NUS DoA M.ARCH2 THESIS SELECTION: MATERIALISING SAND / LIN DERONG (2017/2018) by NUSDoA2022

YEAR 5 COMPILATION OF SAMPLES

2017/2018 M.ARCH 2 THESIS PROJECT LIN DERONG (SUPERVISOR: A/P DR. LILIAN CHEE)

MATERIALISING SAND: THE DUNES THE ARCHIPELAGO THE BEACH

IMAGE CREDIT: LIN DERONG

MASTERS DESIGN PROJECTS

INTERESTS

PROJECT ATTRIBUTES

Masters Design Projects include those explored in two Options Design Research Studios (M.Arch 1), the Advanced Architecture Studio and the Thesis project in M.Arch 2. All studios may explore issues relevant to the interests of the Research Clusters, adjunct teachers and professors in practice. Students are encouraged to capitalise on faculty expertise in widening the scope of investigations which collectively strengthen the Thesis Project in M.Arch 2.

A good Masters project is one where:

Essential and Elective modules are useful in underpinning your Masters studio investigations. Although Options Design Research studios may be varied in content and method, students are advised to be selective and to use them as ‘learning runways’ to identify a Thesis topic and to apply accumulated knowledge there. The Advanced Architecture Studio preceding the Thesis may be used to explore thesis drivers in greater detail and focus. It is expected that the Thesis project will be the most comprehensive and extensive study of all the Masters Design Projects. _______________________________________________________________________________________

• the research process informs design strategy which can be followed through a coherent sequential process of explorations or iterations • the research generates an underlying order giving rise to a number of architectural or urban propositions • the research or issues engaged with, give rise to new solutions through design, some of which are singular, permutable or recombinant • it addresses the contextual specificities of site, material, spatial, culture and program and all of the above are communicated through architectural drawings, well-crafted models and annotations which curate a design process and outcome(s) that can be understood without a verbal presentation by the author Beyond a commitment to individual academic portfolios, Masters projects play an important role in characterising the discursive ethos of a design school. It is important that you do your best.

DESIGN AS INQUIRY Masters projects can be research investigations where design forms a principal mode of inquiry. Methods can be heuristic or empirical or in mixed modes of inquiry. There are a number of research methods in design investigations leading to different outcomes but they are by no means exhaustive: • textual/graphic analysis of theoretical concepts with investigations drawn from critical discourse using text references, works of art/representation • quantitative analysis to verify qualitative hypotheses with simulation, physical experiment, prototype testing and mixed methods • scenario-driven speculative design to suggest solutions to emergent need. The process in itself is a new way of seeing/thinking which generates many solutions. One version of a solution may be articulated spatially and in full materiality • new research knowledge is interpreted in architecture as a new way of thinking/making/experiencing • existing practices, processes or existing technologies are applied to design and which produce ‘unprecedented’ outcomes

_______________________________________________________________________________________

MASTERS DESIGN PROJECTS

INTERESTS

PROJECT ATTRIBUTES

A good Masters project is one where:

_______________________________________________________________________________________

RESEARCH CLUSTERS

ASIA RESEARCH FOCUS

III. TECHNOLOGIES

The Department positions itself as a design and research think-tank for architectural and urban development issues emerging in South Asia and SE Asia contexts. Graduate coursework in design engages with key challenges in population growth, industry, infrastructure, housing and environment, climate change and rapid economic change with disruptive technologies. In engaging with trans-boundary economies and technological change, the Department addresses concerns with the environmental impact of new settlements and cities on the natural environment in the light of climate change and on the threat to heritage and cultural presentation. MArch studios anticipate planning solutions through design explorations at various scales of intervention. The Master’s coursework are thus aligned to a core of five teaching groups viz. History Theory Criticism, Research by Design, Design Technologies, Urbanism and Landscape Studies. _______________________________________________________________________________________

The Technologies cluster investigates environmentally performative/sustainable building forms and systems,and generative-evaluative processes for designing liveable environments. Its research employs traditional and emerging technologies contributing to a new understanding of the human ecosystem, and emerging computational methods and techniques for discovering the relationships between form and performance. It researches on the relationship between human and natural landscapes, at every scale, from the building component scale to the urban scale. Special emphasis is placed on the context of high density Asian cities and the context of the Tropics.

