Electronic Supplementary Information For
Surface oxygen vacancy defect engineering of������� p-CuAlO2 via Ar&H2 plasma
treatment for enhancing VOCs sensing performances���
Bin Tong, a b Gang Meng, * a c Zanhong Deng, a c Mati Horprathum, d Annop
Klamchuen e and Xiaodong Fang * a c
aAnhui Provincial Key Laboratory of Photonic Devices and Materials, Anhui������� Institute of Optics and Fine
Mechanics, Chinese Aca������demy of Sci�������ences, Hefei, 230031, China
bUniversity of Science and Technology������ of China, Hefei 230026, C������hina
cKey Lab of ��Photovoltaic and Energy Conservation Materials, Chinese Academy of Sciences, Hefei
230031, China
d �����Opto-Electrochemical Sensing Research Team, National Electronic and Comp������uter Technology Center,
PathumThani 12120, Thailand
eNational Nanotechnology Center, National Science and Technology Development Agenc������y, Pathum
Thani 12120, Thailand
Experimental Section
1.1 Synthesis of CuAlO2 particles
First of all, 0.04 mol Cu(CH3COO)2·H2O ������(Alfa Aesar, 99.9%) was dissolved in 160 mL absolute alcohol with
vigorous stirring, and then 16 mL HNO3 (Sinopharm Chemical Reagent, 99.7%), 0.2 mol C6H8O7·H2O
(Sinopharm Chemical Reagent, �������99.8%) and 0.04 mol Al[OC������H(CH3)CH2CH3]3 (Alfa Aesar, 97%) were added into
the above solution �������in sequence. After stirring for 6 hours, 16 mL HNO3 was added to the solution drop by drop to
obtain a well-mixed precursor solution. The precursor sol�������ution was dried at 100 °C overnight. In order to remove
the organics, the condensed solution was heated to 300 ����°C for 6 hours. After that, the dried powders were milled
for 24 h using a planetary �����ball miller and then annealed at 1100 °C for 10 h under air atmosphere. Subsequently,
the powders w�������ere reground and heated to 950 °C under flowing N2 atmosphere for 6 hours to form delafossite
CuAlO2 par���t������icles. To ensure the pure phase of delafossite CuAlO2, trace (excess) CuxO was washed with 1 M
diluted hydrochloric acid, 11 deionized water and absolute alcohol in sequence several times, and the�������� final pro������ducts
were dried in an oven at 80 °C for 24 h.
1.2 Fabrication of CuAlO2 sensors
The CuAlO2 slurry was prepared by d�����ispersing the powde����rs in appropriate isopropyl alcohol. CuAlO2 sensors
were prepared by brushing �����the above paste onto a thin alumina substrate with micro-interdigital Pt electrodes.
CuAlO2 films on slide glass substrates were fabricated simultaneously for characterization. After naturally dr�������ying,
the CuAlO2 sensors and films were heated at 350 °C under fl�������owing air atmosphe������re for 3 hours. Afterwards, the
samples were treated by Ar&H2 plasma in KT-S2DQX (150 W, 13.56 MHz, (鄭州科探儀器設備(bei)有限公司)) plasma etching system
at 10 sccm 4% H2 in Ar and the pressure of ~ 99.8 Pa for 30 min, 60�������� min and 90 min, herein are referred to as
pristine, PT-30, PT-60 and PT-90.
1.3 Characterization and gas sensing test
CuAlO2 samples were characterized by X-ray diffract�����ion (XRD, Rigaku Smar�����tlab), scanning electron
microscope (SEM, VEGA3 TESCAN)�����, field emission high resolution transmission electron microscope
(HRTEM, Talos F200X), X-ray photoelectron������ spectroscopy (XPS, Thermo Scientific Esca Lab 250Xi
spectrometer ), photoluminescence (PL, JY Fluorolog-3-Tou) and Electron spin������ resonance (ESR, JEOL, JES
FA200 ESR spectrometer ). Mott-Schottky measurements were carried out o�������n an electrochemical work-station
(Zahner Company, Germany) in 1M NaOH solu������tion (pH=12.5) with frequency of 5000 Hz. Platinum sheet,�������
Ag/AgCl electrode and pristine/ PT-30 CuAlO2 samples were�������� used as counter elec������trode, reference electrode and
work electrode, respective���������ly. Gas sensing tests were examined in SD101 (Hua Chuang Rui Ke Technology Co.,
Ltd.) sensing system. T�������he response������� was defined as ΔR/Ra, ΔR = Rg − Ra, where Ra and Rg are sensor resistance in
��������flow����ing drying air and synthetic VOCs, respectively. During gas sensing test, the total flow rate of the dry air and
VOCs gas w������ere adjusted to be 1000 sccm by mass flow controllers (MFCs).
Fig. S1. Cross-sectional SEM image of typical CuAlO2 sensors. The inset s�����hows a low-magnification image.
The sensing layer is ��comprised of loosely packed CuAlO2 particles, with a thickness of ~ 15 μm
Fig. S2. XRD patterns of pristine and Ar&H2 plasma treated CuAlO2 sensors. Ar&H2 plasma treatment didn’t
cause any detectable impurity phase. All the s��������amples show a 3R (dominent) and 2H mixed Cu�����AlO2 phase.
Fig. S3. SEM images of pristine (a) and Ar&H2 plasma treated PT-30 (b), PT-60 (c) a���nd PT-90 (d) CuAlO2
sensor�����s. Except for 90 minitues treated sample (PT-90) with appearance of small nanodots, no obrvious change
of surface morphology was obervered via Ar&H2 plasma treatment.
中國科學(xue)技(ji)術大(da)學(xue) &nbs�����p;申請論文(wen)提名獎CC - 2019 - SI - Surface oxygen vacancy defect engineering of p-CuAlO2 via Ar&H2 plasma treatment
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