Breakthrough to non-vacuum deposition of single-crystal, ultra-thin, homogeneous nanoparticle layers: A better alternative to chemical bath deposition and atomic layer deposition

Liao, Y.-K.Y.-K.LiaoLiu, Y.-T.Y.-T.LiuHsieh, D.-H.D.-H.HsiehShen, T.-L.T.-L.ShenHsieh, M.-Y.M.-Y.HsiehTzou, A.-J.A.-J.TzouChen, S.-C.S.-C.ChenTsai, Y.-L.Y.-L.TsaiLin, W.-S.W.-S.LinChan, S.-W.S.-W.ChanShen, Y.-P.Y.-P.ShenCheng, S.-J.S.-J.ChengChen, C.-H.C.-H.ChenWu, K.-H.K.-H.WuChen, H.-M.H.-M.ChenKuo, S.-Y.S.-Y.KuoCharlton, M.D.B.M.D.B.CharltonHsieh, T.-P.T.-P.HsiehKuo, H.-C.H.-C.Kuo2019-05-132019-05-132017https://scholars.lib.ntu.edu.tw/handle/123456789/407523[SDGs]SDG7Breakthrough to non-vacuum deposition of single-crystal, ultra-thin, homogeneous nanoparticle layers: A better alternative to chemical bath deposition and atomic layer depositionjournal article10.3390/nano70400782-s2.0-85018509744WOS:000404048100007