3. The Growing Environment Flashcards

Question 1

Q

How do you calculate GDDs for Celsius and Fahrenheit (4)?

Answer

A

Subtract 10 for C, 50 for F (temp. below which vines can’t grow) from avg. mean temp of a month in the growing season.
Multiply this by no. of days in that month.
Make same calculation for each month in the growing season (April-October / October-April).
Add totals together to get GDD.

Question 2

Q

Why is it beneficial to encourage soil life/ecosystems in the vineyard?

Answer

A

Organisms such as earthworms/bacteria/fungi are essential for converting organic nutrient compounds found in manure/compost into inorganic ones, which is the form they must be in to be taken up and used by the vine.

Question 3

Q

Why does the importance of aspect and slope steepness increase at high latitudes (5)?

Answer

A

solar radiation hits the Earth at a lower angle at high latitudes.
the angle of the sun is lower in the spring/autumn than in the summer.
the slope increases the angle (closer to perpendicular) at which the sun hits the Earth’s surface = more intense heat+light
warmth can be a limiting factor at higher latitudes, so slope+aspect make a big difference as to what grapes can grow and how ripe they can get.
more warmth during the spring/autumn extend the growing season for vines grown on slopes that face the sun.

Question 4

Q

What is transpiration in plants?

Caused by?

What is an evapotranspiration rate?

How does the ET rate affect the vine’s need for water?

Answer

A

Transpiration is the drawing up of water by the vine from the soil, through the roots and the above-ground parts of the plant. This is caused by loss of water from leaf stomata.

The amount of transpiration from the vine, combined with the evaporation of water from soil surface (high ET rate means that more water is required to meet vine’s requirements)

Question 5

Q

What can an excess of Potassium lead to (2)?

A deficit (2)?

Answer

A

Excess K: hinders uptake of Magnesium, leading to lower yields and poor ripening. High K in grapes = buffering effect for acidity, raises pH and affects wine quality.

Defecit of K: low sugar accumulation in grapes, reduced yield + poor vine growth.

Question 6

Q

What factors define a Mediterranean climate (2)?

Give 2 examples:

Answer

A

Low annual differences between summer and winter temperatures
Annual rainfall happens in winter months, with dry summers
Ex. Napa Valley + Coonawarra

Question 7

Q

What are 5 different climate classifications?

Breifly describe how they work:

Answer

A

- Growing Degree Days; calculation of days per growing season that have suitable temperatures (50F +) for grape-growing.

- The Huglin Index; similar to GDD, but also takes into account mean and max. temperatures and increased day length at higher latitudes.

- Mean Temperature of the Warmest Month; aka MJT (Mean January/July Temperature), measures the mean temperature of the (thoretically) hottest month in the growing season (July for N. Hem. / Jan. for S. Hem.)

- Growing Season Temperature; uses mean temperatures of entire growing season, then divided into bands.

- Koppen’s Classification; consideration of temp. + rainfall patterns (Maritime / Mediterranean / Continental)

Question 8

Q

How does a region’s topography affect its soils (4)?

Answer

A

Slopes = greater surface run-off in vineyards, less penetration of water into soil and less water available for vine roots.
This is advantageous in regions w/high rainfall.
Run-off causes erosion of soil+leaching of nutrients.
Soil on slopes = usually thin due to erosion, limiting area over which vines can obtain water+nutrients.

Question 9

Q

How are winemakers / grapegrowers adjusting their practices in response to Climate Change (7)?

Answer

A

Vine growth cycle starts sooner / moves more quickly. Therefore, grapegrowers need to make decisions regarding when to harvest. Harvesting sooner helps to retain acidity but might prohibit ripeness of tannins/aroma compounds and color accumulation. Harvesting later will lessen these problems, but will result in wines with less acidity and more alcohol.
Acidification may be necessary.
Irrigation may be necessary.
Grapegrowers might need to switch out current varieties for those that are more suitable for a drier/warmer environment or late-ripening varietals.
New wine regions are emerging or gaining prominence, (e.g. England, Canada) which might increase investment.
Increased presence of sustainable practices (renewable energy, protection of environment.)
Adjustment of vineyard orientations (more north-facing in N. Hem, south-facing in S. Hem.)

