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Abstract

Tracing the sand source is helpful to interpret the evolution of deserts and explain the relations between the desert and the climatic geographical condition around. Furthermore, it is helpful to investigate the reasons for sandstorms in corresponding areas. In this work, near infrared spectroscopy combined with hierarchical cluster analysis was proposed as a novel method to characterize sand samples collected from Badain Jaran and Tengger Deserts, two main sources of sandstorms in North China. Partial least square discriminant analysis gives a classification result with an accuracy of 100% for the estimation of hierarchical cluster analysis. The results provide support that Badain Jaran Desert and Tengger Desert have sand exchanged by monsoonal weather events. The transmission between the two deserts is also affected by the local terrain. The sand samples were also analyzed by electron microscopy, energy dispersive spectroscopy and Fourier transform infrared spectroscopy to investigate the sample differences in morphology, elemental contents and molecular structures. Near infrared spectroscopy combined with chemometric methods has the potential to be used for the identification of sand samples to determine the sources of sands with advantages of fast, nondestructive, low cost and in situ analysis.

Keywords

Sand identification dune activation near infrared spectroscopy chemometrics

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References

Yao

Wang

Han

, et al. Migration of sand dunes on the northern Alxa Plateau, Inner Mongolia, China. J Arid Environ 2007; 70: 80–93.

Kidron

Herrnstadt

Barzilay

. The role of dew as a moisture source for sand microbiotic crusts in the Negev Desert, Israel. J Arid Environ 2002; 52: 517–533.

Onn

Rivka

Yehouda

, et al. Sand dunes as a major proximal dust source for late Pleistocene loess in the Negev Desert, Israel. Quaternary Res 2008; 70: 275–282.

Yang

Williams

MAJ

. The ion chemistry of lakes and late Holocene desiccation in the Badain Jaran Desert, Inner Mongolia, China. CATENA 2003; 51: 45–60.

Zhang

Dong

. Wind regime and sand transport in China’s Badain Jaran Desert. Aeolian Res 2015; 17: 1–13.

Zhang

X-L

Cheng

Chung

Y-S

. Development of a severe sand-dust storm model and its application to Northwest China. Water Air Soil Pollution: Focus 2003; 3: 173–190.

S-H

. Luminescence dating of K-feldspar from sediments: a protocol without anomalous fading correction. Quaternary Geochronol 2011; 6: 468–479.

Wang

Sun

Chen

, et al. Formation and evolution of the Badain Jaran Desert, North China, as revealed by a drill core from the desert centre and by geological survey. Palaeogeogr Palaeoclimatol, Palaeoecol 2015; 426: 139–158.

Yang

. Geochemical and geomorphological evidence for the provenance of aeolian deposits in the Badain Jaran Desert, northwestern China. Quaternary Sci Rev 2016; 131: 179–192.

10.

Ren

Yang

Wang

, et al. Geochemical evidence of the sources of aeolian sands and their transport pathways in the Minqin Oasis, northwestern China. Quaternary Int 2014; 334–335: 165–178.

11.

Liu

Wang

X-H

Zhang

X-Q

, et al. Desertification process and its driving forces in the dune-activation region between the Badain Juran and Tengger deserts. Arid Zone Res 2011; 6: 009.

12.

Yang

, et al. Determination of geographical origin and icariin content of Herba Epimedii using near infrared spectroscopy and chemometrics. Spectrochim Acta Part A: Mol Biomol Spectrosc 2018; 191: 233–240.

13.

Sakudo

. Near-infrared spectroscopy for medical applications: current status and future perspectives. Clin Chim Acta 2016; 455: 181–188.

14.

Dong

Sørensen

, et al. Gum arabic authentication and mixture quantification by near infrared spectroscopy. Food Control 2017; 78: 144–149.

15.

Cayuela

García

. Nondestructive measurement of squalene in olive oil by near infrared spectroscopy. LWT – Food Sci Technol 2018; 88: 103–108.

16.

Kagaya

Miyamoto

. A systematic review of near-infrared spectroscopy in flap monitoring: current basic and clinical evidence and prospects. J Plast Reconstruct Aesth Surg 2018; 71: 246–257.

17.

