If we wish to sustain our terrestrial ecosphere as we know it, then reducing the concentration of atmospheric CO_2 is of critical importance. An ideal pathway for achieving this would be the use of sunlight to recycle CO_2, in combination with water, into hydrocarbon fuels compatible with our current energy infrastructure. However, while the concept is intriguing such a technology has not been viable due to the vanishingly small CO_2-to-fuel photoconversion efficiencies achieved. Herein we report a photocatalyst, reduced blue-titania sensitized with bimetallic Cu–Pt nanoparticles that generates a substantial amount of both methane and ethane by CO_2 photoreduction under artificial sunlight (AM1.5): over a 6 h period 3.0 mmol g^(−1) methane and 0.15 mmol g^(−1)  ethane are obtained (on an area normalized basis 0.244 mol m^(−2) methane and 0.012 mol m^(−2) ethane), while no H_2 nor CO is detected. This activity (6 h) translates into a sustained Joule (sunlight) to Joule (fuel) photoconversion efficiency of 1%, with an apparent quantum efficiency of φ = 86%. The time-dependent photoconversion efficiency over 0.5 h intervals yields a maximum value of 3.3% (φ = 92%). Isotopic tracer experiments confirm the hydrocarbon products originate from CO_2 and water

Cho, Chang-Hee

Grimes, Craig A.

Grimes, Keltin M.

Hoffmann, Michael R.