Question 10

Q

What is continentality?

Which types of regions have high/low continentality?

Answer

A

A measure of the difference between the annual mean temperatures of the hottest and coldest months

usually inland regions = more continental

coastal regions = less continental

Question 11

Q

How does proximity to bodies of water affect solar radiation reflection (3)?

Answer

A

Vineyards can benefit from solar radiation reflecting off the water’s surface and onto the vines.

Amount of radiation depends on angle at which sun hits water; amount of reflection is greatest at high altitudes.

This is advantageous in cool climates that have limited sunshine, e.g. Mosel Valley.

Question 12

Q

What is believed to be the relationship btw/ night-time temperatures and aroma compounds (2)?

What is an exception to the general theory?

Answer

A

It is thought that warmer night temps = greater breakdown of methoxypyrazines, which is important in cool climates.

Cooler temps are associated w/retention of other compunds, e.g. rotundone.

Cold night temps (<15C / 59F) seem to be beneficial in some regions, e.g. Wachau, Austria, where many top sites have both cold days and nights.

Question 13

Q

What can an excess of Nitrogen lead to (3)?

A deficit (3)?

Which is better?

Answer

A

Excess nitrogen = excessive veg. growth (sugars diverted to shoots/leaves), less ripening, shading by canopy leading to fungal disease.

Defecit of nitrogen = reduced vigor + yellowing of leaves. Grapes that are low in N can impair yeasts during fermentation (N is a yeast nutrient), leading to stuck fermentation, reductive odors, caused by stressed yeasts.

Overall, restricted supply of N is better.

Question 14

Q

What’s a maritime climate (2)?

Give 2 examples:

Answer

A

Low annual differences between summer and winter temperatures
Rainfall spread out throughout year
e.g. Bordeaux / Mornington Peninsula, Australia

Question 15

Q

What is ENSO (2)?

Answer

A

El Nino-Southern Oscillation
A climatic cycle in the Pacific Ocean that significantly affects weather patterns of the surrounding areas.

Question 16

Q

How can El Niño negatively affect viticulture in North/South America, as well as Australia (3)?

Answer

A

High levels of rainfall + risk of hurricanes in S. America + California.

Rainfall can disrupt pollination+fruit set, lead to excessive water availability which = more vegetative growth, less ripening.

Australia = warmer temps + drought = vine stress + damage.

Question 17

Q

How do slopes/aspects affect grapes (3)?

Answer

A

Slopes facing the equator will receive more solar radiation than those facing away (S-facing for Northern Hem., N-facing for Southern Hem.)
Slopes facing east benefit from morning sunshine that can heat up atmosphere when air+soil temps are lowest (extends ripening hours, dries out canopy earlier to reduce fungal disease).
Slopes facing west may be too hot in afternoon (can be alleviated in areas with coastal breezes e.g. W. Australia).

Question 18

Q

How does proximity to large bodies of water moderate temperatures of grape-growing areas (5)?

Answer

A

Large bodies of water heat up and cool down slower than dry land
During the day, water and air above a body of water remain cool and lowers temperature of local area
Air above dry land heats up more quickly and this warm air rises
Cool air from above water is drawn to land to replace the warm air as it rises, resulting in cool, humid afternoon breezes
Opposite happens at night: water retains warmth absorbed during the day, land loses heat quickly = cooler summers + milder winters.

Question 19

Q

Given the cooler average temperatures in locations at higher latitudes, what helps the vine to produce enough sugar for ripening grapes (2)?

Answer

A

Locations at higher latitudes (i.e. further away from the equator) have longer daylight hours in the summer and shorter daylight hours in the winter.
This permits a longer duration of time over which photosynthesis can take place in the growing season.

Question 20

Q

Summarize the importance of temperature and its influence on FLOWERING and FRUIT SET (3):

Answer

A

Warm temps (>17C / 64F) promote uniform flowering.
Ideal temps for fruit set = 26-32C (79-90F).
Cold, damp conditions = problems for flowering/fruit set = reductions in yield + potential quality.