I. HISTORY THEORY CRITICISM The History Theory Criticism cluster develops critical capacities to examine questions of architectural production, representation and agency within historical and contemporary milieu. Taking architecture and urbanism in Asia as its primary focus, members work in interdisciplinary and transnational modes. We explore a range of topics relating to colonial/postcolonial and modern/ postmodern Asian cities; aesthetics and technopolitics of tropical climate and the built environment; affective media including film, contemporary art and exhibitionary modes; heritage politics and emergent conservation practices. We develop discursive fronts through a variety of media and scales. The cluster research encompasses scholarly, creative and advocacy activities. Output includes monographs, edited volumes, research papers, architectural reviews in professional journals, curatorial practice, conservation work, film and photography, object-making, and policy-influencing advocacy work.

II. RESEARCH BY DESIGN The Research by Design cluster performs translational research through the practices of making as research rather than through traditional forms academic research. It links the importance of creating, drawing, and building with rigor, originality, and significance to produce innovative and creative designs that shape the built environment. Located strategically between the NorthSouth axis of rapidly urbanizing Asia and the East -West line of the tropical equator, the Research by Design cluster performs research through practice in three main themes: • Novel aesthetics of climatic calibration and performance; • Contemporary architectonics of fabrication, material, and resources contingent on South East Asia; and • Emergent spaces of inhabitation and production surrounding the equator.

IV. URBANISM With a comprehensive understanding of the complexity and distinctive characters of emerging urbanism in Asia, the vision is to develop sustainable models and innovative urban strategies to cope with various environmental, social, economic and technological challenges that Asian cities face today and in the future. Emergent urban issues related to community & participation, conservation & regeneration, ageing & healthcare, built form, modelling & big data, and resilience & informality are investigated from multiple perspectives and inter- and transdisciplinary collaborations to question conventional norms and conceptions and establish new visions for a sustainable urban future.

V. LANDSCAPE STUDIES The Landscape Studies cluster undertakes research to generate new knowledge of landscapes as socio-ecological systems and promotes the use of knowledge in governance systems and landscape design that improve the well-being of humans and the ecological integrity of the environment. The geographic focus is primarily high-density urban regions in Asia, but members of cluster also work in the transitional zones within the rural-urban continuum, where urban regions are expanding at a rapid rate into rural landscapes. The overall research approach is both interdisciplinary and transdisciplinary — we are concerned with not just advancing theoretical concepts and knowledge, but also applying the knowledge in practice and public policy to shape the environment. Our research areas cover a wide spectrum of socio-ecological dimensions of landscape, from landscape science, landscape management, to design research and socio-behavioural studies.

RESEARCH CLUSTERS

ASIA RESEARCH FOCUS

III. TECHNOLOGIES

Materialising Sand The Dunes, The Archipelago, The Beach

by Lin Derong thesis supervisor Dr. Lilian Chee

volume 2

Architectural Design thesis submitted to the Department of Architecture in partial fulfillment of the requirements for the degree of MASTER OF ARCHITECTURE at the National University of Singapore presented on the 28th April 2018

Materialising Sand The Dunes, The Archipelago, The Beach

by Lin Derong thesis supervisor Dr. Lilian Chee

volume 2

Gigantic sand dunes continue to pile as Singapore safeguards her resources amidst global scarcity. Shifting away from sandâ&#x20AC;&#x2122;s instrumentalist narrative, three erratic sandscapes emerge vis-Ă -vis our three stockpile sites as a hyper-productive leisure infrastructure to recast sandâ&#x20AC;&#x2122;s muted politics and its tactility as an emotive material matter. Performing further as a morphological catalysis, our relationships and vulnerabilities with sand unfold.

Behaviourology 010 -----

The Dunes Seletar | Shooting Range 038

The archipelago Punggol | Barge Cruise 064

The Beach Tampines | Infinity Sand-pool 090 --References 116

Behaviourology 010 -----

The Dunes Seletar | Shooting Range 038

The archipelago Punggol | Barge Cruise 064

The Beach Tampines | Infinity Sand-pool 090 --References 116

008

009

008

009

010

011 DB000. [Previous Spread]

Tropical Arid. Standing on

Bartley Viaduct. Tampines on second visit, 2018.

