GCE AS/A level 1211/01 GEOLOGY GL1 Foundation Unit

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Surname Centre Number Candidate Number Other Names 2 GCE AS/A level 1211/01 GEOLOGY GL1 Foundation Unit S15-1211-01 A.M. MONDAY, 11 May 2015 1 hour For s use Question Maximum Mark 1. 15 2. 14 Mark Awarded 1211 010001 3. 15 4. 16 Total 60 ADDITIONAL MATERIALS In addition to this examination paper, you will need: the Mineral Data Sheet; a calculator. INSTRUCTIONS TO CANDIDATES Use black ink or black ball-point pen. Write your name, centre number and candidate number in the spaces at the top of this page. Answer all questions in the spaces provided in this booklet. INFORMATION FOR CANDIDATES The number of marks is given in brackets at the end of each question or part-question. You are reminded that marking will take into account the use of examples and the quality of communication used in your answers. VP*(S15-1211-01)

2 Answer all questions. 1. Figure 1a is a map showing an igneous rock intruded into orthoquartzite. Table 1b shows how the average crystal size varies between A and B on Figure 1a. 0 100 N D metres Orthoquartzite A Igneous body Limit of metamorphism C B Figure 1a Distance from A (metres) 0 50 100 150 200 250 Crystal size (millimetres) 0.5 5 6 7 7.5 8 Table 1b 10 8 Crystal size (millimetres) 6 4 2 0 0 50 100 150 200 250 Distance from A (metres) Figure 1c

3 (a) Refer to Figure 1a and Table 1b. (i) Complete the graph in Figure 1c by plotting the data in Table 1b and joining up the points with a curved line. [2] (ii) Explain the variation in crystal size between locations A and B in Figure 1a. [2] (b) Figure 1d shows a specimen from the igneous intrusion shown in Figure 1a. The specimen was collected at location B on Figure 1a. creamy white plagioclase feldspar mineral F, dark green in colour, 2 good cleavages at 90 1211 010003 0 10 mm Figure 1d (i) Using the Mineral Data Sheet, identify mineral F. [1] (ii) Which three terms below best describe the igneous rock shown in Figure 1d? Tick three boxes. [2] foliated porphyritic mafic equigranular crystalline silicic (iii) Name the igneous rock shown in Figure 1d. [1] Turn over.

4 (c) (i) Complete Figure 1e below to show the texture of a sample of metaquartzite with a mean crystal size of 1.5 mm representative of location C on Figure 1a. [3] 0 1 mm Figure 1e (ii) Compare the mineral composition and texture of the rocks found at locations C and D on Figure 1a. Explain your answers. [4] Mineral composition... Texture... 15

5 1211 010005 BLANK PAGE Turn over.

6 2. Figure 2 shows a roadside rock exposure with the fossils and structures contained in each of the sedimentary units. graptolite C 1 sandstone (not to scale) sandstone (not to scale) shale shale shale P limestone Q 1 1 0.5 graptolite B graptolite A Carboniferous coral Figure 2 Refer to Figure 2. (a) (i) Name the morphological features of graptolite B labelled P and Q. [2] P... Q... (ii) Describe two differences in the morphological features of graptolites A and C. [2]

7 (b) (i) The graptolites in Figure 2 have been replaced by a brass yellow coloured mineral with a metallic lustre. Using the Mineral Data Sheet, identify the mineral most likely to have replaced the original organic matter of the graptolites. [1] (ii) All the graptolite fossils shown in Figure 2 are casts. Describe the geological processes that have led to this type of preservation. [3] (iii) Graptolites are considered to be useful zone fossils in relative dating and correlation in the Palaeozoic. Using Figure 2 and your knowledge, describe three factors that enable graptolites to be useful as zone fossils. [3] (c) The strata in Figure 2 are overturned. Explain the reasons that would support this statement. [3] 14 Turn over.

8 3. Figure 3a shows an ocean ridge with a simplified pattern of magnetic reversals in the rocks of the oceanic crust. Figure 3b shows the actual pattern of magnetic reversals in the oceanic crust of the Atlantic Ocean and Figure 3c shows the time scale for magnetic reversals in the oceanic crust over the last 4.5 million years. normal polarity ocean ridge reversed polarity Figure 3a 0 10 5 0 5 10 million years Time (millions of years) 1 2 3 4 normal reversed Figure 3b Figure 3c (a) (i) Name the type of plate margin shown in Figure 3a. Tick one box. [1] convergent conservative divergent

9 (ii) Describe the pattern shown by the magnetic reversals in Figure 3a. [2] (iii) Explain how a record of the Earth s magnetic field may be preserved in the igneous rocks of the ocean floor. [3] (iv) Explain the age distribution of the rocks of the oceanic crust shown in Figure 3b. [3] (b) (i) With reference to Figure 3c state how long the current period of normal polarity has lasted. [1] (ii) Using Figure 3c state how many magnetic reversals have occurred during the last 2 million years. Calculate the mean time between magnetic reversals in years. [2] Number of reversals Mean time between reversals years (iii) Refer to Figure 3b and suggest two reasons to explain why the actual pattern of magnetic reversals on the sea floor is more complex than the simplified model shown in Figure 3a. [3] 15 Turn over.

10 4. Figure 4 is a geological map. The land in the area is flat. N F1 F2 dip of beds youngest oldest F1 60 F2 sea 0 50 metres fault F1 dips at 18 towards the south west fault F2 is vertical Figure 4 (a) (i) Refer to Figure 4. State which two of the following statements are correct. Tick two boxes. [2] The fold is an anticline The fold has limbs of equal dips The fold is a syncline The fold is younger than the faults The fold has been overturned The northern limb of the fold dips at less than 60 (ii) Draw in the axial plane trace of the fold to the east of fault F1 on Figure 4. [2]

11 (b) (i) Fault F1 involves vertical movement with a downthrow to the east. State the evidence from Figure 4 for F1 being downthrown to the east. [2] Evidence... (ii) F1 is a thrust fault. State the evidence for this from Figure 4. [2] Evidence... (c) (i) Fault F2 shows strike-slip movement (horizontal displacement). Describe one piece of evidence from Figure 4 to support this statement. [2] (ii) Measure the amount of horizontal displacement that has occurred along fault F2 in metres and state whether the movement has been to the left or right. [2] Displacement... metres Movement to the... (d) A student came to the following conclusions about the geological structures shown in Figure 4. State whether or not you agree with each conclusion and give reasons for your answers. [4] The fold and fault F1 were formed at the same time and by the same type of stress F2 is younger than F1... END OF PAPER 16

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