[1] T LIMERO, E REESE, P CHENG et al. Preparation of a gas chromatograph-differential mobility spectrometer to measure target volatile organic compounds on the international space station. International Journal for Ion Mobility Spectrometry, 81(2011).

[2] N S ABRAHAM, M M HASEGAWA, M S SECUNDA. Application of the molecular adsorber coating technology on the Ionospheric Connection Explorer Program. Proceedings of SPIE(2016).

[3] T LIMERO, E REESE, W T WALLACE et al. Results from the air quality monitor (gas chromatograph-differential mobility spectrometer) experiment on board the international space station. International Journal for Ion Mobility Spectrometry, 189(2012).

[4] J T SANDERS. Molecular contamination of an EUV instrument in geosynchronous orbit. Proceedings of SPIE, 5526: 44(2004).

[5] J S CANHAM. Revisiting mechanisms of molecular contamination induced laser optic damage. Proceedings of SPIE(2007).

[6] C W CHANG, K KANNENBERG, M H CHIDESTER. Development of versatile molecular transport model for modeling spacecraft contamination. Proceedings of SPIE(2010).

[7] S S GUO, W D AI, J X FEI et al. Study on the kinetic characteristics of trace harmful gases for a two-person-30-day integrated CELSS test. Environmental Science and Pollution Research, 7020(2015).

[8] V SNITKA, D BATIUSKAITE, I BRUZAITE et al. Surface- enhanced Raman scattering sensors for biomedical and molecular detection applications in space. CEAS Space Journal, 509(2021).

[9] N SHIMOSAKO, T EGASHIRA, K YOSHINO et al. Effects of vacuum on photocatalytic activity of TiO₂. Proceedings of SPIE, 10748: 1074810(2018).

[10] N SHIMOSAKO, K YOSHINO, K SHIMAZAKI et al. Tolerance to electron beams of TiO₂ film photocatalyst. Thin Solid Films, 686: 137421(2019).

[11] M DIBOUNE, H NOUALI, M SOULARD et al. Green hybrid zeolite coatings for on-orbit molecular decontamination. Microporous and Mesoporous Materials, 307: 110478(2020).

[12] N SHIMOSAKO, H SAKAMA. Influence of vacuum environment on photocatalytic degradation of methyl red by TiO₂ thin film. Acta Astronaut, 178: 693(2021).

[13] A H FENG, Y YU, L MI et al. Synthesis and VOCs adsorption performance of surfactant-templated USY zeolites with controllable mesopores. Chemical Physics Letters, 798: 139578(2022).

[14] N S ABRAHAM, D E JALLICE. Preliminary testing of NASA's molecular adsorber coating technology for future missions to Mars. Proceedings of SPIE(2018).

[15] S STRAKA, W PETERS, M HASEGAWA et al(2010).

[16] H Y CHEN, H X XI, X Y CAI et al. Experimental and molecular simulation studies of a ZSM-5-MCM-41 micro-mesoporous molecular sieve. Microporous and Mesoporous Materials, 396(2009).

[17] H MORADI, H AZIZPOUR, H BAHMANYAR et al. Effect of Si/Al ratio in the faujasite structure on adsorption of methane and nitrogen: a molecular dynamics study. Chemical Engineering & Technology, 1221(2021).

[18] J QIAO, S S YANG, J J LI et al. Dynamic simulation of deposition processes of spacecraft molecular contamination. Tehnicki Vjesnik- Technical Gazette, 321(2021).

[19] M Y WANG, Y SHENG. Molecular simulation to analyze the influence of ultrafine particles on activated carbon adsorbing low concentration toluene. Building and Environment, 213: 108875(2022).

[20] F ZHAO, X S SUN, R F LU et al. Adsorption of methanol, methanal, toluene, ethylbenzene, and styrene in zeolites: a grand canonical Monte Carlo simulation study. Canadian Journal of Chemistry, 1241(2017).