DB001. [Opposite] A small

pile of big. Sand particles in

a sand pile. See figure FP103 Sand classification table in

Materialising Sand: Volume 1

for the constitutions of sand as a matter.

Behaviourology

Our relationship and vulnerabilities with sand are deeply embedded in sand’s material properties. Sand is a granular material that consists of particles between 0.06mm to 2mm in diameters as defined in volume 1. They behave in very peculiar ways which are akin to solids, liquids

and gases. Each granular particle is capable of accumulating into scales ranging from table piles to sheer territorial landforms. Together, their forms morph with wind, gravity and water.

The architecture takes an interest in the materiality of sand – tactile,

haptic, scalar – to translate into an alternative experience and ecology. Vis-à-vis Singapore’s three sand stockpiles, three surreal sandscapes emerge: the leaky, the flamboyant, and the vast.

010

011 DB000. [Previous Spread]

Tropical Arid. Standing on

Bartley Viaduct. Tampines on second visit, 2018.

DB001. [Opposite] A small

pile of big. Sand particles in

a sand pile. See figure FP103 Sand classification table in

Materialising Sand: Volume 1

for the constitutions of sand as a matter.

Behaviourology

and gases. Each granular particle is capable of accumulating into scales ranging from table piles to sheer territorial landforms. Together, their forms morph with wind, gravity and water.

The architecture takes an interest in the materiality of sand – tactile,

haptic, scalar – to translate into an alternative experience and ecology. Vis-à-vis Singapore’s three sand stockpiles, three surreal sandscapes emerge: the leaky, the flamboyant, and the vast.

012

013

ABSORB

BURY

CARVE

SURGE

TERRACE

TUNNEL

CONGLOMERATE

DEPOSIT

ERODE

VEGETATE

EXCAVATE

FACET

SALTATE

SCOUR

SEEP

FOLD

GRADATE

IMPACT

SETTLE

SLUMP*

SUBMERGE

LIQUIFY

REBOUND

RIPPLE

DB002. Sand Behaviours Index. Due to sandâ&#x20AC;&#x2122;s material properties,

*Slumping occurs when a coherent mass of loosely consolidated sand

not exhaustive. Drawing reconstructed from Allen, 469-471.

sliding along a concave-upward or planar surface

they behave in a certain way upon external forces acting on it. List is

moves a short distance down a slope. Movement is characterized by

012

013

ABSORB

BURY

CARVE

SURGE

TERRACE

TUNNEL

CONGLOMERATE

DEPOSIT

ERODE

VEGETATE

EXCAVATE

FACET

SALTATE

SCOUR

SEEP

FOLD

GRADATE

IMPACT

SETTLE

SLUMP*

SUBMERGE

LIQUIFY

REBOUND

RIPPLE

DB002. Sand Behaviours Index. Due to sandâ&#x20AC;&#x2122;s material properties,

*Slumping occurs when a coherent mass of loosely consolidated sand

not exhaustive. Drawing reconstructed from Allen, 469-471.

sliding along a concave-upward or planar surface

they behave in a certain way upon external forces acting on it. List is

moves a short distance down a slope. Movement is characterized by

014

015 Angle of Repose = tan-1(h ÷ 1/2 d)

where tanθ = opposite ÷ adjacent h= height from base to peak d= base diameter

h= 12000 θ Dry Sand - 34o

tan34 = h ÷ 1/2 d 34o = tan-1 (2 x 12000/d) d = 24000 ÷ tan(34) d = 35600mm (3 s.f.)

Wind Direction

Smaller particles move by suspension

Larger particles move by saltation

Sand will fall on slip-face by breaking the particle tension, and fill up the gap. This process will repeat overtime under gravity and material weakness.

Slip Face

Cross-bed Surface (Buried Slip Face

Wind Direction

Leeward Slope Windward Slope

Sand (water filled) 30o to 15o

h= 12000

Dune Migration

45o = tan-1[(2 x 12000) ÷ d) d = 24000 ÷ tan(45) d = 24000mm Wet Sand - 45o

Windward slope is smoothened and shaped by wind force.