Question 21

Q

Give an example of a vineyard area in a cool-moderate region that benefits from its specific exposure, and then one from a warm-hot region as well:

Answer

A

Grand Cru sites in the Cote d’Or, Burgundy; the site is in a cool climate, but the south-east facing slopes receive enough sun exposure to fully ripen the grapes.
Cima Corgo in the Douro Valley; hot climate, so vines benefit from northern exposure, meaning that they receive less sunlight, retain acidity and avoid sunburn.

Question 22

Q

How can warmer conditions from climate change be beneficial for some regions (3)?

Answer

A

Increased quality+production potential in regions once thought to be too cool to ripen grapes (Canada / England).

Drier conditions = greater transpiration and promotes mild water stress, which can help ripening in regions that already experience plentiful rainfall.

Drier conditions = less risk of fungal disease

Question 23

Q

Describe how the soil in a vineyard can be composed of different layers (2):

Answer

A

Soil can be made of different layers formed at different periods of time, each w/its own texture, structure and characteristics.
Sediment in topsoil might be different from bedrock underneath, e.g. sediment may have been transported by water, winds, glaciers, gravity (valley floors receiving sediment from slopes).

Question 24

Q

How can having substantially larger or smaller yields in a given vintage affect a winery economically?

Answer

A

LESS yield: problematic for cash flow + customer relations (businesses and consumers may find replacement product, switch permanently).

MORE yield: winery may not have capacity for increased volume of fruit, finding routes to market/customers for all wine (at a profit) may prove difficult.

Question 25

Q

How does altitude affect grapes?

How can altitude be beneficial (3)?

What are 2 examples of high altitude regions?

Answer

A

Temperature falls ~0.6 degrees C every 100m increase
Vineyards at low LATITUDE sites would be too warm without high ALTITUDE (e.g. Salta Province, ranging from 1280 - 3000m ASL)
Sunshine and UV radiation are greater at higher altitudes because the rays travel through LESS ATMOSPHERE before reaching the vines.
High altitude sites have high diurnal range, which helps grapes to retain freshness while also ripening sufficiently.
Salta, Argentina and Mt. Etna, Sicily.

Question 26

Q

Identify the ideal temperature(s) for the following:

Budburst

Flowering

Fruit Set

Photosynthesis

Answer

A

Budburst: >10C (50F)

Flowering: 17C (63F)

Fruit Set: 26 - 32C (79-90F)

Photosynthesis: 18-33C (64 - 92F)

Question 27

Q

What is humus?

Answer

A

Organic matter in the soil formed by partial decomposition of plant material by organisms such as microbes and earthworms.

Question 28

Q

Grapes for wine production can successfully grow btw/which 2 lines of latitude?

Answer

A

30-50^o latitude either side of the equator.

Question 29

Q

Summarize the importance of temperature and its influence on BUDBURST (4):

Answer

A

Temps >10C (50F) stimulate budburst.
Budburst is more successful/uniform when there is a distinct rise in temp (as in Continental climates).
Warm soil temps also promote budburst.
Cold temps can bring frost = harmful to new buds/growth = substantially reduced yields.

Question 30

Q

How do characteristics of the soil affect the grapes (2)?

Give specific examples to illustrate:

Answer

A

Gravelly soils with larger particles (e.g. Bordeaux) will drain freely, warm up more quickly and retain more heat than clay-heavy soils with finer particles (e.g. Alberese soils in Chianti)
Light coloured soils reflect some energy from solar radiation - Dark coloured soil (and stony soils) absorb more energy and re-radiate it when temperatures are cooler

Question 31

Q

When is plentiful water desired / not desired during the growing season (5)?

Answer

A

plentiful water in spring = growth of lots of leaves to photosynthesize + support growth of vine and ripening of grapes.
if too much water in late spring/early summer, encourages vegetative growth which competes for sugars, delaying/hindering ripening.
mild water stress btw/budburst and véraison is beneficial for grapes.
excess water close to harvest can dilute sugar, cause skins to split, encourage grey rot.
however too much water stress near harvest can lead to grape shriveling.

