- •Reading Material Text a
- •Before reading the text try to discuss the following questions.
- •Now read the text, translate it and get ready to do the exercises after the text. Geography
- •Word Study
- •Comprehension and Discussion
- •Origin and development of geography. Early history
- •Geographic methods. Map location and measurement
- •The Round Earth on Flat Paper
- •Dialogue
- •Listening Comprehension Text “Geography”
- •Revision
- •What is science?
- •Становление географии как науки
- •Active Vocabulary
- •Additional Reading Geography and people: Ptolemy
- •Components of maps
- •Maps and graphs Maps
- •Isoline maps
- •Choropleth
- •Topological maps
- •Proportional flow maps
- •Dot maps
- •Line graphs
- •Scattergraphs
- •Pie charts
- •Reading Material Text a
- •The History of Exploration
- •Word Study
- •Comprehension and Discussion
- •Captain Cook
- •Text c The Mystery of the Franklin Expedition
- •Text d
- •The History of Maps
- •Dialogue
- •Listening Comprehension Text “Christopher Columbus”
- •Revision
- •Questions:
- •II. Первое русское кругосветное путешествие
- •Active Vocabulary
- •Additional Reading Famous Russian navigators
- •Navigation Tools
- •Unit III
- •Reading Material Text a
- •Before we start reading let’s recollect the composition of the solar system.
- •What does the solar system consist of?
- •What heavenly object is the most beautiful (mysterious, important)?
- •The Universe and the Solar System
- •Word Study
- •Comprehension and Discussion
- •Our local star
- •Text c The Evolution of the Universe
- •Text d Galaxies
- •Dialogue
- •Is the Sun Good or Bad for Us?
- •Is the sun good or bad for us?
- •Listening Comprehension Text “Stars”
- •Fill in the gaps.
- •Note down the temperature of:
- •Note down the colours of :
- •Revision
- •The Lunar Surface
- •Active Vocabulary
- •Additional Reading The Planets
- •Mercury
- •Jupiter
- •Uranus and Neptune
- •Stellar Evolution
- •Unit IV
- •Reading Material Text a
- •Before reading the passage discuss these points with a partner.
- •Is the earth a perfect sphere?
- •This Earth of Ours
- •Word Study
- •Comprehension and Discussion
- •Volcanic Eruptions
- •Text c The Earth. Size. Shape.
- •Text d The Earth
- •Dialogue Discussing the age of the earth
- •Listening Comprehension Text “The Earth’s shape”
- •1. What is the “equatorial bulge”?
- •2. Are all three models only approximations?
- •Revision
- •History of the Earth
- •Latitude and Longitude
- •Active Vocabulary
- •Additional Reading Yellowstone National Park
- •The geological setting
- •Hydrothermal features
- •Reading Material Text a
- •The Atmosphere: Properties and composition
- •Word Study
- •Comprehension and Discussion
- •Oxygen-Carbon Dioxide Cycle
- •The Ozone Layer
- •The Ionosphere
- •Dialogue
- •Listening Comprehension Text “The Atmosphere”
- •Part b. Listening activities
- •Revision
- •Air pollution
- •Active Vocabulary
- •Additional Texts Greenhouse gases
- •The air we breathe
- •Unit VI
- •Reading Material Text a
- •Before reading the text discuss these points with a partner.
- •Now read the text, translate it and get ready to do the exercises after the text. Climate
- •Word study
- •Climate
- •Comprehension and Discussion
- •The climate of the uk
- •The World’s Inconstant Climate
- •Methods of weather modification
- •Weather
- •Days of Abnormal Weather
- •Vocabulary
- •Days of Abnormal Weather Text 1
- •Interpretation
- •Weather Forecast
- •Listening Comprehension Text “The Climate”
- •Revision
- •Climate
- •Weather maps
- •Project Writing
- •Active Vocabulary
- •Additional Reading Climatic Change
- •Origin of Climatic Change
- •Ocean Currents
- •Unit VII
- •Reading Material Text a
- •Before reading the passage discuss these points with a partner.
