absorption curve的音標(biāo)是[?b?s??p??n kju??(r)]。

absorption curve的基本翻譯是吸收曲線。

速記技巧：可以記為“absorb吸收，curve曲線，吸收曲線”。

以上內(nèi)容僅供參考，建議使用權(quán)威的英語(yǔ)詞典進(jìn)行查詢。

Absorption curve的英文詞源：

Absorption curve這個(gè)詞源于拉丁語(yǔ)absorbere，意為“吸收”。

變化形式：在英語(yǔ)中，absorption curve的形式?jīng)]有發(fā)生改變。

相關(guān)單詞：

1. Absorbent - 意為“吸收性的”，來(lái)源于absorb，表示能夠吸收其他物質(zhì)的東西。例如，紙巾是一種absorbent material，可以吸收液體。

2. Absorption - 意為“吸收”，直接來(lái)源于absorption curve，表示將物質(zhì)吸收到體內(nèi)或物體中。例如，太陽(yáng)能電池板通過(guò)吸收太陽(yáng)光產(chǎn)生電能。

3. Absorptivity - 意為“吸收率”，來(lái)源于absorb和率（ivity），表示物體吸收光線的能力。例如，某些材料對(duì)光的吸收能力很強(qiáng)，而其他材料則較弱。

4. Absorption spectrum - 意為“吸收光譜”，來(lái)源于absorb和spectrum（光譜），表示物體對(duì)特定波長(zhǎng)的光吸收的特性曲線。例如，某些物質(zhì)在特定波長(zhǎng)下會(huì)產(chǎn)生顏色變化，這可以用來(lái)檢測(cè)該物質(zhì)的存在。

5. Absorptivity - 意為“吸收系數(shù)”，來(lái)源于absorb和coefficient（系數(shù)），表示物體吸收光線的物理量。例如，在光學(xué)實(shí)驗(yàn)中，可以使用吸收系數(shù)來(lái)描述材料對(duì)光的吸收能力。

總之，absorption curve這個(gè)詞源于拉丁語(yǔ)absorbere，表示物體吸收物質(zhì)或光線的特性曲線。它與吸收相關(guān)的詞匯有很多，這些詞匯在科學(xué)和工程領(lǐng)域中有著廣泛的應(yīng)用。

Absorption curve

1. absorption coefficient

2. absorption spectrum

3. absorption rate

4. absorption coefficient curve

5. absorption curve analysis

6. absorption curve graph

7. absorption curve measurement

例句：

1. The absorption spectrum of the chemical compound is unique and can be used to identify it.

2. The absorption rate of light varies with the wavelength and intensity of the light source.

3. The absorption coefficient curve is a plot of the amount of light absorbed as a function of wavelength.

4. The absorption curve analysis is used to determine the chemical composition of the sample.

5. The absorption curve graph is a visual representation of the absorption process.

6. The absorption curve measurement is used to determine the amount of light absorbed by a substance.

英文小作文：

Absorption Curve and Its Application

Absorption curve is a plot of the amount of energy absorbed by a substance as a function of the wavelength of incident radiation. This curve is widely used in various fields, including spectroscopy, photochemistry, and solar energy harvesting.

In spectroscopy, absorption curve analysis is used to identify the chemical composition of a sample by examining the wavelengths at which it absorbs radiation. This technique is commonly used in laboratory settings to analyze the composition of gases and liquids, as well as in environmental monitoring to detect pollutants in the air and water.

In photochemistry, absorption curve measurement is used to study the reaction mechanism of photo-induced processes, such as photolysis and photocatalysis. By monitoring the changes in the absorption spectrum of a sample during a reaction, scientists can gain insights into the reaction pathway and rate-limiting steps.

Finally, absorption curve is also used in solar energy harvesting to design efficient solar cells and solar panels. By measuring the absorption spectrum of a material, designers can determine its ability to absorb sunlight and convert it into electricity. This information is crucial in optimizing the performance of solar cells and reducing their cost.

In conclusion, absorption curve plays an essential role in various fields and has opened up new avenues for research and development in areas such as energy conversion, environmental monitoring, and chemical analysis.