Sage Journals: Discover world-class research

Abstract

People can perceive wetness when they touch a cold dry surface, a phenomenon known as the wetness illusion. Most previous studies of the effect of fabric physical properties on wetness perception have been focused on wetted fabrics. However, since water affects a fabric’s physical and heat transfer properties, it is difficult to fully understand the true mechanism of a fabric’s physical properties on wetness perception. Twelve young female participants were recruited to touch the fabrics with their index fingers and assess wetness perception in two experiments. This study is an investigation of the effect of a fabric’s physical properties on wetness perception from two perspectives: surface properties (roughness) and compression properties (softness). In Experiment 1, participants horizontally touched nine dry fabrics with varying roughness and maximum transient thermal flux at three surface temperatures (10°C, 13°C, and 16°C), maintaining a constant velocity, and rated both roughness and wetness perceptions. In Experiment 2, participants vertically pressed nine dry fabrics with varying softness and maximum transient heat flux at the same three surface temperatures (10°C, 13°C, and 16°C), applying constant pressure, and rated both softness and wetness perceptions. The results demonstrate that fabric roughness was negatively correlated with wetness perception, and softness was similarly and negatively correlated with wetness perception. However, regression analysis identified neither roughness nor softness as the primary predictor of wetness perception, whereas maximum transient thermal flux emerged as the primary predictor. We conclude that the effect of fabric surface roughness and softness on wetness perception is primarily attributed to an association with thermal conductivity.

Keywords

Wetness perception cold dry stimulation fabric roughness fabric softness maximum transient thermal flux

Get full access to this article

View all access options for this article.

References

Raccuglia

Sales

Heyde

, et al. Clothing comfort during physical exercise: Determining the critical factors. Appl Ergon 2018; 73: 33–41.

Kim

Wang

JW.

Hygrosensation: Feeling wet and cold. Curr Biol 2016; 26: R408–R410.

Viessman

Man and his thermal environment. In: Jennings

Murphy

(eds.) Interactions of man and his environment: Proceedings of the Northwestern University conference held January 28–29, 1965. Boston, MA: Springer, 1966, pp. 77–85.

Filingeri

Ackerley

The biology of skin wetness perception and its implications in manual function and for reproducing complex somatosensory signals in neuroprosthetics. J Neurophysiol 2017; 117: 1761–1775.

Ackerley

Kavounoudias

The role of tactile afference in shaping motor behaviour and implications for prosthetic innovation. Neuropsychologia 2015; 79: 192–205.

Ackerley

Watkins

RH.

Microneurography as a tool to study the function of individual C-fiber afferents in humans: Responses from nociceptors, thermoreceptors, and mechanoreceptors. J Neurophysiol 2018; 120: 2834–2846.

Filingeri

Havenith

Peripheral and central determinants of skin wetness sensing in humans. In: Romanovsky

(ed.) Handbook of clinical neurology: Volume 156. Thermoregulation: From basic neuroscience to clinical neurology, Part I. Amsterdam: Elsevier, 2018, pp. 83–102.

Shibahara

Sato

, and Kappers

AML.

Relative sensation of wetness of different materials. In: Prattichizzo

Shinoda

Tan

, et al. (eds.) Haptics: Science, technology, and applications: 11th international conference, EuroHaptics 2018, Pisa, Italy, June 13–16, 2018, Proceedings, Part. Cham: Springer International, 2018, pp. 345–353.

Bentley

IM.

The synthetic experiment. Am J Psychol 1900; 11: 405–425.

10.

Han

Wang

, et al. Mouillé: Exploring wetness illusion on fingertips to enhance immersive experience in VR. In: Proceedings of the 2020 CHI conference on human factors in computing systems, Honolulu, HI, USA, 25–30 April 2020, New York, NY: ACM.

11.

Sugimoto

Hoshino

Watanebe

, et al. Research on display that reproduces the thermal sensation perceived by human. In: IECON 2019—45th annual conference of the IEEE Industrial Electronics Society, Lisbon, Portugal, 14–17 October 2019, pp. 6902–6907. Piscataway, NJ: IEEE.