DB003. Angle of Repose. This is the steepest angle of dip relative

to the horizontal plane to which sand can be piled without slumping, anything more, slope surface will slide. Sand has a predetermined

angle of repose from 34o to 45o. Generally, the rougher the grains the steeper the angle due to their ability to better interlock. Reference: Glover, Thomas J. Pocket Ref. 4th ed. Sequoia Publishing, 2010.

DB004. Sand Dune Profile.

Leeward slope forms an angle with the sand surface by mechanical force of the sand’s own weight.

014

015 Angle of Repose = tan-1(h ÷ 1/2 d)

where tanθ = opposite ÷ adjacent h= height from base to peak d= base diameter

h= 12000 θ Dry Sand - 34o

tan34 = h ÷ 1/2 d 34o = tan-1 (2 x 12000/d) d = 24000 ÷ tan(34) d = 35600mm (3 s.f.)

Wind Direction

Smaller particles move by suspension

Larger particles move by saltation

Sand will fall on slip-face by breaking the particle tension, and fill up the gap. This process will repeat overtime under gravity and material weakness.

Slip Face

Cross-bed Surface (Buried Slip Face

Wind Direction

Leeward Slope Windward Slope

Sand (water filled) 30o to 15o

h= 12000

Dune Migration

45o = tan-1[(2 x 12000) ÷ d) d = 24000 ÷ tan(45) d = 24000mm Wet Sand - 45o

Windward slope is smoothened and shaped by wind force.

DB003. Angle of Repose. This is the steepest angle of dip relative

to the horizontal plane to which sand can be piled without slumping, anything more, slope surface will slide. Sand has a predetermined

DB004. Sand Dune Profile.

Leeward slope forms an angle with the sand surface by mechanical force of the sand’s own weight.

016

017 Wind Direction

TRANSVERSE

STAR

LONGITUDINAL

BARCHANOID

Elongated arms extend upwind behind the central part of the dune.

BARCHAN (CONVEX)

DB005. Aeolian Sand Dunes. Geometries shaped naturally by

wind velocity and sand supply. Sand particles moves with the wind direction. These typologies are found in different places on the Earthâ&#x20AC;&#x2122;s surfaces according to global wind movements.

PARABOLIC (CONCAVE) Slip faces often occur on the

outer side of the nose and on the outer slopes of the arms.

016

017 Wind Direction

TRANSVERSE

STAR

LONGITUDINAL

BARCHANOID

Elongated arms extend upwind behind the central part of the dune.

BARCHAN (CONVEX)

DB005. Aeolian Sand Dunes. Geometries shaped naturally by

PARABOLIC (CONCAVE) Slip faces often occur on the

outer side of the nose and on the outer slopes of the arms.

018

019

DB006. [Above] Wind Simulations. Performed under artificial

DB007. [Below] Particle Saltation. Performed under artificial

oeirntates with wind movement as each grain saltates, suspends and

wind movement as each grain saltates, suspends and displaces.

condition, sand as an aggregate pile morphs, shifts position, and displaces.

condition. Sand as an aggregate pile morphs and shifts position with

018

019

DB006. [Above] Wind Simulations. Performed under artificial

DB007. [Below] Particle Saltation. Performed under artificial

oeirntates with wind movement as each grain saltates, suspends and

wind movement as each grain saltates, suspends and displaces.

condition, sand as an aggregate pile morphs, shifts position, and displaces.

condition. Sand as an aggregate pile morphs and shifts position with

020

021 3 MONTHS

6 MONTHS

12 MONTHS

3 MONTHS

6 MONTHS

12 MONTHS

WIND - 50%

Plan

Side

Perspective

WIND - 75%

Plan

Side

Perspective

WIND - 100%

Plan

Side

Perspective

Wind Direction DB008. Barchan Typology. Postulated (convex) sand dune

DB009. Parabolic Typology. Postulated (concave) sand dune

Referenced from Kotenko, Anastasia, and Niki Kakali. ‘Aeolian Sand

alteration with varying wind speed over a period of 12 months.

Odyssey’. Landscape Urbanism, Architectural Association, 2014.

alteration with varying wind speed over a period of 12 months.

