[1] De Deene Y, Jirasek A. Uncertainty in 3D gel dosimetry[J]. Journal of Physics: Conference Series, 573, 1-10(2015).

[2] Hill R, Healthy B, Holloway L et al. Advances in kilovoltage X-ray beam dosimetry[J]. Physics in Medicine & Biology, 59, R183(2014).

[3] Taylor M L, Maeyama T, Fukunishi N et al. Radiological characteristics of charged particle interactions in the first clay-nanoparticle dichromate gel dosimeter[J]. Journal of Physics: Conference Series, 444, 012110(2013).

[4] Zhang P, Jiang L, Chen H et al. Recent advances in hydrogel-based sensors responding to ionizing radiation[J]. Gels, 8, 238(2022).

[5] Kozicki M, Jaszczak M, Maras P et al. On the development of a VIPARnd radiotherapy 3D polymer gel dosimeter[J]. Physics in Medicine and Biology, 62, 986-1008(2017).

[6] De Deene Y, Vandecasteele J. On the reliability of 3D gel dosimetry[J]. Journal of Physics: Conference Series, 444, 012015(2013).

[7] Moftah B, Basfar A A, Almousa A A et al. Novel 3D polymer gel dosimeters based on N-(3-Methoxypropyl)acrylamide (NMPAGAT) for quality assurance in radiation oncology[J]. Radiation Measurements, 135, 106372(2020).

[8] Soliman Y S, Tadros S M, Beshir W B et al. Study of Ag Nanoparticles in a Polyacrylamide Hydrogel Dosimeters by Optical Technique[J]. Gels, 8, 222(2022).

[9] Rabaeh K A, Eyadeh M M, Alshomali L S et al. Optical characterization of Fricke-methylthymol blue hydrogel dosimeter with gellan gum as physical cross-linker[J]. Journal of Radioanalytical and Nuclear Chemistry, 332, 1815-1823(2023).

[10] Wang K K, Zhang W, Qi Y M et al. Radiation-sensitive nanogel-incorporated Fricke hydrogel dosimeters with reduced diffusion rates[J]. Polymers for Advanced Technologies, 34, 539-548(2023).

[11] Xu X W, Jerca V V, Hoogenboom R. Bioinspired double network hydrogels: from covalent double network hydrogels via hybrid double network hydrogels to physical double network hydrogels[J]. Materials Horizons, 8, 1173-1188(2021).

[12] Gong J P, Katsuyama Y, Kurokawa T et al. Double-Network Hydrogels with Extremely High Mechanical Strength[J]. Advanced Materials, 15, 1155-1158(2003).

[13] Huang X X, Li J C, Luo J et al. Research progress on double-network hydrogels[J]. Materials Today Communications, 29, 102757(2021).

[14] Gong J P, Cui K P, Ye Y N et al. Phase separation behavior in tough and self-healing polyampholyte hydrogels[J]. Macromolecules, 53, 5116-5126(2020).

[15] Holloway J L, Lowman A M, Palmese G R J S M. The role of crystallization and phase separation in the formation of physically cross-linked PVA hydrogels[J]. Soft Matter, 9, 826-833(2013).

[16] Cui W, Cai Y F, Zheng Y et al. Mechanical enhancement of hydrophobically associating hydrogels by solvent-regulated phase separation[J]. Polymer, 210, 123042(2020).

[17] Gao Z J, Kong L S, Jin R N et al. Mechanical,adhesive and self-healing ionic liquid hydrogels for electrolytes and flexible strain sensors[J]. Journal of Materials Chemistry C, 8, 11119-11127(2020).

[18] Liang X T, Qu B, Li J R et al. Preparation of cellulose-based conductive hydrogels with ionic liquid[J]. Reactive and Functional Polymers, 86, 1-6(2015).

[19] He X L, Sun X Q, Meng H Y et al. Self-healing polymeric ionic liquid hydrogels with high mechanical strength and ionic conductivity[J]. Journal of Materials Science, 56, 10231-10248(2021).

[20] Alizadeh E, Sanche L. Precursors of solvated electrons in radiobiological physics and chemistry[J]. Chemical Reviews, 112, 5578-5602(2012).

[21] Pimblott S M, LaVerne J A. On the radiation chemical kinetics of the precursor to the hydrated electron[J]. Journal of Physical Chemistry A, 102, 2967-2975(1998).

[22] Mahlman H A, Schweitzer G K. Radiation-induced nitrite formation from concentrated nitrate solutions[J]. Journal of Inorganic and Nuclear Chemistry, 5, 213-218(1958).

[23] Cawse P A, Cornfield A H. The reduction of 15N-labelled nitrate to nitrite by fresh soils following treatment with gamma radiation[J]. Soil Biology and Biochemistry, 1, 267-270(1969).

[24] Miao P D, Liu Z D, Guo J et al. A novel ultrasensitive surface plasmon resonance-based nanosensor for nitrite detection[J]. RSC Advances, 9, 17698-17705(2019).

[25] Huang Y, Shi W, Zhang C et al. Spectrophotometric determination of nitrogen oxides in the air with 2-N-ethyl-5-naphthol-7-sulfonic acid[J]. Journal of Applied Spectroscopy, 84, 639-645(2017).

[26] Huang Y Y, Shi W J, Zhang C H et al. Diazo-coupling spectrophotometric determination of nitrogen oxides in the air[J]. Atmospheric Pollution Research, 7, 333-338(2016).

[27] Zhao C X, Liu J N, Li B Q et al. Multiscale construction of bifunctional electrocatalysts for long-lifespan rechargeable zinc-air batteries[J]. Advanced Functional Materials, 30, 2003619(2020).

[28] Tian Y, Wang Z H, Cao S Y et al. Connective tissue inspired elastomer-based hydrogel for artificial skin via radiation-indued penetrating polymerization[J]. Nature Communications, 15, 636(2024).

[29] Kozmér Z, Arany E, Alapi T et al. New insights regarding the impact of radical transfer and scavenger materials on the OH-initiated phototransformation of phenol[J]. Journal of Photochemistry and Photobiology A: Chemistry, 314, 125-132(2016).

[30] Fakhouri S, Hutchens S B, Crosby A J. Puncture mechanics of soft solids[J]. Soft Matter, 11, 4723-4730(2015).

[31] Dong X Y, Tian Y, Wang F Q et al. Gold-nanoparticle-enhanced radio-fluorogenic hydrogel sensor for low radiation doses in clinical radiotherapy[J]. Polymers, 14, 4841(2022).

[32] Yang F, Zhao J, Koshut W J et al. A synthetic hydrogel composite with the mechanical behavior and durability of cartilage[J]. Advanced Functional Materials, 36, 2003451(2020).