12.

Merrick

Rosati

, and Filingeri

Skin wetness detection thresholds and wetness magnitude estimations of the human index fingerpad and their modulation by moisture temperature. J Neurophysiol 2021; 125: 1987–1999.

13.

Kaplan

Okur

Determination of coolness and dampness sensations created by fabrics by forearm test and fabric measurements. J Sens Stud 2009; 24: 479–497.

14.

Filingeri

Redortier

Hodder

, et al. Thermal and tactile interactions in the perception of local skin wetness at rest and during exercise in thermo-neutral and warm environments. Neuroscience 2014; 258: 121–130.

15.

Filingeri

Redortier

Hodder

, et al. Warm temperature stimulus suppresses the perception of skin wetness during initial contact with a wet surface. Skin Res Technol 2015; 21: 9–14.

16.

Bergmann Tiest

Kosters

Kappers

AML

, et al. Haptic perception of wetness. Acta Psychol 2012; 141: 159–163.

17.

Raccuglia

Pistak

Heyde

, et al. Human wetness perception of fabrics under dynamic skin contact. Text Res J 2018; 88: 2155–2168.

18.

Zhang

Tang

Wang

, et al. Effect of fiber type, water content, and velocity on wetness perception by the volar forearm test: stimulus intensity test. Perception 2019; 48: 862–881.

19.

Merrick

Rosati

, and Filingeri

The role of friction on skin wetness perception during dynamic interactions between the human index finger pad and materials of varying moisture content. J Neurophysiol 2022; 127: 725–736.

20.

Tang

Kan

, and Fan

Assessing and predicting the subjective wetness sensation of textiles: subjective and objective evaluation. Text Res J 2015; 85: 838–849.

21.

Raccuglia

Hodder

, and Havenith

Human wetness perception in relation to textile water absorption parameters under static skin contact. Text Res J 2017; 87: 2449–2463.

22.

Zhang

Tang

, et al. The effect of dynamic friction with wet fabrics on skin wetness perception. Int J Occup Saf Ergon 2018; 26: 370–383.

23.

Maggie

K-P

Chau

K-H

Kan

C-W

, et al. Magnitude estimation approach for assessing stickiness sensation perceived in wet fabrics. Fibers Polym 2018; 19: 2418–2430.

24.

Troynikov

Nawaz

, and Vu

Evaluation of surface characteristics of inner layer fabrics suitable for structural firefighters’ clothing. Text Res J 2012; 82: 1014–1025.

25.

Tan

Effects of fabric roughness and softness on human wetness perception under dry and cold stimuli. Master’s Thesis, Donghua University, China, 2024.

26.

Valenza

Bianco

, and Filingeri

Thermosensory mapping of skin wetness sensitivity across the body of young males and females at rest and following maximal incremental running. J Physiol 2019; 597: 3315–3332.

27.

Fan

Zhang

Comparison of reality and illusion of wetness on soft materials and the multisensory perceptual space of wetness illusion. Text Res J 2024; 94: 1205–1219.

28.

ISO 10551:2019. Ergonomics of the physical environment. Subjective judgement scales for assessing physical environments.

29.

Kawabata

Niwa

Objective measurement of fabric hand. In: Raheel

(ed.) Modern textile characterization methods. Boca Raton, FL: CRC Press, pp. 329–354.

30.

Bergmann Tiest

WM.

Tactual perception of material properties. Vision Res 2010; 50: 2775–2782.

31.

Elder

Fisher

Armstrong

, et al. 5—Fabric softness, handle, and compression. J Text Inst 1984; 75: 37–46.

32.

Shibahara

Sato

Illusion of wet sensation by controlling temperature and softness of dry cloth. In: Bello

Kajimoto

, and Visell

(eds.) Haptics: Perception, devices, control, and applications. Cham: Springer International, 2016, pp. 371–379.

Effect of physical properties of fabric under cold dry stimulation on wetness illusion

Abstract

Keywords

Get full access to this article

References