- •Into how many parts is the earth’s surface divided?
- •How are land and sea distributed?
- •Now read the text, translate it and get ready to do the exercises after the text. Land Forms of the Earth
- •Word Study
- •The Alps
- •Comprehension and Discussion
- •The Surface of the Ground
- •Continental Drift
- •Wegener’s Theory
- •Text d The Soil Beneath our Feet
- •Dialogue Discussing the process of erosion
- •Listening Comprehension Text “Continental drift”
- •Fill in the gaps.
- •Note down the terms used by the lecturer.
- •Note down the thickness of the asthenosphere.
- •Revision
- •Relief form of the earth
- •Earthquake waves
- •Earthquakes
- •Active Vocabulary
- •Additional Reading Erosion
- •Weathering
- •1999 A bad year for earthquakes
- •Limestone in Europe
- •Vulcanism
- •Volcanic Eruptions
- •Glaciers
- •Minerals
- •What Minerals Are
- •Mineral Properties
- •The Earth’s Interior
- •Interior Structure
- •Rock Classification
- •Igneous Rocks
- •Sedimentary Rocks
- •Grammar focus the system of tenses
- •Charles Robert Darwin
- •Passive voice
- •The Greenhouse Effect
- •Participle
- •The gerund
- •Функции герундия в предложении и способы его перевода на русский язык
- •Infinitive
- •I. Образование
- •II. Функции инфинитива в предложении.
- •Complex Object
- •Complex Subject
- •Subjunctive mood
- •Subjunctive Mood Conditional Sentences
- •Modal verbs
- •(Выражение «вероятности», «предположения»)
- •The system of tenses
- •Charles Robert Darwin
Origin of Climatic Change
What causes climates to change? So many different factors influence climate that there is no shortage of possible explanations. One train of thought blames mankind for the temperature fluctuations of Fig. 5.13. The initial temperature rise is attributed to an increase in the carbon dioxide content of the atmosphere. Both the biologic and oceanic cycles are, on the average, balanced in their consumption and production of carbon dioxide. But there are also sources of carbon dioxide that have no absorption processes to counter their effects. The most significant of these sources is the burning of coal and
oil by man to produce heat for dwellings and mechanical energy for industry and transportation. At present our chimneys and exhaust pipes pour about 12 billion tons of carbon dioxide each year into the atmosphere, and this rate is rapidly increasing. Since 1880 the carbon dioxide content of the atmosphere has gone up by 12 percent (Fig. 5.14). Despite the relatively small proportion of carbon dioxide in the atmosphere—only 330 parts per million—it is a most significant constituent because of its ability to absorb solar energy reradiated by the earth and thus to contribute to the greenhouse effect that provides energy to the atmosphere.
The cooling of the atmosphere since 1945 must have a different explanation since the carbon dioxide content has continued to increase. The culprit here is thought by some scientists to be dust at high altitudes which scatters a portion of the incoming sunlight back into space. The chief natural source of airborne dust is volcanic eruptions. Man's contribution comes from the chimneys of industry, large-scale burning of tropical forests to clear land for agriculture, and soil particles blown away during mechanical cultivation. There is no question that a sufficiently large increase in atmospheric dust would lead to the observed general cooling of the atmosphere—but just how large an increase is needed and whether it has in fact occurred are not known, nor are the relative importances of the different dust sources.
Another point of view attributes climatic change to variations in the solar energy arriving at the top of the atmosphere, not to events within the atmosphere. (Of course, the carbon dioxide and dust contents of the atmosphere play a role in climate: the issue is which influences are primary and which are secondary.) The sun's radiation is not constant but fluctuates through the 11-year sunspot cycle, and a number of weather phenomena apparently follow a similar cycle. Perhaps there are long-term variations in solar output as well. Also, periodic changes in the earth's orbit bring it exceptionally close to and far from the sun from time to time. But does the radiation reaching the earth vary enough when this happens to produce the drastic climatic changes known to have taken place in the past, notably the ice ages? The puzzle of climatic change remains one of the most challenging in earth science.