Question 32

Q

What are some ways that climate change is affecting weather events (2)?

Answer

A

Increased frequency + severity of erratic weather events, e.g. storms, hurricanes, floods, frosts, heatwaves.

All lead to substantially reduced yields/quality.

Question 33

Q

What can a deficiency of Phosphorus lead to?

Answer

A

Lack of P = poorly developed root systems => diminished ability to take up water and nutrients => reduced vine growth+yields.

Question 34

Q

What can a deficiency of Magnesium lead to?

Answer

A

Mg deficiency = reduced grape yields and poor ripening.

Question 35

Q

Why do the regions of Willamette Valley and Margaux have different climates even though they’re both located at the same line of latitude (4)?

Answer

A

Wil. Valley + Margaux both located at 45^o Latitude.

WV main grape = early-ripening Pinot Noir / Marg. main grape = Late-ripening Cabernet Sauvignon.

Bordeaux has warmer climate (avg. GST 17.7C / 64F) partially due to the warming Gulf Stream, originating from the Gulf of Mexico.

WV has cooler climate (avg. GST 15.9F / 61F) due to cold California current flowing from northern Pacific. Compare w/ Walla Walla in WA, which is sheltered from cooling influences of Cascade Mntns.

Question 36

Q

Summarize the importance of temperature and its influence on BUD FRUITFULNESS:

Answer

A

warm temps (>25C / 77F) promote increased bud fruitfulness in the next year (affects yields in the next vintage).

Question 37

Q

What are some positive and negative effects sunshine/warmth has on the vines/grapes (6)?

Answer

A

Enhances anthocyanin production (black colour pigment)
Reduces methoxypyrazines
Increases favourable aroma precursors/compounds
Warms grapes, therefore increases rate at which malic acid is used up in respiration (can be pos/neg.)
Reduces risk of fungal disease = higher yields / quality.
Can cause sunburn / reduce acidity / increase sugar which increases potential alcohol / wines can end up tasting jammy.

Question 38

Q

Why do high altitude sites often have a higher diurnal range than lower altitude sites (3)?

Answer

A

the ground absorbs energy from solar radiation during the day, releases energy into the atmosphere at night.
at lower alt., the air (esp. water vapor) absorbs energy, retaining heat at night.
at high alt., air is thinner + holds less moisture and heat escapes more rapidly = cooler night temps.

Question 39

Q

Where is a large diurnal range more helpful for grape-growing?

Less?

Why?

Answer

A

More favorable in warm-hot climates (e.g. Mendoza/Ribera del Duero): cool nights slow respiration of malic acid and are beneficial for formation of anthocyanins.

Less favorable in cool / moderate climates (e.g. Mornington Peninsula / Mosel): night time temps still allow ripening to continue for grapes to ripen sufficiently.

Question 40

Q

Summarize the importance of temperature and its influence on DORMANCY (2):

Answer

A

Temps <10C (50F) ensure dormancy.
Extreme cold (

Question 41

Q

Give an example of how 2 vintages for a specific region varied greatly from each other:

Answer

A

Bordeaux

2007: Cool, cloudy and wet during most of August.

2003: Heat waves w/consistently high temps and near drought conditions were experienced.

Question 42

Q

How does latitude affect grapes (2)?

Answer

A

Grapes grown at lower latitudes (nearer the equator) receive more sunlight per year because the sun’s rays are concentrated on a smaller surface area.

Therefore, they usually have higher levels of sugar, lower levels of acid, riper aromas and higher (but riper) tannins with more colour intensity.

Question 43

Q

Summarize the importance of temperature and its influence on SHOOT and LEAF DEVELOPMENT (2):

Answer

A

Vines begin to use photosynthesis to create sugar for energy.
Ideal temps = 18-33C (64-91F)

Question 44

Q

What is the definition of climate?

Answer

A

The annual pattern of temperature, sunlight, rainfall, humidity and wind in a specific region, averaged out over several (30) years.

Question 45

Q

What effects does climate change have on the vine’s environment (3)?

