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act | science | physical_science | A molten alloy (a mixture of 2 or more metallic ele-ments) can be poured into a cylindrical mold and cooled to form an ingot. Crystals form inside the ingot as it cools.The average crystal length, L, in micrometers (μm), deter-mines how brittle the ingot will be. A method for reducing L using rotating magnetic fields w... | Figure 1 shows the effect of the relative magnetic stirring force, F, on L for ingots formed from molten Alloy Q that had an initial temperature of either 280°C or 550°C. | Table 1 shows the elemental compo-sition of Alloy Q. | <table><tr><td colspan="3">Table 1</td></tr><tr><td>Element</td><td>Symbol</td><td>Percent by mass in Alloy Q</td></tr><tr><td>Aluminum</td><td>Al</td><td>88.7</td></tr><tr><td>Silicon</td><td>Si</td><td>10.8</td></tr><tr><td>Manganese</td><td>Mn</td><td>0.28</td></tr><tr><td>Magnesium</td><td>Mg</td><td>0.22</td></tr>... | A linear region of a graph is a range of data that can be approximated with a straight line. Based on Figure 1, for Alloy Q initially at a temperature of $550^{\circ}\mathrm{C}$, which of the following ranges of $F$ best represents a linear region? | {'A': 'Between 0 and $10\\times 10^{7}$', 'B': 'Between $10\\times 10^{7}$ and $20\\times 10^{7}$', 'C': 'Between $20\\times 10^{7}$ and $30\\times 10^{7}$', 'D': 'Between $30\\times 10^{7}$ and $40\\times 10^{7}$'} | D | Between $30\times 10^{7}$ and $40\times 10^{7}$ | |
act | science | physical_science | A molten alloy (a mixture of 2 or more metallic ele-ments) can be poured into a cylindrical mold and cooled to form an ingot. Crystals form inside the ingot as it cools.The average crystal length, L, in micrometers (μm), deter-mines how brittle the ingot will be. A method for reducing L using rotating magnetic fields w... | Figure 1 shows the effect of the relative magnetic stirring force, F, on L for ingots formed from molten Alloy Q that had an initial temperature of either 280°C or 550°C. | Table 1 shows the elemental compo-sition of Alloy Q. | <table><tr><td colspan="3">Table 1</td></tr><tr><td>Element</td><td>Symbol</td><td>Percent by mass in Alloy Q</td></tr><tr><td>Aluminum</td><td>Al</td><td>88.7</td></tr><tr><td>Silicon</td><td>Si</td><td>10.8</td></tr><tr><td>Manganese</td><td>Mn</td><td>0.28</td></tr><tr><td>Magnesium</td><td>Mg</td><td>0.22</td></tr>... | Consider the 2 trends shown for Alloy Q initially at the temperatures of $280^{\circ}\mathrm{C}$ and $550^{\circ}\mathrm{C}$, from $F = 40\times 10^{7}$ through $F = 48\times 10^{7}$. If these lines were to continue along the same trend, at which of the following values of $F$ would the average crystal lengths most lik... | {'A': '$F = 50\\times 10^{7}$', 'B': '$F = 60\\times 10^{7}$', 'C': '$F = 70\\times 10^{7}$', 'D': '$F = 80\\times 10^{7}$'} | B | $F = 60\times 10^{7}$ | |
act | science | physical_science | A molten alloy (a mixture of 2 or more metallic ele-ments) can be poured into a cylindrical mold and cooled to form an ingot. Crystals form inside the ingot as it cools.The average crystal length, L, in micrometers (μm), deter-mines how brittle the ingot will be. A method for reducing L using rotating magnetic fields w... | Figure 1 shows the effect of the relative magnetic stirring force, F, on L for ingots formed from molten Alloy Q that had an initial temperature of either 280°C or 550°C. | Table 1 shows the elemental compo-sition of Alloy Q. | <table><tr><td colspan="3">Table 1</td></tr><tr><td>Element</td><td>Symbol</td><td>Percent by mass in Alloy