols and terminology for physicochemical quantities and units, appendix II: Definitions, terminology and symbols in colloid and surface chemistry［J］. Pure Appl Chem, 1976, 46(1): 71-90.

[3] POWERS T C, BROWNYARD T L. Studies of the physical properties of hardened Portland cement paste［J］. J Proc, 1946, 43(9): 469-504.

[4] FELDMAN P J, SEREDA R F. A New model for hydrated Portland cement and its practical implications［J］. Eng J (Canada), 1970, 53(8/9): 53-59.

[5] JENNINGS H M. Colloid model of C-S-H and implications to the problem of creep and shrinkage［J］. Mater Struct, 2004, 37(1): 59-70.

[6] JENNINGS H M. Refinements to colloid model of C-S-H in cement: CM-II［J］. Cem Concr Res, 2008, 38(3): 275-289.

[9] MULLER A C A. Characterization of porosity & C-S-H in cement pastes by 1H NMR［D］. Lausanne: EPFL, 2014.

[10] VALORI A, MCDONALD P J, SCRIVENER K L. The morphology of C-S-H: Lessons from 1H nuclear magnetic resonance relaxometry［J］. Cem Concr Res, 2013, 49: 65-81.

[11] LIU H, SUN Z, YANG J, et al. A novel method for semi-quantitative analysis of hydration degree of cement by 1H low-field NMR［J］. Cem Concr Res, 2021, 141: 106329.

[12] ZOU C, LONG G, ZENG X, et al. Water evolution and hydration kinetics of cement paste under steam-curing condition based on low-field NMR method［J］. Constr Build Mater, 2021, 271(15): 121583.

[13] MCDONALD P J, ISTOK O, JANOTA M, et al. Sorption, anomalous water transport and dynamic porosity in cement paste: A spatially localised 1H NMR relaxation study and a proposed mechanism［J］. Cem Concr Res, 2020, 133: 106045.

[14] WYRZYKOWSKI M, GAJEWICZ-JAROMIN A M, MCDONALD P J, et al. Water redistribution-microdiffusion in cement paste under mechanical loading evidenced by 1H NMR［J］. J Phys Chem C, 2019, 123(26): 16153-16163.

[15] REN F, ZHOU C, ZENG Q, et al. Quantifying the anomalous water absorption behavior of cement mortar in view of its physical sensitivity to water［J］. Cem Concr Res, 2021, 143: 106395.

[16] XIE E, ZHOU C, SONG Q, et al. The effect of chemical aging on water permeability of white cement mortars in the context of sol-gel science［J］. Cem Concr Compos, 2020, 114: 103812.

[17] ZHOU C, REN F, WANG Z, et al. Why permeability to water is anomalously lower than that to many other fluids for cement-based material?［J］. Cem Concr Res, 2017, 100: 373-384.

[19] YANG J, SNOECK D, DE BELIE N, et al. Comparison of liquid absorption-release of superabsorbent polymers in alkali-activated slag and Portland cement systems: An NMR study combined with additional methods［J］. Cem Concr Res, 2021, 142: 106369.

[21] WANG Y, YANG W, GE Y, et al. Analysis of freeze-thaw damage and pore structure deterioration of mortar by low-field NMR［J］. Constr Build Mater, 2022, 319: 126097.

[22] BLMICH B. Low-field and benchtop NMR［J］. J Magn Reson, 2019, 306: 27-35.

[23] NAGEL S M, STRANGFELD C, KRUSCHWITZ S. Application of 1H proton NMR relaxometry to building materials - A review［J］. J Magn Reson, 2021(6/7): 100012.

[24] MCDONALD P J, GAJEWICZ A M, MORRELL R. The characterisation of cement based materials using T2 1H nuclear magnetic resonance relaxation analysis.［EB/OL］. (2017-03)

[25] JANSEN D, ECTORS D, KONG X, et al. Synchronous monitoring of cement hydration and polymer film formation using 1H-time-domain- NMR with T2 time-weighted T1 time evaluation: A nondestructive practicable benchtop method［J］. ACS Omega, 2021, 6(11): 7499-7511.

[26] ARDELEAN I. Field-cycling NMR Relaxometry.［M］ Cambridge: Royal Society of Chemistry, 2018: 462-489.