Hwang, Yunju

In, Su-Il

Jung, Jin-Woo

Kim, Hwapyong

Lee, Jaewoong

Majima, Tetsuro

Sorcar, Saurav

Caltech Authors - Main

1Supplementary Information
CO2, water, and sunlight to hydrocarbon fuels: A sustained sunlight to fuel (Joule-
to-Joule) photoconversion efficiency of 1%
Saurav Sorcara, Yunju Hwanga, Jaewoong Leea, Hwapyong Kima, Keltin M. Grimesa, Craig A. 
Grimesa, Jin-Woo Jungb, Chang-Hee Chob, Tetsuro Majimac, Michael R. Hoffmannd, and 
Su-Il Ina,*
aDepartment of Energy Science & Engineering, DGIST, 333 Techno Jungang-daero, Hyeonpung-
myeon, Dalseong-gun, Daegu-42988, Republic of Korea. *email: insuil@dgist.ac.kr
bDepartment of Emerging Materials Science, DGIST, 333 Techno Jungang-daero, Hyeonpung-
myeon, Dalseong-gun, Daegu-42988, Republic of Korea.
cThe Institute of Scientific and Industrial Research (SANKEN), Osaka University, Mihogaoka 8-1, 
Ibaraki, Osaka 567-0047, Japan
dLinde+Robinson Laboratories, California Institute of Technology, Pasadena, California 91125, 
United States
Electronic Supplementary Material (ESI) for Energy & Environmental Science.
This journal is © The Royal Society of Chemistry 2019
2Methods
Blue Titania (BT) nanoparticle synthesis. Blue titania (BT) nanoparticles were synthesized 
according to our previously reported method1. In brief, 200 mg P25 nanoparticles were mixed 
with 30 mg sodium borohydride (NaBH4, 98%) purchased from Alfa Aesar using a mortar and 
pestle.  The mixture was then placed in a quartz tube furnace and heated at 350 °C for 0.5 h. The 
resulting sample was copiously washed with deionized (DI) water and ethanol, a cycle repeated 
five times. Finally, the sample was dried at 90°C overnight.
Synthesis of Cux%-Pt0.35%-BT.  Blue titania nanoparticles were sensitized with a fixed amount (0.35 
wt.%) of Pt nanoparticles according to our previous report1. 100 mg of Pt0.35%-BT was dispersed 
in a solution of 20 ml DI water and 5 ml methanol. Variable concentrations of CuNO3.6H2O were 
added to the above mixture and stirred under dark for 1 h in a closed system.  The suspension 
was then illuminated under AM1.5 for 2 h.  Finally, the samples were washed with DI water and 
dried in a vacuum oven at 90 °C for 12 h.  The resulting samples were identified as Cux%-Pt0.35%-
BT, where x = 0.50, 0.75, 1.00, and 1.25 corresponding to theoretically calculated wt.% Cu.  
Material characterization.  X-ray powder diffraction (XRD) spectroscopy was recorded on a 
Panalytical, Empyrean X-ray diffractometer using Cu kradiation (1.54Å) operating at 40 kV 
and 30 mA. The lattice structure was observed by a field emission tunnelling electron microscopy 
(FE-TEM) taken from Hitachi HF-3300 operating at 300 kV. The elemental composition of Cu1.00%-
Pt0.35%-BT was measured using the energy dispersive spectroscopy (EDS) attachment of the HF-
3300 FE-TEM. UV-Visible diffuse reflectance spectroscopy (UV-vis DRS) were measured upon a 
3Cary series UV-visible near infrared spectrophotometer with a diffuse reflectance accessory. 
Photoluminescence (PL) spectroscopy was carried out on Cary Eclipse fluorescence 
spectrophotometer (excitation = 320 nm) with a diffuse reflectance accessory.  X-ray photoelectron 
spectroscopy (XPS) was conducted using Thermo VG, K-alpha using Al K line as the X-ray source. 
Electron paramagnetic resonance (EPR) spectra were recorded using a Jeol-FA100 spectrometer 
at 100 K.  Time-resolved PL measurements was performed using a home-built optical microscope 
system at room-temperature. The sample was excited by a pico-second pulsed diode laser 
(PicoQuant, LDH-P-FA-355) with a 355 nm wavelength (FWHM = 56 ps) and repetition rate of 40 
MHz. The excitation source was focused from 40× (NA = 0.6) objective (Nikon). Fourier-transform 