Odyssey’. Landscape Urbanism, Architectural Association, 2014.

020

021 3 MONTHS

6 MONTHS

12 MONTHS

3 MONTHS

6 MONTHS

12 MONTHS

WIND - 50%

Plan

Side

Perspective

WIND - 75%

Plan

Side

Perspective

WIND - 100%

Plan

Side

Perspective

Wind Direction DB008. Barchan Typology. Postulated (convex) sand dune

DB009. Parabolic Typology. Postulated (concave) sand dune

Referenced from Kotenko, Anastasia, and Niki Kakali. ‘Aeolian Sand

alteration with varying wind speed over a period of 12 months.

Odyssey’. Landscape Urbanism, Architectural Association, 2014.

alteration with varying wind speed over a period of 12 months.

Odyssey’. Landscape Urbanism, Architectural Association, 2014.

022

023 Aeolian Sand and Obstacles - Sediments Air converges and wind velocity increases as they pass through a physical barrier/ obstacle. Airborne sand particles travelling by

Air converges and velocity

Air diverges and velocity

increase

decreases

suspension will deposit as sediment on the leeward side as air

diverges and wind velocity decrease. Overtime, sand will accumulate. DB010a. Plan of Deposit.

DB010b. [Opposite] Section Profile of Deposit.

Obstacle/ Barrier

DB011a. Obstacles and Artificial Conditions. An abstract object is placed in the middle of a sand pile where conditions are artificially

exaggerated and controlled to expedite the morphology process and achieve certain forms on purpose.

DB011b. Expedited Burial. As sediments accumulate overtime, the

obstacle will eventually be buried in sand.

Wind Deposit Sediment

022

023 Aeolian Sand and Obstacles - Sediments Air converges and wind velocity increases as they pass through a physical barrier/ obstacle. Airborne sand particles travelling by

Air converges and velocity

Air diverges and velocity

increase

decreases

suspension will deposit as sediment on the leeward side as air

diverges and wind velocity decrease. Overtime, sand will accumulate. DB010a. Plan of Deposit.

DB010b. [Opposite] Section Profile of Deposit.

Obstacle/ Barrier

DB011a. Obstacles and Artificial Conditions. An abstract object is placed in the middle of a sand pile where conditions are artificially

exaggerated and controlled to expedite the morphology process and achieve certain forms on purpose.

DB011b. Expedited Burial. As sediments accumulate overtime, the

obstacle will eventually be buried in sand.

Wind Deposit Sediment

024

025 Aeolian Sand and Obstacles - Morphology Simulation Abstract physical obstacles are introduced to alter dune’s movement direction, and also creating paths

for dunes to morph. The experiment attempts to learn simple organisation techniques to achieve specific morphologies. Naturally, these processes will take several decades.

Referenced from Kotenko, Anastasia, and Niki Kakali. ‘Aeolian Sand Odyssey’. Landscape Urbanism, Architectural Association, 2014.

DB012a. [Opposite] Obstacle Simulation A. Obstacles with an

angle to the wind flow shape the dune movements perpendicular to themselves - turning dunes movement direction.

DB012b. Obstacle Simulation B. Straight wall variation.

024

025 Aeolian Sand and Obstacles - Morphology Simulation Abstract physical obstacles are introduced to alter dune’s movement direction, and also creating paths

for dunes to morph. The experiment attempts to learn simple organisation techniques to achieve specific morphologies. Naturally, these processes will take several decades.

Referenced from Kotenko, Anastasia, and Niki Kakali. ‘Aeolian Sand Odyssey’. Landscape Urbanism, Architectural Association, 2014.

DB012a. [Opposite] Obstacle Simulation A. Obstacles with an

angle to the wind flow shape the dune movements perpendicular to themselves - turning dunes movement direction.

DB012b. Obstacle Simulation B. Straight wall variation.

