Aesthetics

Aesthetics imply the appearance and attraction of textile products; it includes the color and texture of the material.^[9]

Durability

Durability in textiles refers to the product's capacity to endure use; the amount of time the product is regarded adequate for the intended application.^[9]

Comfort

The performance of textiles extends to functionality through comfort and protection. The term "comfort" (or "being comfortable") refers to a state of physical or psychological well-being—our perceptions, physiological, social, and psychological requirements are all part of it. After food, It is the clothing that satisfies these comfort needs.^[10] Clothing provides comfort on a number of levels, including aesthetic, tactile, thermal, moisture, and pressure.^[11]

• Aesthetic comfort: Aesthetic comfort is associated with visual perception that is influenced by color, fabric construction, finish, style, garment fit, and fashion compatibility. Comfort on an aesthetic level is necessary for psychological and social well-being.^[12][13][14]
• Thermoregulation in humans and thermophysiological comfort: Thermophysiological comfort is the capacity of the clothing material that makes the balance of moisture and heat between the body and the environment. It is a property of textile materials that creates ease by maintaining moisture and thermal levels in a human's resting and active states. The selection of textile material significantly affects the comfort of the wearer. Different textile fibers have unique properties that make them suitable for use in various environments. Natural fibers are breathable and absorb moisture.^{[15][16][17][18][19][20]} The major determinants that influence thermophysiological comfort are permeable construction, heat, and moisture transfer rate.^[21]
  • Thermal comfort: One primary criterion for our physiological needs is thermal comfort. The heat dissipation effectiveness of clothing gives the wearer a neither very hot nor very cold feel. The optimum temperature for thermal comfort of the skin surface is between 28 and 30 degrees Celsius, i.e., a neutral temperature. Thermophysiology reacts whenever the temperature falls below or exceeds the neutral point on either side; it is discomforting below 28 and above 30 degrees.^[22] Clothing maintains a thermal balance; it keeps the skin dry and cool. It helps to keep the body from overheating while avoiding heat from the environment.^[23][24]
  • Moisture comfort: Moisture comfort is the prevention of a damp sensation. According to Hollies' research, it feels uncomfortable when more than "50% to 65% of the body is wet."
• Tactile comfort: Tactile comfort is a resistance to the discomfort related to the friction created by clothing against the body. It is related to the smoothness, roughness, softness, and stiffness of the fabric used in clothing. The degree of tactile discomfort may vary between individuals. It is possible due to various factors, including allergies, tickling, prickling, skin abrasion, coolness, and the fabric's weight, structure, and thickness. There are specific surface finishes (mechanical and chemical) that can enhance tactile comfort. Fleece sweatshirts and velvet clothing, for example. Soft, clingy, stiff, heavy, light, hard, sticky, scratchy, prickly are all terms used to describe tactile sensations.^{[25][26] [27]}
• Pressure comfort: The comfort of the human body's pressure receptors' (present in the skin) sensory response towards clothing. Fabric with lycra feels more comfortable because of this response and superior pressure comfort. The sensation response is influenced by the material's structure: snugging, looseness, heavy, light, soft, or stiff structuring.^[28][29]

Protection

Protection in textiles refers to a large application area where the performance (of functionality) is more central than aesthetic values.

• UV protection performance in textiles,^[30] There are tests to quantify the protection values from harmful ultraviolet rays.^[31]
• Flame retardant textiles^[32]
• Water repellant performance of textiles^[33]
• Waterproofness^[34]
• Cold and wind protection textiles^[34]
• Bacteria and virus protection in textiles.^[35] Antiviral textiles are a further exploitation of using antimicrobial surfaces that are applicable to both natural and synthetic textiles. Exhibiting antiviral properties, these surfaces may inactivate the lipid-coated viruses.^[35] There are particular test methods for assessing the performance of antiviral textiles.^[36]
• Bulletproof vest

Appearance retention

The ability of a textile product to retain its appearance after being used, washed, and ironed is referred to as appearance retention.^[9]

Care

The treatment necessary to maintain the appearance of textile products is referred to as care. Textile products need to be cleaned and ironed to keep their look. This includes things like how to wash them and how to dry them.^[9] Care labelling for textile products takes into account the performance of each component as well as the manufacturing methods.^[37]