infrared (FTIR) analysis was performed using a Thermo Scientific Nicolet Continuum 
spectrometer. Powder samples were prepared in KBr, and pellets were pressed from the powder 
mixture.
Photocatalytic CO2 reduction.  
We have utilized a continuous flow-through system for CO2 and water reduction under 1 
sun condition. In short, in this case, the photocatalytic powder is dispersed upon a nanoporous 
disk, composed of spun glass through which reactant flows while under AM1.5 illumination. 
Product analysis was conducted every 0.5 h by an online gas chromatography (GC) unit 
(Shimadzu, GC-2014) having helium carrier gas.  The GC was equipped with a flame ionization 
detector (FID, Restek-Rt-Q-bond column, ID = 0.53 mm and length = 30 m).  Photocatalyst stability 
was evaluated by repeated testing of the same sample for CO2 photoreduction; after each 12 h 
4test cycle the photocatalyst was vacuum annealed at 100 °C for 2h, a process previously used to 
regenerate the photocatalyst1,2. 
Hydrogen (H2) detection was performed using a gas chromatograph with Ar as carrier gas 
(Agilent, 7890B) using Molecular sieve (Msieve) 5A column (G3591-7003, 2 m x 1/8 inch, 2 mm 
SS packed type). Carbon monoxide (CO) was determined using gas chromatography (GC) unit 
(Shimadzu, GC-2014) with Rt-Msieve 5A column (30 m, ID = 0.32 mm, 30 m).  Isotopic 13CO2 and 
control experiments were performed to confirm the carbon source.  13CO2 (13C 99%), diluted in 
pure He gas (99.999%) to give a final 13CO2 concentration of 500 ppm, was purchased from Sigma 
Aldrich.  The 13CH4 produced from moist 13CO2 gas was analysed using a gas chromatography-
mass spectrometer (GC-MS) manufactured by Shimadzu, GC-MS-QP2010 ULTRA (Restek Rt Q-
bond column, ID= 0.32 mm and length = 30 m). Moist CO2 was introduced into the photocatalyst 
(40 mg) loaded photoreactor, and the gaseous products analysed after 3 h of AM1.5 illumination. 
Two control tests were performed: (i) He/H2O(g) mixture, and (ii) a blank photoreactor test (no 
photocatalyst) under AM1.5 illumination. H218O (97 atom % 18O) was purchased from Sigma-
Aldrich. Isotopic oxygen evolution test was conducted on gas chromatography-mass 
spectrometer (GC-MS) manufactured by Shimadzu, GC-MS-QP2010 ULTRA (Restek Rt-Msieve 5A 
column, fused silica PLOT, ID = 0.53 mm and length = 30 m).
(1) Photoconversion efficiency calculation for 6 h
Methane: (3 mmol g-1) * 40 mg sample = 120 x 10-6 mole * 810 kJ mol-1 = 97.2 J
Ethane: (0.150 mmol g-1) * 40 mg sample = 6 x 10-6 mole * 1560 kJ mol-1 = 9.4 J
Energy content of fuel produced by CO2 photoreduction during 6 h period: 106.6 J
AM1.5 energy input for 6 h = (4.88 cm2)(100 mJ s-1 cm-2)(3600s h-1)(6 h) = 10,540.8 J
5AM1.5, 100 mW cm-2 incident upon 4.88 cm2 surface area.
Solar energy in to fuel energy out (Joules to Joules) = (106.2/10,540) x 100 = 1.0 %
(2) AQY calculation for 12 h
Yield of CH4 produced in 12 h = 0.283 mmolg-1h-1, hence the number of reacted electrons = 1.4 x 
1021.  Substituting this value and that of manuscript E.7 into equation A.1, the AQY for CH4 is AQY= 
45%. The yield of C2H6 produced in 8 h = 0.020 mmolg-1h-1, the corresponding number of reacted 
electrons = 1.7 x 1020.  Substituting this value and that of E.7 into equation A.1 we find the AQY 
for C2H6 is AQY = 5%.  The total AQY over 12 h = 50%.
6Fig. S1. Time resolved photoluminescence spectroscopy results of (a) P25, (b) BT, (c) Cu1.00%-BT, 
(d) Pt0.35%-BT, and (e) Cu1.00%-Pt0.35%-BT (f) Pt0.35%- Cu1.00%-BT samples.
7Fig. S2. HR-TEM images of Cu1.00%-Pt0.35%-BT sample.
8Fig. S3. EDS image of Cu1.00%-Pt0.35%-BT sample.