[27] BARBERON F, KORB J P, PETIT D, et al. Probing the surface area of a cement-based material by nuclear magnetic relaxation dispersion［J］. Phy Rev Let, 2003, 90(11): 116103.

[28] BROWNSTEIN K R, TARR C E. Spin-lattice relaxation in a system governed by diffusion［J］. J Magn Reson, 1977, 26(1): 17-24.

[29] BROWNSTEIN K R, TARR C E. Importance of classical diffusion in NMR studies of water in biological cells［J］. Phy Rev A, 1979, 19(6): 2446-2453.

[30] COHEN M H, MENDELSON K S. Nuclear magnetic relaxation and the internal geometry of sedimentary rocks［J］. J App Phy, 1982, 53(2): 1127-1135.

[31] HALPERIN W P, JEHNG J Y, SONG Y Q. Application of spin-spin relaxation to measurement of surface area and pore size distributions in a hydrating cement paste［J］. Magn Reson Imag, 1994, 12(2): 169-173.

[32] BHATTACHARJA S, MOUKWA M, D’ORAZIO F, et al. Microstructure determination of cement pastes by NMR and conventional techniques［J］. Adv Cem Based Mater, 1993, 1(2): 67-76.

[33] MENDELSON K S, HALPERIN W P, JEHNG J Y, et al. Surface magnetic relaxation in cement pastes［J］. Magn Reson Imag, 1994, 12(2): 207-208.

[34] SONG Y Q. Magnetic Resonance of Porous Media (MRPM): A perspective［J］. J Magn Reson, 2013, 229: 12-24.

[36] GODEFROY S, KORB J P, FLEURY M, et al. Surface nuclear magnetic relaxation and dynamics of water and oil in macroporous media［J］. Phy Rev E, 2001, 64(2): 021605.

[37] TARCZON J C, BHATTACHARJA S, D’ORAZIO F, et al. Magnetic Resonance Relaxation Analysis of Porous Media［M］//KLAFTER J, DRAKE J M. Molecular Dynamics in Restricted Geometries. New York: John Wiley & Sons, 1989: 311.

[38] SONG Y Q. Magnetic Resonance of Porous Media (MRPM): A perspective［J］. J Magn Reson, 2013, 229: 12-24.

[39] KORB J P. NMR and nuclear spin relaxation of cement and concrete materials［J］. Curr Opin Colloid Inter Sci, 2009, 14(3): 192-202.

[40] KORB J P. Microstructure and texture of cementitious porous materials［J］. Magn Reson Imag, 2007, 25(4): 466-469.

[41] KORB J P, MONTEILHET L, MCDONALD P J, et al. Microstructure and texture of hydrated cement-based materials: A proton field cycling relaxometry approach［J］. Cem Concr Res, 2007, 37(3): 295-302.

[42] KORB J P. Multiscale nuclear magnetic relaxation dispersion of complex liquids in bulk and confinement［J］. Prog Nucl Mag Res Sp, 2018, 104: 12-55.

[43] MCDONALD P J, KORB J P, MITCHELL J, et al. Surface relaxation and chemical exchange in hydrating cement pastes: A two-dimensional NMR relaxation study［J］. Phy Rev E, 2005, 72(1): 011409.

[44] MCDONALD P J, MITCHELL J, MULHERON M, et al. Two-dimensional correlation relaxation studies of cement pastes［J］. Magn Reson Imaging, 2007, 25(4): 470-473.

[45] VALORI A, RODIN V, MCDONALD P J. On the interpretation of 1H 2-dimensional NMR relaxation exchange spectra in cements: Is there exchange between pores with two characteristic sizes or Fe3+ concentrations?［J］. Cem Concr Res, 2010, 40(9): 1375-1377.

[46] MONTEILHET L, KORB J P, MITCHELL J, et al. Observation of exchange of micropore water in cement pastes by two-dimensional T2-T2 nuclear magnetic resonance relaxometry［J］. Phy Rev E, 2006, 74(6): 061404.

[47] KORB J P. Nuclear magnetic relaxation of liquids in porous media［J］. New J Phy, 2011, 13(3): 035016.