Q</td></tr><tr><td>Aluminum</td><td>Al</td><td>88.7</td></tr><tr><td>Silicon</td><td>Si</td><td>10.8</td></tr><tr><td>Manganese</td><td>Mn</td><td>0.28</td></tr><tr><td>Magnesium</td><td>Mg</td><td>0.22</td></tr>... | Based on Figure 1, which of the following combinations of values for initial temperature and $F$ would produce the shortest average crystal length in an ingot of Alloy Q? The smallest $\bar{L}$ would be produced with a temperature of: | {'A': '$280^{\\circ}\\mathrm{C}$ and $F = 10\\times 10^{7}$', 'B': '$280^{\\circ}\\mathrm{C}$ and $F = 40\\times 10^{7}$', 'C': '$550^{\\circ}\\mathrm{C}$ and $F = 10\\times 10^{7}$', 'D': '$550^{\\circ}\\mathrm{C}$ and $F = 40\\times 10^{7}$'} | D | $550^{\circ}\mathrm{C}$ and $F = 40\times 10^{7}$ | |
act | science | physical_science | A molten alloy (a mixture of 2 or more metallic ele-ments) can be poured into a cylindrical mold and cooled to form an ingot. Crystals form inside the ingot as it cools.The average crystal length, L, in micrometers (μm), deter-mines how brittle the ingot will be. A method for reducing L using rotating magnetic fields w... | Figure 1 shows the effect of the relative magnetic stirring force, F, on L for ingots formed from molten Alloy Q that had an initial temperature of either 280°C or 550°C. | Table 1 shows the elemental compo-sition of Alloy Q. | <table><tr><td colspan="3">Table 1</td></tr><tr><td>Element</td><td>Symbol</td><td>Percent by mass in Alloy Q</td></tr><tr><td>Aluminum</td><td>Al</td><td>88.7</td></tr><tr><td>Silicon</td><td>Si</td><td>10.8</td></tr><tr><td>Manganese</td><td>Mn</td><td>0.28</td></tr><tr><td>Magnesium</td><td>Mg</td><td>0.22</td></tr>... | The following table lists the mass of silicon in $50 \mathrm{g}$ samples of 4 different alloys, one of which is Alloy Q. Given the composition of Alloy Q, which sample is most likely Alloy Q? | {'A': 'Sample W', 'B': 'Sample X', 'C': 'Sample Y', 'D': 'Sample Z'} | D | Sample Z | |
act | science | physical_science | A molten alloy (a mixture of 2 or more metallic ele-ments) can be poured into a cylindrical mold and cooled to form an ingot. Crystals form inside the ingot as it cools.The average crystal length, L, in micrometers (μm), deter-mines how brittle the ingot will be. A method for reducing L using rotating magnetic fields w... | Figure 1 shows the effect of the relative magnetic stirring force, F, on L for ingots formed from molten Alloy Q that had an initial temperature of either 280°C or 550°C. | Table 1 shows the elemental compo-sition of Alloy Q. | <table><tr><td colspan="3">Table 1</td></tr><tr><td>Element</td><td>Symbol</td><td>Percent by mass in Alloy Q</td></tr><tr><td>Aluminum</td><td>Al</td><td>88.7</td></tr><tr><td>Silicon</td><td>Si</td><td>10.8</td></tr><tr><td>Manganese</td><td>Mn</td><td>0.28</td></tr><tr><td>Magnesium</td><td>Mg</td><td>0.22</td></tr>... | Based on Table 1, if an ingot of Alloy Q had a mass of $200 \mathrm{g}$, that ingot would contain what mass of $\mathrm{Mg}$? | {'A': '$0.22 \\mathrm{g}$', 'B': '$0.44 \\mathrm{g}$', 'C': '$2.2 \\mathrm{g}$', 'D': '$4.4 \\mathrm{g}$'} | B | $0.44 \mathrm{g}$ |
Trial Dataset (VQA)
This dataset contains various configurations for Visual Question Answering (VQA) tasks involving tables, figures, and multiple-choice options.
Dataset Structure
The dataset is split into multiple configurations based on the complexity of the input (number of tables/figures) and the response type (MCQ or Constructed Response).
How to Load
You can load any specific configuration using the datasets library:
from datasets import load_dataset
# Example: Load the 4-option MCQ configuration
dataset = load_dataset("Krishna5T/trial_dataset", "mcq_4options")
print(dataset["train"][0])
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