[21] H MORADI, H AZIZPOUR, H BAHMANYAR et al. Molecular dynamic simulation of carbon dioxide, methane, and nitrogen adsorption on Faujasite zeolite. Chinese Journal of Chemical Engineering, 43: 70(2022).

[22] G MAURIN, Y BELMABKHOUT, G PIRNGRUBER et al. CO₂ adsorption in LiY and NaY at high temperature: molecular simulations compared to experiments. Adsorption-Journal of the International Adsorption Society, 453(2007).

[23] F PORCHER, J L PAILLAUD, L GABEROVA et al. Monitoring by in situ neutron diffraction of simultaneous dehydration and Ni²⁺ mobility in partially exchanged NaY zeolites. New Journal of Chemistry, 4228(2016).

[24] T AMMOULI, J L PAILLAUD, H NOUALI et al. Insights into water adsorption in potassium-exchanged X-type faujasite zeolite: molecular simulation and experiment. The Journal of Physical Chemistry C, 19405(2021).

[25] P XIONG, P HE, Y X QU et al. The adsorption properties of NaY zeolite for separation of ethylene glycol and 1, 2-butanediol: experiment and molecular modelling. Green Energy & Environment, 102(2021).

[26] L Q SONG, X S DU, Y R CHEN et al. Screening of zeolites for H₂S adsorption in mixed gases: GCMC and DFT simulations. Microporous and Mesoporous Materials, 328: 111495(2021).

[27] B VUJIC, A P LYUBARTSEV. Transferable force-field for modelling of CO₂, N₂, O₂ and Ar in all silica and Na⁺ exchanged zeolites. Modelling and Simulation in Materials Science and Engineering, 045002(2016).

[28] H Y CHEN, W L WANG, J DING et al. CO₂ adsorption capacity of FAU zeolites in presence of H₂O: a Monte Carlo simulation study. Energy Procedia, 105: 4370(2017).

[29] S Y HOU, Y L TANG, T L ZHU et al. Adsorptive removal of gas phase naphthalene on ordered mesoporous carbon. Journal of Hazardous Materials, 436: 129208(2022).

[30] M RAHMATI, H MODARRESS. Selectivity of new siliceous zeolites for separation of methane and carbon dioxide by Monte Carlo simulation. Microporous and Mesoporous Materials, 176: 168(2013).

[31] Z KEYVANLOO, A N POUR, F MOOSAVI et al. Molecular dynamic simulation studies of adsorption and diffusion behaviors of methanol and ethanol through ZSM-5 zeolite. Journal of Molecular Graphics & Modelling, 110: 108048(2022).

[32] A FENG, Y YU, L MI et al. Synthesis and characterization of hierarchical Y zeolites using NH₄HF₂ as dealumination agent. Microporous and Mesoporous Materials, 280: 211(2019).

[33] A FENG, Y YU, L MI et al. Structural, textural and toluene adsorption properties of NH₄HF₂ and alkali modified USY zeolite. Microporous and Mesoporous Materials, 290: 109646(2019).

[34] R YOSHIMOTO, K HARA, K OKUMURA et al. Analysis of toluene adsorption on Na-form zeolite with a temperature-programmed desorption method. The Journal of Physical Chemistry C, 1474(2007).

[35] E P HESSOU, L A BEDE, H JABRAOUI et al. Adsorption of toluene and water over cationic-exchanged Y zeolites: a DFT exploration. Molecules, 5486(2021).

[36] H M ZHENG, L ZHAO, J J JI et al. Unraveling the adsorption mechanism of mono- and diaromatics in faujasite zeolite. ACS Applied Materials & Interfaces, 10190(2015).

[37] C C BRUNCHI, J M C SANCHEZ, A I STANKIEWICZ et al. Adsorption of volatile organic compounds. experimental and theoretical study. Industrial & Engineering Chemistry Research, 16697(2012).