Answer

A

Rise in temperatures; greater evapotranspiration, threat of water stress. This can benefit some regions (e.g. Mosel in Germany) while harming others (Olifants River, S. Africa)
Changes in distribution of rainfall
Greater weather variability and frequency of extreme events

Question 46

Q

Why is it helpful to plant on free-draining soils in cooler climates (4)?

What is a risk involved?

Answer

A

Free-draining soils (e.g. sandy/stony soils) warm up faster in spring than damp soils.
Rising soil temps stimulate budburst + shoot growth.
It’s helpful for cooler climates to have these soils to promotoe early budburst, which creates a longer growing season to encourage grape ripening.
Warm soils also encourage root growth = able to absorb more water+nutrients.

RISK: Early budburst increases risk of spring frosts damaging young buds+shoots.

Question 47

Q

What are the average temperature ranges for cool, moderate, warm and hot climates?

Answer

A

Cool: 16.5 (62.5 F) or less
Moderate: 16.5-18.5 (62-65 F)
Warm: 18.5-21 ( 65- 70 F)
Hot: 21+ (70 F+)

Question 48

Q

How does the vine use water (5)?

Answer

A

Turgidity (i.e. not wilting)
Photosynthesis
Temperature regulation
Solvent for nutrients in the soil
Medium in which all vine’s biochecmical/physiological mechanisms take place.

Question 49

Q

What are some additional benefits provided by slopes NOT related to sun exposure (3)?

What are some problems (2)?

Answer

A

Shallower, poorer soils w/better drainage.
Shelter from wind+rain (rain shadow effect).
Protection from frosts (cold air flows downward).

Problems: soil erosion + inability to use machinery on steep slopes

Question 50

Q

Define Diurnal Range:

What factors contribute to a region’s diurnal range (2)?

Answer

A

Diurnal Range: avg. difference btw/day and night-time temps.

Regions w/continental climates / high altitude = higher diurnal ranges.

Regions near large bodies of water have lower diurnal ranges.

Question 51

Q

Give an example each of a cool and warm climate that benefit from proximity to water:

How do they benefit?

Answer

A

Cool Climate: Finger Lakes, New York

Located in upstate NY, normally very cool-cold climate, but proximity to the Finger Lakes helps reduce severity of winter freeze (which could damage/kill vines) and creates air movement which protects from spring frosts, which could lower yields.

Warm Climate: Carneros, S. Napa Valley, California

Located at the southern end of Napa Valley, this would be a very hot site if not for its proximity to San Pablo Bay. The bay provides cooling breezes and fog which make Carneros well-suited for cool-climate varietals e.g. Pinot Noir and Chardonnay.

Question 52

Q

Why do mists form (2)?

What does dense mist become?

When is the most common time of day for mists to form, and give 3 eg.s of regions that experience mists:

Answer

A

Mists = tiny droplets of water collecting in the air above ground/water.

Formed when warm air is rapidly cooled = vapor in air condenses, e.g. when warm air over water meets cooler conditions above land.

Dense mist = Fog.

Most commonly occuring in morning, but can form in different regions at different times of the day.

e.g. Sonoma / Leyda Valley / Sauternes

Question 53

Q

What is chlorosis?

What is it caused by?

Answer

A

Chlorosis is a condition in which leaves turn yellow and photosynthesis stops, negatively affecting grape ripening and yields.

Chlorosis is caused by a deficiency of iron caused by soils high in pH (e.g. limestone soils high in calcium carbonate).

Question 54

Q

How do rising temps caused by climate change affect the properties of grapes and the wines produced from them (4)?

Answer

A

Warmer temps = faster vine cycle.
faster rate of sugar accumulation and reduction of acidity, but same rate of ripening for aroma and tannin compounds.
if grapes are picked later in order to achieve tannin/aroma/flavor ripeness, grapes will have higher levels of sugar = higher alc, lower acidity, higher pH = problematic.

ALSO: rise in temps will affect signature aroma compounds, e.g. rotundone “black pepper” in N. Rhone Syrah will likely diminish in warming temperatures.

Question 55

Q

What are the 5 main nutrients required for successful vines and what is their general purpose?