Cost

It is influenced by a variety of elements. The cost of a textile product includes the raw material, manufacturing, and maintenance costs.^[9]

Environmental impact

Every textile product has an impact on the environment. The extent to which textiles harm the environment during manufacturing, care, and disposal is a concept of textile serviceability.^[9] The substances which add performance to textiles have a severe impact on the environment and on human health. The halogenated flame retardants, PFC treated stain repellant, and triclosan or triclocarban or silver-containing antimicrobial fabrics certainly have a lot to do with the effluent and environment.^[38][39]

Fundamentally, each fiber and fabric has distinct properties, and they are chosen based on their suitability for fitness for purpose.^[46][47][48] Users have five basic criteria for performance, including appearance, comfort, durability, maintenance, and cost.^[49] These performance expectations are not the same as those of specialist textiles. Due to the often highly technical and legal requirements of these products, these textiles are typically tested in order to ensure they meet stringent performance requirements. A few examples of different areas are:

• Sportswear must have these characteristics: strength, moisture management, stretch, and thermal comfort.
• Military textiles demand protection from hostile weather. A bulletproof vest necessitates low impact. Camouflage may be needed.^[50]
• Firefighting clothing must be flame resistant, thermally resistant, and lightweight. Water resistance and visibility are requirements for bunker gear. Turnout gear for firefighters is not a "one size fits all" proposition. It depends on the individual role and duties assigned.^{[upper-alpha 1]}
• Occupational hazards demand a specific degree of protection.^[50]
• Medical textiles need clothing with barriers and antimicrobial surfaces, such as cleanroom suits and hazmat suits.
• Wearable electronics in E-textiles require flexibility as well as washability. (See Wearable technology and Hexoskin.)
• Body armor (protective clothing designed to absorb or deflect physical attacks) demands specific performance standards.
• Wetsuits are made with neoprene and butyl rubber. The foamed neoprene of the suit thermally insulates the wearer.^[52]
• Automotive textiles have specific performance requirements in various sections of the car. The different types of fibers used for separate areas of the car's interior are shown below:

Tensile strength, bursting, sensorial comfort, thermal comfort, heat transfer, water repellency MVTR, air permeability, pilling, shrinkage, fading, lightfastness, drape and hand feel are a few performance parameters.^[5][55][56]

High-performance fibers

High-performance fibers are specifically synthesized to achieve unique properties such as higher heat resistance, exceptional strength, high strength-to-weight ratio, stiffness, tensile strength, chemical or fire resistance.^[71] These high-performance fibers are used in protective clothing (PPE) with exceptional characteristics like chemical resistance and fire resistance.^[72]

• Aramid fiber, namely Kevlar, a strong, abrasion-resistant, durable material with high performance. Fiber and fabric engineering can optimize the functionality of the materials.^[73] Kevlar and Nomex which is a flame-resistant meta-aramid material, are used together in advanced bomb suits. The suit helps bomb disposal soldiers from threats associated with improvised explosive devices, including those related to fragmentation, blast overpressure, impact, heat, and flame.
• Carbon fibers have several advantages including high stiffness, high tensile strength, low weight to strength ratio, high chemical resistance, high temperature tolerance and low thermal expansion.^[74][75]
• Polybenzimidazole fiber, also known as PBI, has high thermal stability, flame resistance, and moisture recovery, making it suitable for use in protective clothing. PBI are usually yellow to brown solid infusible up to 400 °C or higher.^[76] PBI is also used in Space suits. In 1969, the United States Air Force selected polybenzimidazole (PBI) for its superior thermal protective performance after a 1967 fire aboard the Apollo 1 spacecraft killed three astronauts.^[77] In the early 1970s USAF laboratories experimented with polybenzimidazole fibers for protective clothing to reduce aircrew deaths from fires.^[78]
• Silicon carbide fiber composed of Silicon carbide is used for bulletproof vests.
• UHMWPE (Ultra-high-molecular-weight polyethylene) is a high abrasion and wear resistance material suitable for durability, low friction, and chemical resistance.^[72]

