{"_id":"67Znzc67F9EX6ByuB","bibbaseid":"geng-duan-grismer-zhao-bohn-catalystandprocessingeffectsonmetalassistedchemicaletchingfortheproductionofhighlyporousgan-2013","author_short":["Geng, X.","Duan, B. K.","Grismer, D. A.","Zhao, L.","Bohn, P. W."],"bibdata":{"bibtype":"article","type":"article","title":"Catalyst and processing effects on metal-assisted chemical etching for the production of highly porous GaN","volume":"28","issn":"02681242","doi":"10.1088/0268-1242/28/6/065001","abstract":"Metal-assisted chemical etching is a facile method to produce micro-/nanostructures in the near-surface region of gallium nitride (GaN) and other semiconductors. Detailed studies of the production of porous GaN (PGaN) using different metal catalysts and GaN doping conditions have been performed in order to understand the mechanism by which metal-assisted chemical etching is accomplished in GaN. Patterned catalysts show increasing metal-assisted chemical etching activity to n-GaN in the order Ag \\textless Au \\textless Ir \\textless Pt. In addition, the catalytic behavior of continuous films is compared to discontinuous island films. Continuous metal films strongly shield the surface, hindering metal-assisted chemical etching, an effect which can be overcome by using discontinuous films or increasing the irradiance of the light source. With increasing etch time or irradiance, PGaN morphologies change from uniform porous structures to ridge and valley structures. The doping type plays an important role, with metal-assisted chemical etching activity increasing in the order p-GaN \\textless intrinsic GaN \\textless n-GaN. Both the catalyst identity and the doping type effects are explained by the work functions and the related band offsets that affect the metal-assisted chemical etching process through a combination of different barriers to hole injection and the formation of hole accumulation/depletion layers at the metal-semiconductor interface. © 2013 IOP Publishing Ltd.","number":"6","journal":"Semiconductor Science and Technology","author":[{"propositions":[],"lastnames":["Geng"],"firstnames":["Xuewen"],"suffixes":[]},{"propositions":[],"lastnames":["Duan"],"firstnames":["Barrett","K."],"suffixes":[]},{"propositions":[],"lastnames":["Grismer"],"firstnames":["Dane","A."],"suffixes":[]},{"propositions":[],"lastnames":["Zhao"],"firstnames":["Liancheng"],"suffixes":[]},{"propositions":[],"lastnames":["Bohn"],"firstnames":["Paul","W."],"suffixes":[]}],"year":"2013","bibtex":"@article{geng_catalyst_2013,\n\ttitle = {Catalyst and processing effects on metal-assisted chemical etching for the production of highly porous {GaN}},\n\tvolume = {28},\n\tissn = {02681242},\n\tdoi = {10.1088/0268-1242/28/6/065001},\n\tabstract = {Metal-assisted chemical etching is a facile method to produce micro-/nanostructures in the near-surface region of gallium nitride (GaN) and other semiconductors. Detailed studies of the production of porous GaN (PGaN) using different metal catalysts and GaN doping conditions have been performed in order to understand the mechanism by which metal-assisted chemical etching is accomplished in GaN. Patterned catalysts show increasing metal-assisted chemical etching activity to n-GaN in the order Ag {\\textless} Au {\\textless} Ir {\\textless} Pt. In addition, the catalytic behavior of continuous films is compared to discontinuous island films. Continuous metal films strongly shield the surface, hindering metal-assisted chemical etching, an effect which can be overcome by using discontinuous films or increasing the irradiance of the light source. With increasing etch time or irradiance, PGaN morphologies change from uniform porous structures to ridge and valley structures. The doping type plays an important role, with metal-assisted chemical etching activity increasing in the order p-GaN {\\textless} intrinsic GaN {\\textless} n-GaN. Both the catalyst identity and the doping type effects are explained by the work functions and the related band offsets that affect the metal-assisted chemical etching process through a combination of different barriers to hole injection and the formation of hole accumulation/depletion layers at the metal-semiconductor interface. © 2013 IOP Publishing Ltd.},\n\tnumber = {6},\n\tjournal = {Semiconductor Science and Technology},\n\tauthor = {Geng, Xuewen and Duan, Barrett K. and Grismer, Dane A. and Zhao, Liancheng and Bohn, Paul W.},\n\tyear = {2013},\n}\n\n","author_short":["Geng, X.","Duan, B. K.","Grismer, D. A.","Zhao, L.","Bohn, P. W."],"key":"geng_catalyst_2013","id":"geng_catalyst_2013","bibbaseid":"geng-duan-grismer-zhao-bohn-catalystandprocessingeffectsonmetalassistedchemicaletchingfortheproductionofhighlyporousgan-2013","role":"author","urls":{},"metadata":{"authorlinks":{}}},"bibtype":"article","biburl":"https://api.zotero.org/groups/5446813/items?key=O5SyRPuvYGCamuqNXm82OgG4&format=bibtex&limit=100","dataSources":["JLgW58tWv37BMqmko","74aQfjv6gMLQcjo4z"],"keywords":[],"search_terms":["catalyst","processing","effects","metal","assisted","chemical","etching","production","highly","porous","gan","geng","duan","grismer","zhao","bohn"],"title":"Catalyst and processing effects on metal-assisted chemical etching for the production of highly porous GaN","year":2013}