- •Л.П. Маркушевская, с.В. Шенцова, е.В. Соколова optics:
- •Contents
- •The History of Optics
- •Understanding a printed text
- •Comprehensive reading The History of Optics
- •Check your understanding
- •Exercise 2. Complete the sentences:
- •Increase your vocabulary
- •Chapter I Classical (Geometrical) Optics
- •Comprehensive reading From the History of Geometrical Optics
- •Check your understanding Exercise 1. True or false?
- •Exercise 2. Choose the correct answer.
- •Increase your vocabulary
- •A virtual image …
- •Language activity
- •Unit 2 word-study
- •Understanding a printed text
- •Reading for precise information Nature of Light and Color
- •Laws of reflection:
- •Laws of refraction:
- •Check your understanding
- •3 Laws
- •Increase your vocabulary
- •Language activity
- •Unit 3 word-study
- •Understanding a printed text
- •Scan-reading Optical Instruments
- •Check your understanding
- •Increase your vocabulary
- •Language activity
- •Exercise 4. Summarize your knowledge of Past Simple or Past Continuous. Choose the correct tense.
- •Unit 4 word study
- •Understanding a printed text List of Terms:
- •Reading and translating the text Lenses
- •Check your understanding
- •Increase your vocabulary
- •Language activity
- •Unit 5 word study
- •Understanding a printed text List of Terms:
- •Read the text and entitle it
- •Check your understanding
- •Increase your vocabulary
- •Language acitivity
- •Review of the chapter I
- •Supplementary tasks
- •Improve your translation practice task 1
- •The History of the Telescope
- •Exercise 1. Rearrange the sentences in the chronological order.
- •Holography
- •Illumination, never remove protective cover from the
- •Астрономические наблюдения объектов в широком диапазоне длин волн
- •Chapter II Fiber Optics Unit 1
- •Comprehensive reading The History of Fiber Optics
- •Check your understanding Exercise 1. Answer the following questions.
- •Increase your vocabulary Exercise 1. Compare the two columns and find Russian equivalents.
- •Exercise 2. Match the antonyms.
- •Language activity Exercise 1. Summarize your knowledge of Passive Constructions and translate the following sentences.
- •Fiber Optic Systems
- •Fiber Optic Technology
- •Check your understanding
- •Exercise 2. Complete the sentences with words from the text.
- •Increase your vocabulary
- •Language activity
- •Unit 3 word-study
- •Understanding a printed text
- •Reading and translating the text
- •Check your understanding Exercise 1. Which title better suits the text?
- •Increase your vocabulary
- •Language activity
- •Exercise 2. Which of the italicized words in each sentence is the predicate?
- •Unit 4 word study
- •Read – reread;
- •Understanding a printed text
- •Comprehensive reading Optical Fiber Applications
- •Check your understanding
- •Increase your vocabulary
- •Language activity
- •Rewiew of the chapter II
- •Supplementary tasks
- •Improve your translation practice task 1
- •Fiber Optic Economics
- •Exercise 1. Answer the questions.
- •Exercise 2. Translate the following parentheses into Russian.
- •How Optical Fibers Work
- •Chapter III
- •Word study
- •Understanding a printed text
- •Amplifier – усилитель
- •Reading for discussion Maser-Laser History
- •Check your understanding
- •Increase your vocabulary
- •Language activity
- •Unit 2 word study
- •Understanding a printed text
- •Reading for precise information Types of Lasers
- •Solid-State Lasers
- •Gas Lasers
- •Semiconductor Lasers
- •Free-Electron Lasers
- •Liquid Lasers (Dye Lasers)
- •Chemical Lasers
- •Check your understanding
- •Increase your vocabulary
- •Language activity
- •Comprehensive reading Solid - State Lasers
- •Semiconductor Lasers
- •Check your understanding
- •Increase your vocabulary
- •Adjectives
- •Language activity
- •Unit 4 word-study
- •Understanding a printed text
- •Comprehensive reading Gas and Molecular Lasers Gas Lasers
- •Fig.1. Construction of He-Ne laser
- •Molecular Lasers
- •Check your understanding
- •Increase your vocabulary
- •Language activity
- •Exercise 3. Summarize your knowledge on non-Finite forms. Define the form of the underlined words (Infinitive, Participle - I, Participle - II, Gerund). Translate the sentences.
- •Unit 5 word study
- •Verb – noun
- •Understanding a printed text
- •Scan-reading Laser Applications
- •Industry
- •Scientific Research
- •Communication
- •Medicine
- •Military Technology
- •Laser Safety
- •Check your understanding
- •Increase your vocabulary
- •Exercise 2. Translate the following word combinations with Participle II as an attribute.
- •Language activity
- •Exercise 3. Cross out “that”, “who”, “which”, “when” if one can manage without them. Underline the subject in the second sentence.
- •Supplementery tasks
- •Improve your translation practice
- •Лазерная сварка
- •Лазеры в медицине
- •How a Laser Works The Basics of an Atom
- •The Connection Between Atoms and Lasers
- •Understanding a printed text
- •Lasers in Communication
- •Laser Uses
- •Appendix I Химические формулы
- •Appendix II
- •Appendix III Business Communication
- •I. Introduction. Writing and Speaking – Your Keys to Business Success.
- •II. The job campaign
- •Working Experience
- •Curriculum vitae
- •Education
- •III. Business letters
- •I. Introducing your firm (the body the message of a letter).
- •II. Official Invitations
- •III. Request
- •IV. Claim, protest!
- •V. Gratitude, thanks.