9Fig. S4. (a) TEM Elemental mapping showing the presence of (b) Ti, (c) O, (d) Pt, (e) Cu, and (f) 
EDS, for Cu1.00%-Pt0.35%-BT sample.
10
Fig. S5 XRD patterns of Cu-Pt deposited blue titania nanoparticles. 
Identical XRD patterns were obtained for all the samples prepared, which demonstrates 
that both Cu and Pt nanoparticles deposition did not affect the original crystalline phase of 
composition of blue titania nanoparticles. The results imply that no large Cu or Pt related 
crystallites were formed.
11
Fig. S6 Electron paramagnetic resonance (EPR) spectroscopy result of blue titania. 
12
Fig. S7 Control test results of Cu1.00%-Pt0.35%-BT sample.
13
Fig. S8 Control samples test results with respect to Cu1.00%-Pt0.35%-BT sample (Methane evolution).
14
Fig.S9 Control samples test results with respect to Cu1.00%-Pt0.35%-BT sample (Ethane evolution).
15
Fig. S10 XPS results for Cu1.00%-Pt0.35%-BT sample after 12 h photocatalytic CO2 reduction test (a) 
Pt 4f, and (b) Cu 2p.
16
Fig. S11. Fuel output obtained by synthesizing a fresh Cu1.00%-Pt0.35%-BT photocatalyst sample, i.e. 
‘from scratch,’ and testing it in different GC unit: (a) Methane yield, and (b) Ethane yield.
17
Table S1. Comparison of previous works pertained with CO2 photoreduction into hydrocarbon products.
Photocatalyst Photocatalytic CO2 reduction test 
condition
Hydrocarbon yield
G-TiO23
0.1 g of sample dispersed on glass reactor 
with an area of 4.2 cm2. A 300 W Xe arc 
lamp used as light source.
CH4 = 10.1 molg-1h-1  
C2H6 =  16.8 molg-1h-1
Nf/Pd-TiO24
Experiments were carried out in the 
presence of sodium carbonate, and CO2 
was purged for 30 min prior to irradiation. 
Initially the pH of the suspension was 
adjusted to different values (pH 1, 3, and 
11). A 300 W Xe arc lamp (Oriel) was used 
as a light source.
CH4 ≈1.4 molg-1h-1 
C2H6  ≈0.7 molg-1h-1
Au@TiO2 yolk-shell hollow sphere5
0.1 g of sample dispersed on glass reactor 
with an area of 4.2 cm2. The volume of 
reaction system used was about 230 ml. A 
300 W Xe arc lamp used as light source.
CH4 = 2.52 molg-1h-1
C2H6 = 1.67 molg-1h-1
Reduced Titania nanoparticles6 100 mg photocatalyst illuminated using 
300 W Xe lamp ( AM 1.5G)
CO = 1818 ppmg-1
CH4 = 477 ppmg-1
Cu(I)/TiO2-x nanoparticles7
50 mg photocatalyst preheated using 250 
W infrared lamp followed by illumination 
using 150 W solar simulator (Oriel) CO = 4.3 µmolg
-1h-1
Ti3+-self doped TiO2 brookite nanosheets8
Mixture of CO2 (99.99%) and water 
vapour. Visible light irradiation using 300 
W Xe lamp ( ≥420 nm)
CO = 23.5 molg-1h-1
CH4 = 11 molg-1h-1
0.35 weight percent-Pt-Blue Titania1 
40 mg photocatalyst loaded onto 
photoreactor followed by illumination 
with  100 W solar simulator (Oriel, LCS-
100 with AM 1.5G filter)
CH4 = 80.35 molg-1h-1
Reduced {001}-TiO2-x9
0.03 g catalysts dispersed on petri dish. 
The volume of reactor used was 300 ml 
and tests were done using 300 W Xe lamp 
( AM 1.5G)
CO ≈ 0.8 molg-1
CH4 ≈ 0.9 molg-1
TiO2-Pd/C composite10
125 mg catalyst was taken in 125 ml 
NaOH solution with CO2 inflation. Tests 
were carried out in 225 ml cylindrical 
glass reactor with a built in light source of 
32 W Hg lamp. 
CH4 = 5.70 ± 0.11 x 10-6 mol
18
1 weight percent -Pt Graphene-Blue 
Titania nanoparticles2
40 mg photocatalyst loaded onto 
photoreactor followed by illumination 
with  100 W solar simulator (Oriel, LCS-
100 with AM 1.5G filter)
CH4 = 37 molg-1h-1
C2H6 = 11 molg-1h-1
Self-doped TiO2 11 Self-assembled reactor (380 ml). 
Illumination with two 300 W Xe lamp. 
CO = 0.075 mol per m2 
CH4 = 0.015 mol per m2
Au-Pd alloying at TiO2 {101} facet12
10 mg photocatalyst was coated on 
quartz plate. Illumination using 300 W Xe 
lamp.
CH4 = 2.72 molg-1h-1
Porous hyperlinked polymer-TiO2-
