?url_ver=Z39.88-2004&rft_id=10.5204%2Fthesis.eprints.119163&rft_val_fmt=info%3Aofi%2Ffmt%3Akev%3Amtx%3Adc&rft.title=Nickel+based+nanomaterials+for+renewable+energy+conversion+and+storage+application&rft.creator=Wang%2C+Teng&rft.subject=Supercapacitor&rft.subject=layered+double+hydroxide&rft.subject=oxygen+evolution+reaction&rft.subject=barium+nickel+phosphate&rft.subject=metal+oxides&rft.subject=NiCo+LDH&rft.subject=battery+type+materials&rft.description=This+research+focuses+on+the+synthesis+and+development+of+new+functional+nanomaterials+with+tailored+morphology+for+high+performance+supercapacitors+and+hydrogen+generation+through+electrolysis+of+water+splitting+in+order+to+alleviate+the+energy+crisis+and+environmental+problems.+A+series+of+nickel+based+nanomaterials+have+been+synthesized+and+their+electrochemical+properties+were+thoroughly+studied.+Ultrafine+amorphous+barium+nickel+phosphate+nanofibers%2C+and+Ni-Co+and+NiCu+layered+double+hydroxide+(LDH)+nanosheet+arrays+directly+grown+on+carbon+fibre+clothes+(CFC)+demonstrated+excellent+performance+for+supercapacitors+while+NiCoFe+LDH+nanosheet+arrays+on+CFC+showed+high+catalytic+activity+for+oxygen+evolution+reaction+for+water+splitting.&rft.publisher=Queensland+University+of+Technology&rft.date=2018&rft.type=Thesis&rft.format=application%2Fpdf&rft.relation=https%3A%2F%2Feprints.qut.edu.au%2F119163%2F8%2FTeng_Wang_Thesis.pdf&rft.rights=free_to_read&rft.relation=doi%3A10.5204%2Fthesis.eprints.119163&rft.relation=Wang%2C+Teng+(2018)+Nickel+based+nanomaterials+for+renewable+energy+conversion+and+storage+application.+PhD+by+Publication%2C+Queensland+University+of+Technology.&rft.id_number=https%3A%2F%2Feprints.qut.edu.au%2F119163%2F&rft.identifier=Science+%26+Engineering+Faculty%3B+School+of+Chemistry%2C+Physics+%26+Mechanical+Engineering