026

027 DB012c. Obstacle Simulation C. Dunes tend to turn their crest

DB012d. Obstacle Simulation D. Obstacles with an angle to the

wind direction.

turning dunes movement direction.

parallel to the obstacles they meet with in their moving direction/

wind flow shape the dune movements perpendicular to themselves -

026

027 DB012c. Obstacle Simulation C. Dunes tend to turn their crest

DB012d. Obstacle Simulation D. Obstacles with an angle to the

wind direction.

turning dunes movement direction.

parallel to the obstacles they meet with in their moving direction/

wind flow shape the dune movements perpendicular to themselves -

028

029

Conveyor belt vibrates sand particles to separate individual grains

SINGLE MOUND

Angle of repose of slope face keep at 34o and below.

RIDGE PILE

Section profile of conveyor belt diverting sand to the peak.

Processed and washed

STACKED PILE

sand proceeds to the

final stage to be stored in a pile. DB013. Artificial Sand Pile. Geometries formed as a result from pragmatic storage purpose - fresh off conveyor mills and sand barges. These typologies are found in sand stockpiles.

DB014. Piling Sand. Drawing based on observations outside a cement plant in Punggol. Extension to figure AA06 Formation

Method: Artificial Sources, and AA07 Frac Sand Plant Process of

Materialising Sand, Volume 1.

Scale [1:150]

028

029

Conveyor belt vibrates sand particles to separate individual grains

SINGLE MOUND

Angle of repose of slope face keep at 34o and below.

RIDGE PILE

Section profile of conveyor belt diverting sand to the peak.

Processed and washed

STACKED PILE

sand proceeds to the

DB014. Piling Sand. Drawing based on observations outside a cement plant in Punggol. Extension to figure AA06 Formation

Method: Artificial Sources, and AA07 Frac Sand Plant Process of

Materialising Sand, Volume 1.

Scale [1:150]

030

031

DB015. [Opposite] Sand Terrace. Tampines on second visit. DB016. White Mounds. Tampines on second visit.

030

031

DB015. [Opposite] Sand Terrace. Tampines on second visit. DB016. White Mounds. Tampines on second visit.

032

033 Single Drum and Tendem Rollers

Deep Sand Vibrator - by Piling to reinforce surface

Vibrating Plate Compactors

Lightweight compaction

DB017a. Compacting Sand - Vibration. Heavy duty Stress is

equipment to maintain sand

compactness. Vibration of sand

applied repeatedly and rapidly via a mechanically driven hammer.

mass ensures higher density.

Often combined with rolling compaction. Drawing not to scale.

Slope Vibratory Compactor

Limited Compactness

DB017c. Compacting Sand - Static. A large static stress and pressure is added on the surface and then released overtime.

Drawing not to scale. Reference from Mishra, Gopal. ‘Different Types

of Soil Compaction Equipments -Types of Rollers’. Accessed 31 March 2018.

Weight is hydraulically lifted and Placement of Foot

Static Linear Pressure

dropped from specific height

Vibratory Roller

Soil Compactor

and Hammer

Levelling Blade

100mm

750kg

300mm

sand influence zone, up to 9

400mm

meters deep

500mm 600mm

Sand compact by impact, compaction hole created

a large mass onto the surface of the soil. Drawing not to scale.

500kg

200mm

Compact point:

DB017b. Compacting Sand - Impact. Stress is applied by dropping

300kg

700mm DB017d. Compacting Sand - Rolling. A heavy cylinder is rolled over the surface of the soil. Often fitted with vibratory devices.

Commonly used on sports pitches. Reconstructed from Danneberger, Karl. ‘The Science of Soil Compaction’. SportsField Management, 2013. Drawing not to scale.

1000kg 15psi 12psi 9psi 6psi 3psi

032

033 Single Drum and Tendem Rollers

Deep Sand Vibrator - by Piling to reinforce surface

Vibrating Plate Compactors

Lightweight compaction

DB017a. Compacting Sand - Vibration. Heavy duty Stress is

equipment to maintain sand

compactness. Vibration of sand

applied repeatedly and rapidly via a mechanically driven hammer.

mass ensures higher density.

Often combined with rolling compaction. Drawing not to scale.

Slope Vibratory Compactor

Limited Compactness

DB017c. Compacting Sand - Static. A large static stress and pressure is added on the surface and then released overtime.

Drawing not to scale. Reference from Mishra, Gopal. ‘Different Types

of Soil Compaction Equipments -Types of Rollers’. Accessed 31 March 2018.