graphene composite13
20 mg photocatalyst was placed on a 
circular glass dish. The CO2 was generated 
by the reaction of sodium hydrogen 
carbonate with diluted sulphuric acid 
after removing the air. A 300 W Xe lamp 
was used as the light source.
CH4 = 27.62 molg-1h-1
Pt-Ultrathin TiO2 nanosheets14
10 mg sample spread in chamber with 
0.08 MPa CO2. Water vapour added 
through bubbling (50 ml chamber 
volume).  A 300 W Xe lamp was used as 
the light source.
CH4 = 66.4 molg-1h-1
Pt-Carbon doped titania15 
0.1 g photocatalyst filled in reactor 
(volume 357 ml) with 100 ml NaOH. A 8 W 
Hg UV lamp was used as light source.
CO ≈ 0.25 molg-1h-1
CH4 = 2.5molg-1h-1
Nanorattle Au@PtAg-ZIF-816
30 mg photocatalyst sprinkled on bottom 
of Pyrex cell reactor (600 ml). Water was 
sprayed around the catalyst. Illumination 
with 500 W Xe lamp at UV−vis (λ = 
200−1000 nm).
CO = 14.5 molg-1h-1
CH4 = 1.2molg-1h-1
Current work
40 mg photocatalyst loaded onto 
photoreactor followed by illumination 
with  100 W solar simulator (Oriel, LCS-
100 with AM 1.5G filter)
CH4 = 500 molg-1h-1
C2H6 = 25 molg-1h-1
19
Table S2. Information obtained from TRPL decay curves according to bi-exponential decay.
Charge transfer lifetime17 (CT) = (semi xhybrid) / semi -hybrid
Photoinduced Charge transfer efficiency17 (%) = hybrid / CT
Sample
s 
(ns)
f
(ns)
average 
(ns)
CT
(ns)
(%)
BT 3.36 0.43 2.90 -- --
Pt0.35%-BT 2.99 0.40 2.53 19.82 12.76
Cu1%-BT 2.99 0.37 2.56 21.83 11.72
Pt0.35%-Cu1%-BT 2.85 0.41 2.41 14.26 16.90
Cu1%-Pt0.35%-BT 2.78 0.32 2.39 
(Minimum)
13.59 
(Minimum)
17.58
(Maximum)
20
References
1 S. Sorcar, Y. Hwang, C. A. Grimes and S. Il In, Mater. Today, 2017, 20, 507–515.
2 S. Sorcar, J. Thompson, Y. Hwang, Y. H. Park, T. Majima, C. A. Grimes, J. R. Durrant and S. 
Il In, Energy Environ. Sci., 2018, 11, 3183–3193.
3 W. Tu, Y. Zhou, Q. Liu, S. Yan, S. Bao, X. Wang, M. Xiao and Z. Zou, Adv. Funct. Mater., 
2013, 23, 1743–1749.
4 W. Kim, T. Seok and W. Choi, Energy Environ. Sci., 2012, 5, 6066.
5 W. Tu, Y. Zhou, H. Li, P. Li and Z. Zou, Nanoscale, 2015, 7, 14232–14236.
6 H. Yaghoubi, Z. Li, Y. Chen, H. T. Ngo, V. R. Bhethanabotla, B. Joseph, S. Ma, R. Schlaf and 
A. Takshi, ACS. Catal., 2015, 5, 327–335.
7 L. Liu, C. Zhao and Y. Li, J. Phys. Chem. C, 2012, 116, 7904–7912.
8 X. Xin, T. Xu, L. Wang and C. Wang, Sci. Rep., 2016, 6, 23684.
9 W. Fang, L. Khrouz, Y. Zhou, B. Shen, C. Dong, M. Xing, S. Mishra, S. Daniele and J. Zhang, 
Phys. Chem. Chem. Phys., 2017, 19, 13875–13881.
10 Y. Yu, W. Zheng and Y. Cao, New J. Chem., 2017, 41, 3204–3210.
11 Y. Zhang, X. Wang, P. Dong, Z. Huang, X. Nie and X. Zhang, Green Chem., 2018, 20, 2084–
2090.
12 Q. Chen, X. Chen, M. Fang, J. Chen, Y. Li, Z. Xie, Q. Kuang and L. Zheng, J. Mater. Chem. A, 
2019, 7, 1334–1340.
13 S. Wang, M. Xu, T. Peng, C. Zhang, T. Li, I. Hussain, J. Wang and B. Tan, Nat. Commun., , 
DOI:10.1038/s41467-019-08651-x.
14 Y. Liu, C. Miao, P. Yang, Y. He, J. Feng and D. Li, Appl. Catal. B Environ., 2019, 244, 919–
21
930.
15 M. Tasbihi, M. Schwarze, M. Edelmannová, C. Spöri, P. Strasser and R. Schomäcker, Catal. 
Today, 2018, 328, 8–14.
16 Y. Su, H. Xu, J. Wang, X. Luo, Z. liang Xu, K. Wang and W. Wang, Nano Res., 2019, 12, 
625–630.
17 J. Lee, H. S. Shim, M. Lee, J. K. Song and D. Lee, J. Phys. Chem. Lett., 2011, 2, 2840–2845.


CO_2, water, and sunlight to hydrocarbon fuels: a sustained sunlight to fuel (Joule-to-Joule) photoconversion efficiency of 1%

https://authors.library.caltech.edu/95640/2/c9ee00734b1_si.pdf

CO_2, water, and sunlight to hydrocarbon fuels: a sustained sunlight to fuel (Joule-to-Joule) photoconversion efficiency of 1%

Abstract

Similar works

Full text

Available Versions

Caltech Authors - Main