國立虎尾科技大學 |

1D Oxide Nanostructures Obtained by Sol-Gel and Hydrothermal Methods

紀錄類型:	書目-語言資料,印刷品 : Monograph/item
正題名/作者:	1D Oxide Nanostructures Obtained by Sol-Gel and Hydrothermal Methods/ by Crina Anastasescu, Susana Mihaiu, Silviu Preda, Maria Zaharescu.
作者:	Anastasescu, Crina.
其他作者:	Mihaiu, Susana.
面頁冊數:	VIII, 82 p. 29 illus., 7 illus. in color.online resource. :
Contained By:	Springer Nature eBook
標題:	Ceramics. -
電子資源:	https://doi.org/10.1007/978-3-319-32988-8
ISBN:	9783319329888

1D Oxide Nanostructures Obtained by Sol-Gel and Hydrothermal Methods
Anastasescu, Crina.

1D Oxide Nanostructures Obtained by Sol-Gel and Hydrothermal Methods[electronic resource] /by Crina Anastasescu, Susana Mihaiu, Silviu Preda, Maria Zaharescu. - 1st ed. 2016. - VIII, 82 p. 29 illus., 7 illus. in color.online resource. - SpringerBriefs in Materials,2192-1091. - SpringerBriefs in Materials,.

Introduction (general considerations on the 1 D oxide nanostructures) -- Synthesis of oxide nanotubes by sol-gel method -- Synthesis of oxide nanotubes/nanorods by hydrothermal method.

This book presents wet chemical sol-gel and hydrothermal methods for 1D oxide nanostructure preparation. These methods represent an attractive route to multifunctional nanomaterials synthesis, as they are versatile, inexpensive and, thus, appropriate for obtaining a wide range of oxide materials with tailored morphology and properties. Three specific oxides (SiO2, TiO2, ZnO) are discussed in detail in order to illustrate the principle of the sol-gel and hydrothermal preparation of 1D oxide nanostructures. Other oxides synthesized via this method are also briefly presented. Throughout the book, the correlation between the tubular structure and the physico-chemical properties of these materials is highlighted. 1D oxide nanostructures exhibit interesting optical and electrical properties, due to their confined morphology. In addition, a well-defined geometry can be associated with chemically active species. For example, the pure SiO2 nanotubes presented a slight photocatalytic activity, while the Pt-doped SiO2 tubular materials act as microreactors in catalytic reactions. In the case of titania and titanate nanotubes, large specific surface area and pore volume, ion-exchange ability, enhanced light absorption, and fast electron-transport capability have attracted significant research interest. The chemical and physical modifications (microwave assisted hydrothermal methods) discussed here improve the formation kinetics of the nanotubes. The ZnO nanorods/tubes were prepared as random particles or as large areas of small, oriented 1D ZnO nanostructures on a variety of substrates. In the latter case a sol-gel layer is deposited on the substrate prior to the hydrothermal preparation. Using appropriate dopants, coatings of ZnO nanorods with controlled electrical behavior can be obtained.

ISBN: 9783319329888

Standard No.: 10.1007/978-3-319-32988-8doiSubjects--Topical Terms:

673527
Ceramics.

LC Class. No.: TP807-823

Dewey Class. No.: 620.14

1D Oxide Nanostructures Obtained by Sol-Gel and Hydrothermal Methods
LDR:03466nam a22004095i 4500 001 982249
003 DE-He213
005 20200701041845.0
007 cr nn 008mamaa
008 201211s2016 gw | s |||| 0|eng d
020 $a 9783319329888 $9 978-3-319-32988-8
024 7 $a 10.1007/978-3-319-32988-8 $2 doi
035 $a 978-3-319-32988-8
050 4 $a TP807-823
050 4 $a TA418.9.C6
072 7 $a TDCQ $2 bicssc
072 7 $a TEC021010 $2 bisacsh
072 7 $a TDC $2 thema
082 0 4 $a 620.14 $2 23
100 1 $a Anastasescu, Crina. $4 aut $4 http://id.loc.gov/vocabulary/relators/aut $3 1112288
245 1 0 $a 1D Oxide Nanostructures Obtained by Sol-Gel and Hydrothermal Methods $h [electronic resource] / $c by Crina Anastasescu, Susana Mihaiu, Silviu Preda, Maria Zaharescu.
250 $a 1st ed. 2016.
264 1 $a Cham : $b Springer International Publishing : $b Imprint: Springer, $c 2016.
300 $a VIII, 82 p. 29 illus., 7 illus. in color. $b online resource.
336 $a text $b txt $2 rdacontent
337 $a computer $b c $2 rdamedia
338 $a online resource $b cr $2 rdacarrier
347 $a text file $b PDF $2 rda
490 1 $a SpringerBriefs in Materials, $x 2192-1091
505 0 $a Introduction (general considerations on the 1 D oxide nanostructures) -- Synthesis of oxide nanotubes by sol-gel method -- Synthesis of oxide nanotubes/nanorods by hydrothermal method.
520 $a This book presents wet chemical sol-gel and hydrothermal methods for 1D oxide nanostructure preparation. These methods represent an attractive route to multifunctional nanomaterials synthesis, as they are versatile, inexpensive and, thus, appropriate for obtaining a wide range of oxide materials with tailored morphology and properties. Three specific oxides (SiO2, TiO2, ZnO) are discussed in detail in order to illustrate the principle of the sol-gel and hydrothermal preparation of 1D oxide nanostructures. Other oxides synthesized via this method are also briefly presented. Throughout the book, the correlation between the tubular structure and the physico-chemical properties of these materials is highlighted. 1D oxide nanostructures exhibit interesting optical and electrical properties, due to their confined morphology. In addition, a well-defined geometry can be associated with chemically active species. For example, the pure SiO2 nanotubes presented a slight photocatalytic activity, while the Pt-doped SiO2 tubular materials act as microreactors in catalytic reactions. In the case of titania and titanate nanotubes, large specific surface area and pore volume, ion-exchange ability, enhanced light absorption, and fast electron-transport capability have attracted significant research interest. The chemical and physical modifications (microwave assisted hydrothermal methods) discussed here improve the formation kinetics of the nanotubes. The ZnO nanorods/tubes were prepared as random particles or as large areas of small, oriented 1D ZnO nanostructures on a variety of substrates. In the latter case a sol-gel layer is deposited on the substrate prior to the hydrothermal preparation. Using appropriate dopants, coatings of ZnO nanorods with controlled electrical behavior can be obtained.
650 0 $a Ceramics. $3 673527
650 0 $a Glass. $3 681282
650 0 $a Composites (Materials). $3 1253658
650 0 $a Composite materials. $3 561730
650 0 $a Nanochemistry. $3 596891
650 0 $a Nanoscale science. $3 1253587
650 0 $a Nanoscience. $3 632473
650 0 $a Nanostructures. $3 561754
650 0 $a Optical materials. $3 672695
650 0 $a Electronic materials. $3 1253592
650 0 $a Lasers. $3 557748
650 0 $a Photonics. $3 562392
650 0 $a Catalysis. $3 673438
650 1 4 $a Ceramics, Glass, Composites, Natural Materials. $3 1116204
650 2 4 $a Nanoscale Science and Technology. $3 783795
650 2 4 $a Optical and Electronic Materials. $3 593919
650 2 4 $a Optics, Lasers, Photonics, Optical Devices. $3 1112289
700 1 $a Mihaiu, Susana. $e author. $4 aut $4 http://id.loc.gov/vocabulary/relators/aut $3 1274397
700 1 $a Preda, Silviu. $e author. $4 aut $4 http://id.loc.gov/vocabulary/relators/aut $3 1274398
700 1 $a Zaharescu, Maria. $e author. $4 aut $4 http://id.loc.gov/vocabulary/relators/aut $3 1274399
710 2 $a SpringerLink (Online service) $3 593884
773 0 $t Springer Nature eBook
776 0 8 $i Printed edition: $z 9783319329864
776 0 8 $i Printed edition: $z 9783319329871
830 0 $a SpringerBriefs in Materials, $x 2192-1091 $3 1254986
856 4 0 $u https://doi.org/10.1007/978-3-319-32988-8
912 $a ZDB-2-CMS
912 $a ZDB-2-SXC
950 $a Chemistry and Materials Science (SpringerNature-11644)
950 $a Chemistry and Material Science (R0) (SpringerNature-43709)