When referring to the antonyms of ductile, it pertains to materials that lack the ability to stretch or deform easily without breaking. Ductility, a key property in materials science, signifies the capacity of a material to sustain plastic deformation under tensile stress. Contrary to ductile materials, antonyms in this context depict substances that are brittle and prone to fracturing when subjected to mechanical stress.
In the realm of metallurgy and material engineering, the antonyms of ductile are essential to understanding the structural integrity and performance limitations of various substances. Non-ductile materials often exhibit characteristics such as stiffness, rigidity, and a propensity to shatter rather than stretch under pressure. Recognizing the antonyms of ductile materials provides crucial insights into their applications, potential uses, and limitations in different industries.
By exploring the antonyms of ductile substances, scientists and engineers gain valuable insights into the mechanical properties and behavior of materials under different conditions. Understanding the limitations of non-ductile materials is pivotal in designing products and structures that require specific mechanical properties or resistance to deformation.
Example Sentences With Opposite of Ductile
| Antonym | Sentence with Ductile | Sentence with Antonym |
|---|---|---|
| Rigid | The metal wire was ductile and easily bent. | The iron bar was rigid, impossible to bend. |
| Inflexible | The dough was ductile, allowing for easy shaping. | The plastic was inflexible, resisting all attempts at shaping. |
| Hard | The clay was ductile and pliable in the artist’s hands. | The rock was hard and unyielding to pressure. |
| Stiff | The cotton fabric was ductile, flowing smoothly when touched. | The cardboard was stiff and rigid to the touch. |
| Brittle | Gold is known for being ductile while glass is brittle. | The glass shattered easily, showing its brittle nature. |
| Inelastic | Rubber bands are ductile while plastic is inelastic. | The plastic ruler didn’t stretch, revealing its inelastic quality. |
| Unyielding | The Copper wire was ductile and easily moldable. | The marble was unyielding, resisting any attempts to shape it. |
| Resistive | Aluminum foil is ductile, easily shaped for cooking. | The steel beam was resistive to any force applied to it. |
| Rigid | Clay can be ductile, easily manipulated by the potter. | The rubber material was rigid, unable to be reshaped. |
| Unpliable | Wax is ductile, ideal for molding into different shapes. | The concrete block was unpliable, impossible to change its form. |
| Stiff | The thread was ductile, smoothly bending through the needle. | The frozen rope was stiff, immovable and unyielding. |
| Brittle | Materials like copper are ductile while glass is brittle. | The glass jar broke easily, showing its brittle composition. |
| Inelastic | Rubber bands are ductile while plastic is inelastic. | The plastic remained inelastic, unable to stretch or change its shape. |
| Unbendable | The silver ring was ductile, easily adjusted to fit different sizes. | The steel rod was unbendable, firm and resistant to any change. |
| Non-Malleable | Gold is ductile and malleable, unlike iron which is non-malleable. | The iron bar was non-malleable, unable to be reshaped or molded. |
| Incompliant | Though aluminum is ductile, the adamantium was incompliant and refused to be bent. | The stainless steel was incompliant, resisting attempts to bend it. |
| Inexpansible | Copper is ductile, able to be stretched without breaking. | The balloon was inexpansible, unable to be inflated any further. |
| Stubborn | Although clay was ductile, capable of being molded, stone was stubborn and unyielding to change. | |
| Hardened | The mud was ductile, easily reshaped, while the concrete was hardened and unyielding. | |
| Rigid | The plasticine clay was ductile and easily squished. | The steel wire was rigid and didn’t bend at all. |
| Solid | The precious metal was ductile, shaping effortlessly. | The glass was solid and did not change its form. |
| Fixed | The chewing gum is ductile, stretches easily. | The metal clamp is fixed and cannot be bent. |
| Immalleable | The clay was ductile, easily moulded, unlike the brick which is immalleable. | |
| Stone-like | Dough is ductile and soft, quite different from the stone-like nature of marble. | |
| Unadaptable | The plastic is ductile, molding into different shapes. | The glass was unadaptable, unable to change from its original state. |
| Plastic | Materials like gold are ductile while some substances are plastic. | The ice was plastic, unyielding to efforts to reshape it. |
| Immutable | The wire was ductile and could be easily reshaped. | The concrete was immutable, refusing to change form. |
| Ungiving | The clay was ductile, yielding to the pressure applied. | The steel beam was ungiving, not responding to attempts to bend it. |
| Permanent | The clay was soft and ductile, easily reshaped. | The metal alloy was hard and permanent, unchanging in form. |
| Indestructible | While the thread was ductile, the diamond was indestructible. | The glass was indestructible, contrasting with the ductile nature of metal. |
| Unbreakable | Gold is known to be ductile while glass is considered unbreakable. | The diamond necklace was unbreakable, different from the ductile copper wire. |
| Iron-like | The silver wire was ductile, unlike the iron-like steel rod. | While the clay was ductile, the granite was iron-like. |
| Inflexible | The dough was ductile and could be molded easily. | The plastic sheet was inflexible, offering no give. |
| Enamel | Copper is ductile, can be stretched without breaking. | The enamel was hard as rock, lacking the ductile property. |
| Rigid | Rubber bands are ductile, stretchy, quite the opposite from rigid metals. | |
| Stone-like | The clay was ductile, allowing for easy molding. | The concrete was stone-like, unyielding to any change. |
More Example Sentences With Antonyms Of Ductile
| Antonym | Sentence with Ductile | Sentence with Antonym |
|---|---|---|
| Rigid | The metal was ductile and could be easily bent. | The material was rigid and unable to flex. |
| Inflexible | Copper is known for being ductile and malleable. | The plastic was inflexible and could not be shaped easily. |
| Stiff | The wire was so ductile that it could be twisted. | The board was stiff and did not bend at all. |
| Brittle | Unlike the ductile dough, the crackers were brittle. | The glass was brittle and broke easily. |
| Unyielding | The clay was ductile and easy to mold. | The rock was unyielding and impossible to shape. |
| Rigid | The rubber bands were ductile and easily stretched. | The metal bars were rigid and did not budge. |
| Fixed | The ductile fabric draped beautifully. | The cardboard was fixed and would not mold. |
| Hard | Gold is a ductile metal that can be drawn into wire. | The diamond was hard and could not be bent. |
| Tough | The leather was ductile and could be sewn easily. | The steak was tough and difficult to chew. |
| Inelastic | The ductile rubber band could stretch without breaking. | The metal chain was inelastic and did not stretch. |
| Stiff | The clay was ductile and could be shaped effortlessly. | The branches were stiff and did not move in the wind. |
| Rigid | The plastic was ductile and could be molded easily. | The steel was rigid and could not be reshaped. |
Outro
Antonyms of ductile, opposite of ductile and ductile ka opposite word are the same thing. In conclusion, the opposite of ductile, a word that describes a material’s ability to deform easily under stress without breaking, is brittle. A brittle material is one that breaks or shatters when subjected to force, lacking the flexibility and malleability that ductile materials possess. The distinction between ductile and brittle properties plays a crucial role in various fields such as material science, engineering, and construction.
Understanding the differences between ductile and brittle materials is essential in determining the appropriate materials to use in different applications. While ductile materials can withstand deformation and stretching, brittle materials are more prone to sudden failure under stress. By recognizing these contrasting characteristics, engineers and designers can make informed decisions to ensure the safety and longevity of structures and products. In essence, the opposite of ductile, brittleness, highlights the importance of material properties and their impact on the performance and reliability of various materials.