Journal of Inorganic Materials ›› 2026, Vol. 41 ›› Issue (7): 974-982.DOI: 10.15541/jim20250365
• RESEARCH ARTICLE • Previous Articles Next Articles
FAN Shengqiang1,2(
), ZHOU Shuhao1, QIAN Junchao1, MA Ruguang1(
), WU Zhengying1(
)
Received:2025-09-19
Revised:2025-12-05
Published:2026-07-20
Online:2026-01-21
Contact:
MA Ruguang, professor. E-mail: ruguangma@usts.edu.cn;About author:FAN Shengqiang (1998-), male, Master candidate. E-mail: fanshengqiang0127@126.com
Supported by:CLC Number:
FAN Shengqiang, ZHOU Shuhao, QIAN Junchao, MA Ruguang, WU Zhengying. Manganese Dioxide/Biocarbon Composite Photothermal Material: Synthesis and Performance in Solar Interface Water Evaporation[J]. Journal of Inorganic Materials, 2026, 41(7): 974-982.
Fig. 1 SEM and TEM characterizations for CC, HMO and HMO/CC (a-c) SEM images of (a) CC, (b) HMO and (c) HMO/CC; (d-f) TEM images of (d) HMO and (e, f) HMO/CC; (g) HRTEM image, (h) SAED pattern and (i) EDS elemental mappings of HMO/CC
Fig. 2 XRD, Raman, EPR and XPS results for CC, HMO and HMO/CC (a) XRD patterns and (b) Raman spectra of CC, HMO and HMO/CC; (c) EPR results of HMO and HMO/CC; (d) Mn2p and (e) O1s XPS spectra of HMO and HMO/CC; (f) C1s XPS spectra of CC and HMO/CC. Colorful figures are available on website
Fig. 3 Optical properties of CC, HMO and HMO/CC (a) UV-Vis-NIR absorption spectra of CC, HMO and HMO/CC; (b) Fluorescence emission spectra of HMO and HMO/CC
Fig. 4 Water evaporation performance of pure water, MCE, CC-MCE, HMO-MCE and HMO/CC-MCE membranes (a) Mass changes of water, (b) evaporation rates and efficiency of pure water, MCE, CC-MCE, HMO-MCE and HMO/CC-MCE membranes at 1 sun illumination; (c) Mass changes of water, (d) evaporation rates and efficiency of HMO/CC-MCE membrane under different light illuminations. Colorful figures are available on website
Fig. 5 Photothermal and water evaporation performance of PU, CC-PU, HMO-PU and HMO/CC-PU sponges (a, b) Surface temperature evolutions of PU, CC-PU, HMO-PU and HMO/CC-PU sponges at 1 sun illumination under (a) dry and (b) wet states; (c) Mass changes of water, (d) evaporation rates and efficiency of pure water, PU, CC-PU, HMO-PU and HMO/CC-PU sponges; (e) Mass changes of water, (f) evaporation rates and efficiency of HMO/CC-PU sponge under different light illuminations. Colorful figures are available on website
| Sample | Total absorption | UV (<400 nm) | Visible (400-760 nm) | Infrared (>760 nm) |
|---|---|---|---|---|
| Solar spectrum | 100% | 7% | 50% | 43% |
| CC | 93.0% | 6.4% | 46.6% | 40.0% |
| HMO | 90.9% | 5.9% | 44.8% | 40.2% |
| HMO/CC | 94.2% | 6.4% | 47.0% | 40.8% |
Table S1 Absorption efficiency of CC, HMO and HMO/CC for spectra in the range of 200-2500 nm
| Sample | Total absorption | UV (<400 nm) | Visible (400-760 nm) | Infrared (>760 nm) |
|---|---|---|---|---|
| Solar spectrum | 100% | 7% | 50% | 43% |
| CC | 93.0% | 6.4% | 46.6% | 40.0% |
| HMO | 90.9% | 5.9% | 44.8% | 40.2% |
| HMO/CC | 94.2% | 6.4% | 47.0% | 40.8% |
Fig. S4 Photothermal performance of MCE and HMO/CC-MCE (a, b) Surface temperature evolutions of MCE and HMO/CC-MCE membranes in the (a) dry and (b) Wet states; (c) Infrared thermographs in the wet state
Fig. S5 Comparison of photothermal performance for HMO/CC and other materials (a) Mass changes of water for different photothermal materials; (b) Mass changes of water for photothermal materials prepared with different carbon substrates
Fig. S6 Cycling and salt-resistance performance of HMO/CC-PU (a) Evaporation rates under 15 cycles; (b) Mass changes in natural seawater and brine with different concentrations;(c) Salt resistance performance of HMO/CC-PU aerogel sponge
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