Answer

A

1) Nitrogen (needed for photosynthesis, majorly impacts vine growth. Excess can lead to vegetative cycle.)
2) Potassium (helps regulate flow of water)
3) Phosphorus (photosynthesis)
4) Calcium (role in structure of plant cells / photosynthesis)
5) Magnesium (found in chlorophyll = photosynthesis)

Question 56

Q

What is the definition of TRANSPIRATION?

Answer

A

The process by which vines draw water and nutrients up from the soil through the roots, to be delivered to the above-ground parts of the vine.

Question 57

Q

How does soil pH influence nutrient availability?

Specific eg.?

Answer

A

Different nutrients become more/less available at different pH levels.

e.g. Iron is poorly available in soils w/high pH levels like limestone soils which have high proportions of calcium carbonate.

Question 58

Q

Generally speaking, what are the 3 components that make up soil composition?

What are the main functions of soil (3)?

Answer

A

Geological sediment, organic remains (humus) and pores in between that contain water and air.

supports the vine’s roots.
is the medium through which vines take up water and nutrients.
habitat for organisms (animals and microbes)

Question 59

Q

What must happen to organic nutrient compounds before they are available to the vine?

In this context, what does ‘organic’ mean?

What helps in this process and how?

Answer

A

Organic nutrient compounds (found in manure/compost/humus) must be broken down into inorganic ones in order to be useful for vines.
‘Organic’ describes compounds that contain carbon; ‘Inorganic’ = those that don’t.
Organisms in the soil (earthworms/bacteria/fungi) feed on organic matter and converts it into available forms (‘mineralization’), either as humus (partially decomposed matter) or inorganic compounds.

Question 60

Q

What is a continental climate (2)?

What are 2 examples?

Answer

A

More extreme differences between summer and winter temperatures.
Short summers, cold winters with temperatures rapidly changing in the spring / autumn.
e.g Burgundy + Alsace

Question 61

Q

How common is Calcium deficiency?

What can this lead to?

Answer

A

Ca deficiency is rare.

Can have a negative influence on fruit set.

Question 62

Q

How does aspect correlate w/Grand Cru sites in France (2)?

Answer

A

In cool climates, e.g. Burgundy and Alsace, Grand Cru sites are usually positioned on SE-facing slopes, giving the wines greater ripeness and concentration.
Generic appellation sites are found on flatter terrain.

Question 63

Q

For which wine styles is Vintage Variation not desirable (2)?

How can wineries adjust winemaking practices to deal w/vintage variation (3)?

Answer

A

NV Sparkling wines.

High-volume, inexpensive wines for which consumers are expecting the same taste year in and year out.

Adjustments to must/wine / greater extraction in warm years to balance high alc levels / deacidification in cooler years).

Question 64

Q

How does a region’s topography affect patterns of rainfall (2)?

Give a specific example of these effects:

Answer

A

Mountain ranges force winds of warm moist air upwards over high altitudes => cools + condenses into clouds => precipitation.
Can lead to one side getting greater rainfall whereas the other is sheltered and has very dry conditions ; “rain shadow” effect.
e. g. wine regions of WA State: west of Cascade mntns = Puget Sound AVA is much cooler+wetter VS east side of Cascades = Columbia Valley which is much drier and often needs irrigation.

Answer 65

A

esp. when paired w/dry conditions, excess heat causes photosynthesis to slow/stop = slower vine growth+development.
This is due to heat sensitivity of enzymes that catalyze photosynthesis.
Water stress (typ. in hot regions) = photosynthesis slows/stops due to closing of stomata to prevent water loss.
Closed stomata = less intake of CO2, which is needed for photosynthesis.

Answer 66

A

grape growers can plant on aspects that face away from the equator in warm climates to limit their sun exposure.
this allows them to grow earlier-ripening varieties or produce wines w/less abv and more acid than would normally be possible at that latitude.
e. g. in Stellenbosch, white grapes are sometimes planted on S-facing slopes in order to retain refreshing acidity.

