References

  1. N. Ghaffour, T.M. Missimer, G.L. Amy, Technical review and evaluation of the economics of water desalination: current and future challenges for better water supply sustainability, Desalination, 309 (2013) 197–207.
  2. S. Shoeibi, N. Rahbar, A.A. Esfahlani, H. Kargarsharifabad, A comprehensive review of enviro-exergo-economic analysis of solar stills, Renewable Sustainable Energy Rev., 149 (2021) 111404, doi: 10.1016/j.rser.2021.111404.
  3. N.M. Shatar, M.F.M. Salleh, M.H. Ani, M.F.M. Sabri, Mix wettability surface on solar still cover for freshwater productivity enhancement, Desalination, 534 (2022) 115797, doi: 10.1016/j.desal.2022.115797.
  4. A. Dubey, S.K. Singh, S.K. Tyagi, Advances in design and performance of dual slope solar still: a review, Sol. Energy, 244 (2022) 189–217.
  5. A.F. Muftah, M.A. Alghoul, A. Fudholi, M.M. Abdul-Majeed, K. Sopian, Factors affecting basin type solar still productivity: a detailed review, Renewable Sustainable Energy Rev., 32 (2014) 430–447.
  6. P. Prakash, V. Velmurugan, Parameters influencing the productivity of solar stills – a review, Renewable Sustainable Energy Rev., 49 (2015) 585–609.
  7. K. Selvaraj, A. Natarajan, Factors influencing the performance and productivity of solar stills - a review, Desalination, 435 (2018) 181–187.
  8. S.W. Sharshir, N. Yang, G. Peng, A.E. Kabeel, Factors affecting solar stills productivity and improvement techniques: a detailed review, Appl. Therm. Eng., 100 (2016) 267–284.
  9. A. Muthu Manokar, K. Kalidasa Murugavel, G. Esakkimuthu, Different parameters affecting the rate of evaporation and condensation on passive solar still – a review, Renewable Sustainable Energy Rev., 38 (2014) 309–322.
  10. S.K. Singh, S.C. Kaushik, V.V. Tyagi, S.K. Tyagi, Comparative performance and parametric study of solar still: a review, Sustainable Energy Technol. Assess., 47 (2021) 101541, doi: 10.1016/j.seta.2021.101541.
  11. A. Dubey, S.K. Singh, S.K. Tyagi, Advances in design and performance of dual slope solar still: a review, Sol. Energy, 244 (2022) 189–217.
  12. M. Mohsenzadeh, L. Aye, P. Christopher, A review on various designs for performance improvement of passive solar stills for remote areas, Sol. Energy, 228 (2021) 594–611.
  13. S.J.P. Gnanaraj, S. Ramachandran, Identification of operational parameter levels that optimize the production in solar stills with plain, corrugated, and compartmental basin, Environ. Sci. Pollut. Res., 29 (2022) 7096–7116.
  14. W. Abdelmaksoud, M. Almaghrabi, M. Alruwaili, A. Alruwaili, Improving water productivity in active solar still, Desal. Water Treat., 43 (2021) 2774–2787.
  15. S.A. Mohiuddin, A.K. Kaviti, T.S. Rao, V.S. Sikarwar, Historic review and recent progress in internal design modification in solar stills, Environ. Sci. Pollut. Res., 29 (2022) 38825–38878.
  16. M.S.S. Abujazar, S. Fatihah, A.R. Rakmi, M.Z. Shahrom, The effects of design parameters on productivity performance of a solar still for seawater desalination: a review, Desalination, 385 (2016) 178–193.
  17. S. Shoeibi, N. Rahbar, A.A. Esfahlani, H. Kargarsharifabad, A review of techniques for simultaneous enhancement of evaporation and condensation rates in solar stills, Sol. Energy, 225 (2021) 666–693.
  18. S. Shoeibi, M. Saemian, H. Kargarsharifabad, S. Hosseinzade, N. Rahbar, M. Khiadani, M.M. Rashidi, A review on evaporation improvement of solar still desalination using porous material, Int. Commun. Heat Mass Transfer, 138 (2022) 106387, doi: 10.1016/j.icheatmasstransfer.2022.106387.
  19. A. Iqbal, M.S. Mahmoud, E.T. Sayed, K. Elsaid, M.A. Abdelkareem, H. Alawadhi, A.G. Olabi, Evaluation of the nanofluid-assisted desalination through solar stills in the last decade, J. Environ. Manage., 277 (2021) 111415, doi: 10.1016/j.jenvman.2020.111415.
  20. G. Peng, S.W. Sharshir, Y. Wang, M. An, D. Ma, J. Zang, A.E. Kabeel, N. Yang, Potential and challenges of improving solar still by micro/nano-particles and porous materials - a review, J. Cleaner Prod., 311 (2021) 127432, doi: 10.1016/j.jclepro.2021.127432.
