Synthesis and characterizations of triethanolamine-copper black titanium photocatalyst for carbon dioxide photoreduction

Name: Poomipat Chotngamkham

Organization : Mahidol University. Faculty of Engineering

Name: Kongphoom Khumsupa

Organization : Mahidol University. Faculty of Engineering

Name: Somchate Wasantwisut

Organization : Mahidol University. Faculty of Engineering

Name: Poomiwat Phadungbut

Organization : Mahidol University. Faculty of Engineering

Name: Woranart Jonglertjunya

Organization : Mahidol University. Faculty of Engineering

Email : woranart.jon@mahidol.edu

Name: Sira Srinives

Organization : Mahidol University. Faculty of Engineering

keyword: Triethanolamine

LCSH: Photocatalysis

LCSH: Carbon dioxide

LCSH: Copper compounds

LCSH: Titanium dioxide

LCSH: Nanocomposites (Materials)

Abstract: CO2 emission is a leading cause of global warming and has become a prime public concern in recent years. Various methods were explored for CO2 capture and storage (CCS), including amine scrubbers, solid adsorbents, and underground CO2 storage, hoping to mitigate the emission incident. An emerging and promising alternative is CO2 photoreduction, the artificial leaf, which employs photocatalysts to convert CO2 into valuable products such as methane, acetaldehyde, and methanol. Titanium dioxide (TiO2) is a notable photocatalyst in surface coating and wastewater treatment industries. In this regard, commercial-grade Degussa P25 TiO2 was studied for its ability to convert CO2 into high-value substances with limited photoactivity due to rapid electron-hole recombination and restricted light absorption. In this study, the P25 TiO2 was transformed to black titanium (BT), dope with copper, and functionalized with triethanolamine (TEA). BT is an amorphous phase of TiO2 with oxygen vacancy and Ti3+ active species, while copper decelerates the electron-hole recombination rate. TEA is a tertiary alkanolamine that can capture CO2 and release CO2 to the photocatalyst. Combining BT, copper, and TEA creates TEA-Cu-BT, providing excellent photoactivity for CO2 photoreduction. Our best result showed TEA-Cu-BT converting CO2 to target products in both gas and liquid phases, including methane, acetaldehyde, ethanol, and acetone, at a total carbon consumption of 5,760 μmol/gCAT

Address: BANGKOK

Email: library@kmutnb.ac.th

Created: 2025

Modified: 2025-07-21

Issued: 2568-07-21

บทความ/Article

application/pdf

BibliograpyCitation : In Thai Institute of Chemical Engineering and Applied Chemistry and Khon Kaen University. Faculty of Engineering. The 34th Thai Institute of Chemical Engineering and Applied Chemistry International Conference (TIChE 2025) (TIChE 2025 TIChE-AM-03). Bangkok : Thai Institute of Chemical Engineering And Applied Chemistry, 2025

eng

©copyrights King Mongkut's University of Technology North Bangkok

ลำดับที่.	ชื่อแฟ้มข้อมูล	ขนาดแฟ้มข้อมูล	จำนวนเข้าถึง	วัน-เวลาเข้าถึงล่าสุด
1	TIChE 2025 TIChE-AM-03.pdf	2.33 MB

ใช้เวลา

0.027056 วินาที