Answer 67

A

Photosynthesis - 18-33 C (64-91 F)

Fruit set - 26-32 C (79-90 F)

Answer 68

A

Rows of trees can be planted at the edge of vineyards to act as windbreaks.

Fences can also be used, but less aesthetically pleasing and require maintenance.

Care must be taken because trees will compete with vines for resources.

Answer 69

A

Winds can WARM (e.g. the Zonda in Mendoza) or COOL (e.g. the Mistral in the Southern Rhone) vineyards.
Reduce humid, stagnant air which can cause fungal diseases.
Increase evapotranspiration rates, meaning that areas with STRONGER winds might need MORE water.
Extremely strong winds can also damage vines and vineyard trellising.

Answer 70

A

Valleys that face the coast or other low-lying areas (e.g. Petaluma Gap in California) = winds are felt far inland.

Valley also funnels stronger winds even more inland.

Answer 71

A

El Niño: Warmer water flowing from the western Pacific eastwards toward the Caribbean. Brings higher rainfall/storms to S. America and California but warmer/drier conditions to Washington/Oregon. Also brings warm/drought conditions to Australia.

La Niña: Same process, but with cooler water. Brings warmer, drier conditions in S. America/California but cooler/wetter conditions in Pacific NW. Also cooler/wetter conditions in Australia.

Answer 72

A

A soil type found in Jerez, Spain.
High in chalk, has good water retention and releases water slowly to the vines during the hotter months when there is no rainfall.
The light color of the soil also reflects sunlight off its surface.
Also forms a crust when dry, reducing evaporation.

Answer 73

A

A soil that has moderate, balanced proportions of sand, silt and clay.

Answer 74

A

Can limit sunlight (therefore photosynthesis), lower temperatures, and cause fungal diseases.

They can also provide cooling conditions for sites that might otherwise be too hot, e.g. Sonoma Coast, California or Hunter Valley, NSW, Australia.

Additionally, they provide conditions necessary for the development of Noble Rot / Botrytis cinerea, essential for the production of wines such as Sauternes and Toakaji.

Answer 75

A

Because of the curvature of the earth, the sun hits different areas of latitude at different angles.
At the equator (i.e. the earth’s middle latitude), the sun hits at a more direct angle, so the sun’s radiation is concentrated on a smaller area.
Further away, the sun hits the earth at a lower/higher angle, meaning that the radiation is spread across a greater area.

Answer 76

A

Sugar accumulation = faster at warm temps due to photosynthesis producing sugar + increased grape transpiration.
Malic acid decreases due to its use in transpiration in warm temps.
Mean temps >21C (70F) in final month = rapid loss of acidity. Mean temps <15C (59F) = possibly too much acidity.
Riper flavor/aromas come with warmer temps.
Cooler temps hinder breakdown of methoxypyrazines = herbaceous flavors.
For black grapes, anthocyanin and tannin (color) development is optimum at 15-25C (59-77F).

Answer 77

A

TEXTURE: proportion of mineral particles of sand, silt and clay. Soils with finer particles, i.e. clay, will retain more water and nutrients but drain less easily.

STRUCTURE: how the mineral particles form aggregates (crumbs.) Soils with high amounts of clay will be sticky, i.e. harder for vines to burrow through. Soils with high amounts of sand/rocks will have more gaps, but also be looser, more unstable.

Answer 78

A

The annual variation that happens relative to the climatic average, i.e. VINTAGE.

PREDICTABLE: Central Valley, California.

UNPREDICTABLE: Bordeaux, France.

Answer 79

A

Full, intense, unblocked sunshine is not required.

Light only becomes a limiting factor to photosynthesis if sunlight levels fall below 1/3 full sunshine.

Hence, fog can slow photosynthesis but an average cloudy day will not.

Answer 80

A

Open stomata allow free exchange of water vapor out of the vine + let CO2 and O2 diffuse in/out of leaves.
W/sufficient water, stomata stay open all day.
Lack of water = partially closed stomata to conserve water but also leads to hindered/halted photosynthesis due to lack of CO2 entering leaves.
Lack of photosynthesis = less sugars for energy = stunted growth and ripening.

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3. The Growing Environment Flashcards

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