Weight is hydraulically lifted and Placement of Foot

Static Linear Pressure

dropped from specific height

Vibratory Roller

Soil Compactor

and Hammer

Levelling Blade

100mm

750kg

300mm

sand influence zone, up to 9

400mm

meters deep

500mm 600mm

Sand compact by impact, compaction hole created

a large mass onto the surface of the soil. Drawing not to scale.

500kg

200mm

Compact point:

DB017b. Compacting Sand - Impact. Stress is applied by dropping

300kg

700mm DB017d. Compacting Sand - Rolling. A heavy cylinder is rolled over the surface of the soil. Often fitted with vibratory devices.

Commonly used on sports pitches. Reconstructed from Danneberger, Karl. ‘The Science of Soil Compaction’. SportsField Management, 2013. Drawing not to scale.

1000kg 15psi 12psi 9psi 6psi 3psi

034

035 Sand Pile Casting. Small amount of water is able to bind the gaps between particles. Electrostatic attraction of water to mineral surfaces will increase soil strength.

DB018a. Mixture A. 1 : 1 [Sand : Water]

DB018b. Mixture B. Kinetic Sand with Scenic Spray DB018c. Mixture C. 1 : 1/8 [Sand : Water]

DB018d. Mixture D. 1: 1/8 [Sand : Seawater]

DB018e. Mixture E. 1 : 1/2 : 3/4 [Sand : Cornstarch : Water]

DB018f. Mixture F. 2 : 1 : 1 [Sand : White Glue : Cornstarch] DB018f. Cooking mixture E over heat.

034

035 Sand Pile Casting. Small amount of water is able to bind the gaps between particles. Electrostatic attraction of water to mineral surfaces will increase soil strength.

DB018a. Mixture A. 1 : 1 [Sand : Water]

DB018b. Mixture B. Kinetic Sand with Scenic Spray DB018c. Mixture C. 1 : 1/8 [Sand : Water]

DB018d. Mixture D. 1: 1/8 [Sand : Seawater]

DB018e. Mixture E. 1 : 1/2 : 3/4 [Sand : Cornstarch : Water]

DB018f. Mixture F. 2 : 1 : 1 [Sand : White Glue : Cornstarch] DB018f. Cooking mixture E over heat.

036

037 There is a principle specific to environmental ecology: it states that anything is possible – the worst disasters or the most flexible evolutions

- Felix Guatarri, “The Three Ecologies”, 1989

The architecture interventions are set to blur the boundaries between

architecture and landscape. In Antoine Picon’s words, it is a convergence of “abstract information and tangible sensation”. Whereas architecture is understood as an abstraction, landscape is traditionally associated

with tangible materiality and sensation. In the reconciliation between conceptual and tangible, constructing these interventions involve

negotiating through challenging realms as the site contexts impose their

technical limits – practicality, access, codes, programmatic performances – set within a defined architectural context.

Using landforms created by sand and its material properties, three

sandscapes – a series of dunes, an archipelago, and a beach – emerge and

transform into extreme forms of landscape. Beyond pastoral images, they make use of the three site contexts and their corresponding associative uses of sand – a shooting range, a barge cruise, and an infinity sand-

pool. These are artificially constructed grounds made to activate sand’s

tactility, materiality, performance, texture and properties. Sand becomes unpredictable and at times, risky. They leak, erode, slump, bury, shift,

morph, deplete and accumulate, and they are ever changing; challenging the static and inert state of sand in the stockpiles. As compared to

their counterparts in the natural realm, these morphological processes are architecturally tampered with and hastened; while leaving these

supposedly arid and dry landforms readily at the disposal of Singapore’s hot and wet climate.

Combined with the primacy of sand’s materiality, the landscape is

immersive, haptic, and experienced directly by the body. Users would have to climb, scale, and traverse across these vast landscapes while playing

and tampering with the terrains. Being excessive and exaggerated, these hyper-productive leisure infrastructures become zones of differences

to bring forth an alternative experience with sand whereby an aesthetic dream is built-up.

Through their tangible material consequence and immaterial experience of sand operating on both an intimate and colossal scale, the affective

is hence generated while exposing the symbiotic relationships between people and sand.

Three Sandscapes