- •VI. Regret, apology
- •Supplementary reading appendix IV Albert Einstein
- •Arthur l. Schawlow
- •Charles h. Townes
- •Aleksandr m. Prokhorov
- •Nicolay g. Basov
- •Ted Maiman and the world's first laser
- •Dictionary
- •Haze, n – туман, дымка
- •Observe, V – наблюдать
- •Optics, n – оптика, оптические приборы
- •Literature
Chapter III
Lasers
Unit 1
Word study
Exercise 1. Check the transcription in the dictionary and read the words listed below.
Nouns
acronym, amplifier, characteristic, existence, emission, frequency, microwave,
mixture, recognition, technique, technology, width.
Verbs
award, extend, patent, pertain, recognize, require.
Adjective
dynamic, molecular, monochromatic, notable, quantitative, relevant,
simultaneous.
Exercise 2. Read and translate the following international words.
Fundamental, emission, experimentation, intensity, monochromatic, radiation, recombination, technology.
Understanding a printed text
List of Terms:
Amplifier – усилитель
cavity dimensions – размеры резонатора
continuous wave (CW) – незатухающая волна
energy level – энергетический уровень
FEL=free electron laser – лазер на свободных электронах
forbidden transition – запрещенный переход
high-resolution microwave spectrometer – спектрометр с высокой разрешающей
способностью
line width – ширина линии
long-lived energy state – устойчивые энергетические состояние
molecular beam – молекулярный пучок
neodymium-doped glass laser – лазер на стекле с примесью неодима(ND)
optical frequency range – диапазон оптических частот
oscillator – осциллятор, генератор
pink ruby medium – лазерная активная среда на розовом рубине
population inversion – инверсия заселенности энергетических уровней
semiconductor junction laser – диодный полупроводниковый лазер
spontaneous emission – спонтанное излучение
stimulated emission – вынужденное излучение
time delay – временная задержка
wavelength – длина волны
Reading for discussion Maser-Laser History
The devices known as masers and lasers serve as amplifiers and generators of radiation. Their common characteristic is that they make use of the conversion of atomic or molecular energy to electromagnetic radiation by means of the process known as stimulated emission of radiation. When the wavelength of the emitted radiation is in the vicinity of 1 cm we speak of microwave amplifiers or masers. Instruments which generate or amplify visible or nearly visible radiation are called optical masers or lasers.
Albert Einstein recognized the existence of stimulated emission in 1917, but it was not until the 1950s when the first device was demonstrated.
The maser period begins with the publication of an article by the Russian scientists Basov and Prokhorov and the construction of the first operating maser by Townes, Gordon and Zeiger (from the USA). Basov and Prokhorov gave a detailed theoretical exploration of the use of molecular beams in microwave spectroscopy. The article of Basov and Prokhorov contained detailed calculations pertaining to the role of the relevant physical parameters, the effects of line-width, cavity dimensions, and the like. Thus the quantitative conditions for the operation of a microwave amplifier and generator were found.
In 1954 at Columbia University Charles Townes and two of his students announced the construction and operation of a device that may be used as a high-resolution microwave spectrometer, a microwave amplification, or a very stable oscillator. They named the device a “maser” – an acronym for microwave application by stimulated emission of radiation.
From 1958 on, many masers were constructed for applications in radio astronomy and as components of radar receivers. These masers were mostly of the ruby type. Their design became a part of the engineering art and research interest turned toward the extension of stimulated emission techniques in the visible and infrared regions.
Arthur Schawlow of Bell Laboratories and Charles Townes proposed extending the maser concept to the optical frequency range in 1958.
The maser period extends from 1954 to 1960.
The laser period opens with the achievement of the ruby laser. The acronym l.a.s.e.r. stands for light amplification by stimulated emission of radiation.
Physicist Theodore Harold Maiman invented the first operable laser in 1960. He developed, demonstrated, and patented a laser using a pink ruby medium, for which he gained worldwide recognition. In 1962 Maiman founded his own company, Korad Corporation, devoted to the research, development, and manufacture of lasers.
Early in 1961 the first continuously operating laser was announced by Ali Javan and his coworkers at Bell Laboratories. This laser was the first to use a gas, a mixture of helium and neon, for the light emitting material. At the same years scientists from American Optical Company made the first neodymium-doped glass laser. In 1962 scientists at General Electric and International Business Machines (IBM) almost simultaneously demonstrated the first semiconductor junction laser.
In 1962 Basov and Oraevskii proposed that rapid cooling could produce population inversions in molecular systems. And in 1966, the first gas-dynamic laser was successfully operated at the Avco Everett Research Laboratory.
The 1970s years became the time of discovery of free electron laser.
The 1964 Nobel Prize in physics was awarded to Charles Townes and to the Russian scientists Nikolai Basov and Alexander Prokhorov “for fundamental work in the field of quantum electronics, which has led to the construction of oscillators and amplifiers based in the maser-laser principle”.
Laser applications have also increased in variety. Experiments requiring really high intensities in narrow spectral regions can only be done with lasers. Outside the field of scientific experimentation many applications were found in medicine, communications, geophysical and space exploration, military and metals technology. The potential importance of these applications continues to stimulate new developments in the laser field.
Now lasers are everywhere. In your computer CD-ROM, your CD рlaуег, at supermarket and in laser light shows. As far as technologies go, they have been one of the inventions most quickly absorbed into society.
The future of lasers is a promising one. Judging from the quick development of lasers in the past and continuing laser research, there does not appear to be a slowing of laser research in the near future. As time progresses, there will doubtless be new scientists with new ideas and new inventions.