Finishing methods

Finishing improves appearance and performance.^[79]

Functional finishes or special purpose finishes

The first modern waterproof raincoat was created following the patent by Scottish chemist Charles Macintosh in 1824 of new tarpaulin fabric, described by him as "India rubber cloth," and made by sandwiching a rubber softened by naphtha between two pieces of fabric.^[93][94] Application of performance finishes are not a new concept; Oilcloth is the first known coated fabric. Boiling linseed oil is used to make oilcloth. Boiling oils have been used from the year 200 AD.^[95] The "special purpose finishes" or ''Performance finishes'' are that improve the performance of textiles for a specific end-use.^[96] Performance finishing contributes to a variety of areas. These finishes enable treated textiles with different characteristics, which may be opposite to their natural or inherent nature. Functional finishes add value other than handfeel and aesthetics.^[4][5] Certain finishes can alter the performance suiting for thermal comfort (thermal regulation), antimicrobial, UV protection, easy care (crease resistant cotton fabrics), and insect repellant etc.^[97]

Nanotechnology

Nanotechnology in textiles is a branch of nano-science in which molecular systems at the nano-scale of size (1–100 Nanometre) are applied in the field of textiles to improve performance or add functions to textiles. Nanotechnology unites a variety of scientific fields, such as material science, physics, chemistry, biology and engineering. For example: Nanocoating (of microscopically structured surfaces fine enough to interfere with visible light) in textiles for biomimetics is the new method of structural coloration without dyes.^{[98][99][100][101][102][103][104][105][106]}

See further Nanofabrics

Surface treatments

Certain technologies can alter the surface characterizations of textiles.

Plasma

Plasma is a highly reactive state that activates the substrate, and the oxidized surface of the plasma-treated textile improves dyeing while reducing environmental impacts. Plasma can also be used to treat textiles to obtain waterproofing and oil repellent properties. Different gases in the same fiber may have other effects, and various gases are chosen for different results.^[109]

Laser

Light amplification by stimulated emission of radiation (laser) irradiation is used to modify the structural and surface properties of textiles, as well as to texturize them.^[109]

3D textiles

3D textiles are used in versatile applications, like military textiles, bulletproof jackets, protective clothing, manufacturing 3D composites, and medical textiles. Examples include 3D spacer fabrics, which are used in treating a wound.^[110]

Sweating guarded hot plate test

The test method evaluates the thermal resistance and water vapor permeability of fabrics, which bear on the garment's comfort.^[115][116]

• ISO 11092:2014 (the test for physiological effects — Test for measuring thermal resistance and water-vapor resistance)^[117]
• ASTM F1868 (test for measuring thermal and evaporative resistance)^[118]

Breathability test

Water vapor transmission rate also called moisture vapor transmission rate (MVTR) is a method of testing or measuring the permeability for vapor barriers.

• ASTM F2298 – 03 (test for clothing materials such as protective clothing, laminates, and membranes) a similar test by Japanese Standards Association is JSA – JIS L 1099.^[119]

Air permeability

The air permeability test method is for measuring the ability of air to pass through textile materials.^[120]

• ASTM D737-96 alternative test method is
• ISO 9237:1995

Moisture management test

The moisture wicking or moisture management test is for testing moisture management properties such as wicking capabilities and drying efficiencies.

• AATCC test method 195
• ISO 13029:2012 ^[121]

Qmax test

The Qmax test method is used to evaluate the surface warm-cool sensations of fabric and to indicate the instantaneous thermal feeling sensed when the fabric first comes into contact with the skin surface.^[122][123]

Manikin test

A thermal manikin is a device for analysing the thermal interface of the human body and its environment. It assesses the thermal comfort and insulation properties of clothing, such as protective gear for the military.^[124][125]

Kawabata evaluation system

Kawabata evaluation system measures the mechanical properties of the textiles such as tensile strength, shear strength, surface friction and roughness, The Kawabata evaluation system predicts human responses and understands the perception of softness. Additionally, it can be used to determine the transient heat transfer properties associated with the sensation of coolness generated when fabrics come into contact with the skin while being worn.^[126][127]