[48] KORB J P, WHALEY-HODGES M, BRYANT R G. Translational diffusion of liquids at surfaces of microporous materials: Theoretical analysis of field-cycling magnetic relaxation measurements［J］. Phy Rev E, 1997, 56(2): 1934-1945.

[49] MCDONALD P J, RODIN V, VALORI A. Characterisation of intra- and inter-C-S-H gel pore water in white cement based on an analysis of NMR signal amplitudes as a function of water content［J］. Cem Concr Res, 2010, 40(12): 1656-1663.

[50] SCHULTE HOLTHAUSEN R, MCDONALD P J. On the quantification of solid phases in hydrated cement paste by 1H nuclear magnetic resonance relaxometry［J］. Cem Concr Res, 2020, 135: 106095.

[51] PETROV O V, FUR I. NMR cryoporometry: Principles, applications and potential［J］. Progress in Nuclear Magn Reson Spec, 2009, 54(2): 97-122.

[54] MITCHELL J, WEBBER J B W, STRANGE J H. Nuclear magnetic resonance cryoporometry［J］. Physics Reports, 2008, 461(1): 1-36.

[55] THOMSON W. LX. On the equilibrium of vapour at a curved surface of liquid［J］. The London, Edinburgh,Dublin Philosophical Magazine and J Sci, 1871, 42: 448-452.

[56] JACKSON C L, MCKENNA G B. The melting behavior of organic materials confined in porous solids［J］. J Chem Phy, 1990, 93(12): 9002-9011.

[57] WEBBER J B W, DORE J C, STRANGE J H, et al. Plastic ice in confined geometry: The evidence from neutron diffraction and NMR relaxation［J］. J Phy: Condens Matter, 2007, 19(41): 415117.

[58] WEBBER J. A generalisation of the thermoporisimetry Gibbs-Thomson equation for arbitrary pore geometry［J］. Magn. Reson. Imaging, 2003, 21: 428.

[59] JEHNG J Y, SPRAGUE D T, HALPERIN W P. Pore structure of hydrating cement paste by magnetic resonance relaxation analysis and freezing［J］. Magn. Reson Imaging, 1996, 14(7): 785-791.

[60] STRANGE J H, MITCHELL J, WEBBER J B W. Pore surface exploration by NMR［J］. Magn. Reson Imaging, 2003, 21(3): 221-226.

[61] VALCKENBORG R, PEL L, KOPINGA K. Combined NMR cryoporometry and relaxometry［J］. J Phy D: Appl Phy, 2002, 35: 249.

[62] GAJEWICZ A M. Characterisation of Cement Microstructure and Pore-Water Interaction by 1H Nuclear Magnetic Resonance Relaxometry［D］//Ph.D. Thesis. 2014.

[63] MULLER A C A, SCRIVENER K L, GAJEWICZ A M, et al. Densification of C-S-H Measured by 1H NMR Relaxometry［J］. J Phy Chem C, 2013, 117(1): 403-412.

[64] GAJEWICZ A M, GARTNER E, KANG K, et al. A 1H NMR relaxometry investigation of gel-pore drying shrinkage in cement pastes［J］. Cem Concr Res, 2016, 86: 12-19.

[65] CARR H Y, PURCELL E M. Effects of diffusion on free precession in nuclear magnetic resonance experiments［J］. Phy Rev, 1954, 94(3): 630-638.

[66] MEIBOOM S, GILL D. Modified spin‐echo method for measuring nuclear relaxation times［J］. Rev Sci Instr, 1958, 29(8): 688-691.

[67] POWLES J G, STRANGE J H. Zero time resolution nuclear magnetic resonance transient in solids［J］. Proc Phy Soc, 1963, 82(1): 6-15.

[68] ECTORS D, GOETZ-NEUNHOEFFER F, HERGETH W D, et al. In situ 1H-TD-NMR: Quantification and microstructure development during the early hydration of alite and OPC［J］. Cem Concr Res, 2016, 79: 366-372.

[69] RADEBE N W, RATZSCH K F, KLEIN C O, et al. Use of Combined Rheo-NMR to Investigate the Relationship Between the Molecular and Mechanical Properties of Early Cement Paste Hydration［C］// MECHTCHERINE V, KHAYAT K, SECRIERU E. Rheology and Processing of Construction Materials. Cham: Springer International Publishing, 2020: 256-265.