  21. T. Chekifi, M. Boukraa, Solar still productivity improvement using nanofluids: a comprehensive review, Desal. Water Treat., 44 (2023) 1396–1416.
  22. A.S. Abdullah, F.A. Essa, Z.M. Omara, Effect of different wick materials on solar still performance – a review, Desal. Water Treat., 42 (2021) 1055–1082.
  23. S.K. Suraparaju, S.K. Natarajan, Performance analysis of single slope solar desalination setup with natural fiber, Desal. Water Treat., 193 (2020) 64–71.
  24. M. Asbik, H. Boushaba, H. Hafs, A. Koukouch, A. Sabri, A. Muthu Manokar, Investigating the effect of sensible and latent heat storage materials on the performance of a single basin solar still during winter days, J. Energy Storage, 44 (2021) 103480, doi: 10.1016/j.est.2021.103480.
  25. K.J. Khatod, V.P. Katekar, S.S. Deshmukh, An evaluation for the optimal sensible heat storage material for maximizing solar still productivity: a state-of-the-art review, J. Energy Storage, 20 (2022) 104622, doi: 10.1016/j.est.2022.104622.
  26. A.M. lafta, K.E. Amori, Hydrogel materials as absorber for improving water evaporation with solar still, desalination and wastewater treatment, Mater. Today Proc., 60 (2022) 1548–1553.
  27. M.H. Sharbatiyan, S. Rashidi, M. Mirhosseini, Experimental study on the performance of floating solar desalination system with porous absorbent plate, J. Taiwan Inst. Chem. Eng., 148 (2023) 104677, doi: 10.1016/j.jtice.2023.104677.
  28. M.R. Diab, F.A. Essa, F.S. Abou-Taleb, Z.M. Omara, Solar still with rotating parts: a review, Environ. Sci. Pollut. Res., 28 (2021) 54260–54281.
  29. Z. Haddad, A. Chaker, A. Rahmani, Improving the basin type solar still performances using a vertical rotating wick, Desalination, 418 (2017) 71–78.
  30. Z.M. Omara, A.S. Abdullah, T. Dakrory, Improving the productivity of solar still by using water fan and wind turbine, Sol. Energy, 147 (2017) 181–188.
  31. M. Younis, C. Habchi, M.N. Ahmad, K. Ghali, Optimization of the performance of a solar still assisted by a rotating drum with a rough surface, Sol. Energy, 211 (2020) 847–865.
  32. M.A. Eltawil, Z. Zhengming, Wind turbine-inclined still collector integration with solar still for brackish water desalination, Desalination, 249 (2009) 490–497.
  33. B. Darbari, S. Rashidi, Performance analysis for single slope solar still enhanced with multi-shaped floating porous absorber, Sustainable Energy Technol. Assess., 50 (2022) 101854, doi: 10.1016/j.seta.2021.101854.
  34. A.K. Rajasekaran, K.M. Kulandaivelu, Performance comparison of solar still with inbuilt condenser and agitator over conventional solar still with energy and exergy analysis, Environ. Sci. Pollut. Res., 29 (2022) 83378–83388.
  35. S.K. Patel, K.V. Modi, Techniques to improve the performance of enhanced condensation area solar still: a critical review, J. Cleaner Prod., 268 (2020) 122260, doi: 10.1016/j. jclepro.2020.122260.
  36. N.M. Shatar, M.F.M. Salleh, M.H. Ani, M.F.M. Sabri, Mix wettability surface on solar still cover for freshwater productivity enhancement, Desalination, 534 (2022) 115797, doi: 10.1016/j.desal.2022.115797.
  37. H. Amiri, Enhancing the stepped solar still performance using a built-in passive condenser, Sol. Energy, 248 (2022) 88–102.
  38. A.S. Abdullah, F.A. Essa, Z.M. Omara, Y. Rashid, L. Hadj- Taieb, G.B. Abdelaziz, A.E. Kabeel, Rotating-drum solar still with enhanced evaporation and condensation techniques: comprehensive study, Energy Convers. Manage., 199 (2019) 112024, doi: 10.1016/j.enconman.2019.112024.
  39. K. Rabhi, R. Nciri, F. Nasri, C. Ali, H.B. Bacha, Experimental performance analysis of a modified single-basin single-slope solar still with pin fins absorber and condenser, Desalination, 416 (2017) 86–93.
  40. S. Nazari, H. Safarzadeh, M. Bahiraei, Performance improvement of a single slope solar still by employing thermoelectric cooling channel and copper oxide nanofluid: an experimental study, J. Cleaner Prod., 208 (2019) 1041–1052.
  41. G. Sadeghi, S. Nazari, Retrofitting a thermoelectric-based solar still integrated with an evacuated tube collector utilizing an antibacterial-magnetic hybrid nanofluid, Desalination, 500 (2021) 114871, doi: 10.1016/j.desal.2020.114871.
  42. R. Sathyamurthy, S.A. El-Agouz, V. Dharmaraj, Experimental analysis of a portable solar still with evaporation and condensation chambers, Desalination, 367 (2015) 180–185.