Meer Fvd . Near-infrared laboratory spectroscopy of mineral chemistry: a review. Int J Appl Earth Observ Geoinform 2018; 65: 71–78.

18.

Chen

Wang

Qing-Tao

, et al. On-line determination of white granulated sugar granularity by artificial neural network-near infrared spectroscopy. Food Sci Technol 2011; 5: 211–114.

19.

Wang

Chen

, et al. Rapid authentication of starch adulterations in ultrafine granular powder of Shanyao by near-infrared spectroscopy coupled with chemometric methods. Food Chem 2017; 215: 108–115.

20.

Zwanziger

Förste

. Near infrared spectroscopy of fuel contaminated sand and soil. I. Preliminary results and calibration study. J Near Infrared Spectrosc 1998; 6: 492–496.

21.

Dungan

Iii

. Near infrared spectroscopic analysis of foundry moulding and core sands. J Near Infrared Spectrosc 2007; 15: 189–194.

22.

Balabin

Syunyaev

. Petroleum resins adsorption onto quartz sand: near infrared (NIR) spectroscopy study. J Coll Interface Sci 2008; 318: 167–174.

23.

Wold

Esbensen

Geladi

. Principal component analysis. Chemometr Intell Lab Syst 1987; 2: 37–52.

24.

Mehmood

Liland

Snipen

, et al. A review of variable selection methods in partial least squares regression. Chemometr Intell Lab Syst 2012; 118: 62–69.

25.

Marini

Bucci

Magrì

, et al. Artificial neural networks in chemometrics: history, examples and perspectives. Microchem J 2008; 88: 178–185.

26.

Wenz

. Examining water in model membranes by near infrared spectroscopy and multivariate analysis. Biochim Biophys Acta (BBA) – Biomembr 2018; 1860: 673–682.

27.

Almeida

JAS

Barbosa

LMS

Pais

AACC

, et al. Improving hierarchical cluster analysis: a new method with outlier detection and automatic clustering. Chemometr Intell Lab Syst 2007; 87: 208–217.

28.

Wold

Esbensen

Geladi

. Principal component analysis. Chemometr Intell Lab Syst 1987; 2: 37–52.

29.

Brereton

Lloyd

. Partial least squares discriminant analysis: taking the magic away. J Chemometr 2014; 28: 213–225.

30.

Kloprogge

Ruan

Frost

. Near-infrared spectroscopic study of [AlO₄Al₁₂(OH)₂₃(H₂O)₁₂]⁷⁺-O - Si(OH)₃ nitrate crystals formed by forced hydrolysis of Al 3+ in the presence of TEOS. Spectrochim Acta Part A Mol Biomol Spectrosc 2000; 56: 2405–2411.

31.

Viscarra Rossel

Chappell

De Caritat

, et al. On the soil information content of visible–near infrared reflectance spectra. Eur J Soil Sci 2011; 62: 442–453.

32.

Bei-Gang

Qin

Guo

. Forms and bioavailability of phosphorus in sand samples from wulanbuhe desert. J Ecol Rural Environ 2008; 24: 86–486.

33.

Dong

Wang

Chen

, et al. New observational and experimental evidence for the recharge mechanism of the lake group in the Alxa Desert, north-central China. J Arid Environ 2016; 124: 48–61.

34.

Huo

Qing

Yang

, et al. Characteristics of sand-dust weather over Kumtagh Desert during 2007–2008 and the weather styles. J Desert Res 2011; 31: 1037–1045.

35.

Yang

Rao

, et al. Isotopic evidences for provenance of East Asian Dust. Atmos Environ 2009; 43: 4481–4490.

36.

Laurent

Marticorena

Bergametti

, et al. Modeling mineral dust emissions from Chinese and Mongolian deserts. Glob Planet Change 2006; 52: 121–141.

37.

Powell GL, Cox RL, Barber TE, et al. Nondestructive inspection of organic films on sandblasted metals using diffuse reflectance infrared spectroscopy. Office of Scientific & Technical Information Technical Reports, Y–12, July 8, 1996.

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Tracing the dune activation of Badain Jaran Desert and Tengger Desert by using near infrared spectroscopy and chemometrics

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