[70] KORB J P. NMR and nuclear spin relaxation of cement and concrete materials［J］. Curr Opin Colloid In, 2009, 14(3): 192-202.

[71] KORB J P, MCDONALD P J, MONTEILHET L, et al. Comparison of proton field-cycling relaxometry and molecular dynamics simulations for proton-water surface dynamics in cement-based materials［J］. Cem Concr Res, 2007, 37(3): 348-350.

[72] BOHRIS A J, GOERKE U, MCDONALD P J, et al. A broad line NMR and MRI study of water and water transport in Portland cement pastes［J］. Magn. Reson Imag, 1998, 16(5): 455-461.

[73] APTAKER P S, MCDONALD P J, MITCHELL J. Surface GARField: A novel one-sided NMR magnet and RF probe［J］. Magn. Reson Imag, 2007, 25(4): 548.

[74] JANSEN D, NABER Ch, ECTORS D, et al. The early hydration of OPC investigated by in-situ XRD, heat flow calorimetry, pore water analysis and 1H NMR: Learning about adsorbed ions from a complete mass balance approach［J］. Cem Concr Res, 2018, 109: 230-242.

[75] MULLER A C A, SCRIVENER K L, SKIBSTED J, et al. Influence of silica fume on the microstructure of cement pastes: New insights from 1H NMR relaxometry［J］. Cem Concr Res, 2015, 74: 116-125.

[76] JI Y, PEL L, SUN Z, et al. NMR study on the pore structure development of cement paste with bleeding during hydration［J］. J Mater Civil Eng, 2020, 32(12): 04020365.

[77] JI Y, SUN Z, YANG J, et al. NMR study on bleeding properties of the fresh cement pastes mixed with polycarboxylate (PCE) superplasticizers［J］. Constr Build Mater, 2020, 240: 117938.

[78] KAZEMI-KAMYAB H, MULLER A C A, DENARI E, et al. Kinetics of mixing-water repartition in UHPFRC paste and its effect on hydration and microstructural development［J］. Cem Concr Res, 2019, 124: 105784.

[79] BOGNER A, LINK J, BAUM M, et al. Early hydration and microstructure formation of Portland cement paste studied by oscillation rheology, isothermal calorimetry, 1H NMR relaxometry, conductance and SAXS［J］. Cem Concr Res, 2020, 130: 105977.

[80] ZHOU C, REN F, ZENG Q, et al. Pore-size resolved water vapor adsorption kinetics of white cement mortars as viewed from proton NMR relaxation［J］. Cem Concr Res, 2018, 105: 31-43.

[81] WYRZYKOWSKI M, MCDONALD P J, SCRIVENER K L, et al. Water redistribution within the microstructure of cementitious materials due to temperature changes studied with 1H NMR［J］. J Phy Chem C, 2017, 121(50): 27950-27962.

[82] RATZSCH K F, FRIEDRICH C, WILHELM M. Low-field rheo-NMR: A novel combination of NMR relaxometry with high end shear rheology［J］. J Rheol, 2017, 61(5): 905-917.

[83] MCDONALD P J, APTAKER P S, MITCHELL J, et al. A unilateral NMR magnet for sub-structure analysis in the built environment: The surface GARField［J］. J Magn Reson, 2007, 185(1): 1-11.

[84] SCHULTE HOLTHAUSEN R, RAUPACH M. Monitoring the internal swelling in cementitious mortars with single-sided 1H nuclear magnetic resonance［J］. Cem Concr Res, 2018, 111: 138-146.

[85] SCHULTE HOLTHAUSEN R, RAUPACH M. A phenomenological approach on the influence of paramagnetic iron in cement stone on 2D T1-T2 relaxation in single-sided 1H nuclear magnetic resonance［J］. Cem Concr Res, 2019, 120: 279-293.

[86] SCHULTE HOLTHAUSEN R, RAUPACH M. Influence of fresh concrete pressure on cover porosity investigated by single-sided proton nuclear magnetic resonance［J］. Maga of Concr Res, 2021, 73(1): 45-54.

[87] SONG Y Q, UTSUZAWA S, TANG Y. Low fields but high impact: Ex-situ NMR and MRI［J］. J Magn Reson, 2019, 306: 109-111.