  43. S.S.A. Toosi, H.R. Goshayeshi, S.Z. Heris, Experimental investigation of stepped solar still with phase change material and external condenser, J. Energy Storage, 40 (2021) 102681, doi: 10.1016/j.est.2021.102681.
  44. R. Arun Kumar, G. Esakkimuthu, K. Kalidasa Murugavel, Performance enhancement of a single basin single slope solar still using agitation effect and external condenser, Desalination, 399 (2016) 198–202.
  45. A. Wesley Jeevadason, S. Padmini, C. Bharatiraja, A.E. Kabeel, A review on diverse combinations and energy-exergyeconomics (3E) of hybrid solar still desalination, Desalination, 527 (2022) 115587, doi: 10.1016/j.desal.2022.115587.
  46. M.S. Yousef, H. Hassan, M. Ahmed, S. Ookawara, Energy and exergy analysis of single slope passive solar still under Egyptian climate conditions, Energy Procedia, 141 (2017) 18–23.
  47. S.W. Sharshir, M.A. Eltawil, A.M. Algazzar, R. Sathyamurthy, A.W. Kandeal, Performance enhancement of stepped double slope solar still by using nanoparticles and linen wicks: energy, exergy and economic analysis, Appl. Therm. Eng., 174 (2020) 115278, doi: 10.1016/j.applthermaleng.2020.115278.
  48. E.F. El-Gazar, W.K. Zahra, H. Hassan, S.I. Rabia, Fractional modeling for enhancing the thermal performance of conventional solar still using hybrid nanofluid: energy and exergy analysis, Desalination, 503 (2021) 114847, doi: 10.1016/j. desal.2020.114847.
  49. P. Dumka, D.R. Mishra, Energy and exergy analysis of conventional and modified solar still integrated with sand bed earth: study of heat and mass transfer, Desalination, 437 (2018) 15–25.
  50. P. Dumka, A. Jain, D.R. Mishra, Energy, exergy, and economic analysis of single slope conventional solar still augmented with an ultrasonic fogger and a cotton cloth, J. Energy Storage, 30 (2020) 101541, doi: 10.1016/j.est.2020.101541.
  51. M. Jafaripour, F.A. Roghabadi, S. Soleimanpour, S.M. Sadrameli, Barriers to implementation of phase change materials within solar desalination units: exergy, thermal conductivity, economic, and environmental aspects review, Desalination, 546 (2023) 116191, doi: 10.1016/j.desal.2022.116191.
  52. N. Rahbar, A. Gharaiian, S. Rashidi, Exergy and economic analysis for a double slope solar still equipped by thermoelectric heating modules - an experimental investigation, Desalination, 420 (2017) 106–113.
  53. Y.S. Prasanna, S.S. Deshmukh, Energy, exergy and economic analysis of an air cavity appended passive solar still of different basin material at varying depth, Energy Sustainable Dev., 71 (2022) 13–26.
  54. T. Rajaseenivasan, K. Srithar, Performance investigation on solar still with circular and square fins in basin with CO2 mitigation and economic analysis, Desalination, 380 (2016) 66–74.
  55. S. Vaithilingam, G.S. Esakkimuthu, Energy and exergy analysis of single slope passive solar still: an experimental investigation, Desal. Water Treat., 55 (2015) 1433–1444.
  56. S. Vaithilingam, V. Muthu, M.M. Athikesavan, A. Afzal, R. Sathyamurthy, Energy and exergy analysis of conventional acrylic solar still with and without copper fins, Environ. Sci. Pollut. Res., 29 (2022) 6194–6204.
  57. H. Sharon, Energy, exergy, environmental benefits and economic aspects of novel hybrid solar still for sustainable water distillation, Process Saf. Environ. Prot., 150 (2021) 1–21.
  58. P. Dumka, Y. Kushwah, A. Sharma, D.R. Mishra, Comparative analysis and experimental evaluation of single slope solar still augmented with permanent magnets and conventional solar still, Desalination, 459 (2019) 34–45.
  59. S.S. Tuly, M.S. Islam, R. Hassan, B.K. Das, M.R.I. Sarker, Investigation of a modified double slope solar still integrated with nanoparticle-mixed phase change materials: energy, exergy, exergo-economic, environmental, and sustainability analyses, Case Stud. Therm. Eng., 37 (2022) 102256, doi: 10.1016/j.csite.2022.102256.
  60. K. Rabishokr, R. Daghigh, A portable solar still’s productivity boost combining a magnetic stirrer and thermoelectric, Desalination, 549 (2023) 116340, doi: 10.1016/j.desal.2022.116340.
  61. A. Rahmani, F. Khemmar, Z. Saadi, Experimental investigation on the negative effect of the external condenser on the conventional solar still performance, Desalination, 501 (2021) 114914, doi: 10.1016/j.desal.2020.114914.