What is the relationship between spot and futures?

The spot price is usually below the futures price . The situation is known as contango. Contango is quite common for non-perishable goods with significant storage costs. On the other hand, there is backwardation, which is a situation when the spot price exceeds the futures price.

What is the difference between spot market and commodity market?

The spot market is a market for delivery of commodities on spot or that is normally 4-5 days . The futures markets will be delivered after a specific period; normally 1 month, 2 months, or 3 months. The working of commodity markets in India is basically about the futures market but the spot market is equally important.

What is the difference between spot market and future market?

A spot market is where spot commodities or other assets like currencies are traded for immediate delivery for cash. Forward and futures markets instead involve the trading of contracts where the purchase is to be completed at a later date (read on to the following question for more on this).

What is the lead lag relationship between spot and futures markets?

The smaller the lead–lag relationship between the futures and spot prices, the better developed and more efficient the market . According to the efficient market hypothesis, information is reflected instantly in spot and futures prices in an efficient market, which means that there is no lead or lag effect.

Revisiting the relationship between spot and futures markets: evidence from commodity markets and NARDL framework (2024)

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PMC8314855

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Ann Oper Res. 2022; 313(1): 171–189.

Published online 2021 Jul 27. doi:10.1007/s10479-021-04172-3

PMCID: PMC8314855

PMID: 34334864

Hachmi Ben Ameur,¹ Zied Ftiti,² and Waël Louhichi³

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Associated Data

Data Availability Statement

Abstract

This study aims to investigate the relationship between the spot and futures commodity markets. Considering the complexity of the relationship, we use a nonlinear autoregressive distributed lag (NARDL) framework that considers the asymmetry and nonlinearity in both the long and short run. Based on the daily returns of six commodity indices reaggregated on three commodity types, our study reaches some interesting findings. Our analysis highlights a bidirectional relationship between both markets over the short and long run, with a greater lead for the futures market. This result confirms the future market’s dominant contribution to price discovery in commodities. Changes in commodity prices appear first in the futures market, as informed investors and speculators prefer trading on this market that is characterized by low costs and a high-leverage effect. Then, the information is transmitted from the futures to the spot market through arbitrageurs’ activity, which explains the nonlinearity of the relationship. These results are helpful to scholars, investors and policymakers.

Keywords: Commodity markets, NARDL, Spot market, Futures market, Lead–lag relationship

Introduction

Since 2002, the commodity market has exhibited fundamental changes, as explained by financialization. Investment flow into commodity markets has grown substantially, since institutional as well as specialized investors have been interested in this market (Domanski et al. 2007). Consequently, various financial instruments and derivatives have been developed, leading to more attention from investors, traders and hedgers. Additionally, commodity market mechanisms have evolved substantially since 2002, unlike in conventional markets, based on their physical features (storable and non-storable commodity) as well as their importance in worldwide economic activity.

In the two decades of commodity markets' financialization, various periods of instability, high volatility, extreme movements and seasonal patterns have been observed. These stylized facts revive the issue of price discovery. Financial instruments (derivatives, futures contracts, etc.) are known to have a positive effect on price discovery and the efficiency of resource allocation (Chan 1992; Schwarz et al. 1994; Henriksen et al. 2019). However, they might be sources of anomalies. Indeed, futures contracts are sources of various forward-looking decisions of economic agents: producers might define their supply strategy based on the price of futures contracts and physical traders, investors might define their asset allocation strategy based on the trend of futures prices, etc. Therefore, the spot–futures relationship is still a topical issue, particularly for commodity markets that this study aims to revisit.

From a theoretical point of view, various mechanisms might highlight the spot–futures relationship. Based on market efficiency theory, the Law of One Price in futures markets stipulates that the spot and futures prices might be related based on spot–futures parity, which ends any trade-off opportunities. However, the commodity market is imperfect, characterized by market frictions such as transaction costs and news reactions. Moreover, the theory of storage, pioneered by Kaldor (1983), is susceptible to supporting the spot–futures relationship. This theory stipulates that in equilibrium, the futures prices are equal to the spot prices plus the cost of carrying. Specifically, the theory of storage concurs that the basis and futures spread are connected to risk premium, convenience yield and the cost of storage. The basis defines whether the commodity market is in a contango or backwardation situation, including the shortage or surplus of the physical commodity in the market. As the market approaches maturity, the basis reduces until it equals zero and spot and futures prices converge.

Both theories discussed above highlight the connection between spot and futures prices in the long term. However, the commodity market has some specifications and stylized facts, supporting theoretically and practically a divergence between both prices in the short term, such as seasonal dynamics of consumption, thin trading, lags in information transmission, capital market microstructure effects, etc. This potential short-run deviation between both prices supports a nonlinear connection that might be observed through a lead–lag relationship between spot and futures prices. This nonlinear relationship might be displayed, in the case of commodity prices, through a demand shock due to seasonal consumption. Indeed, if the consumption of a commodity increases, explained by the seasonal effect, the inventory level decreases. Consequently, the convenience yield will increase and influence the price. Consequently, the seasonal effect inducing a demand shock leads to the futures price being highly volatile during the life of the futures contract. During the life of the futures contract, particularly at the beginning of the contract, a lead–lag relationship might be present between both prices, with a magnitude decrease in the function of its maturity. At maturity (in the long run), the futures prices converge with the spot prices.

From a literature review, many studies have investigated the issue of spot–futures price connections, particularly for commodity markets, but they are inconclusive. Moreover, the literature is orientated to precious metals such as gold. Some studies show that futures markets lead spot markets and play an important role in price discovery (e.g., Aslan et al. 2018; Bopp et al. 1987; Brooks et al. 2001; Kawaller et al. 1987; Stoll et al. 1990; Talbi et al. 2020). Some others reach a contradictory conclusion, showing that spot prices lead to futures prices (e.g., Pradhan et al. 2020; Srinivasan 2012). Some studies support an unclear relationship between both prices (e.g., Turnovsky 1983; Pindyck 2001; Bohl 2020; Wang et al. 2017), while some others investigate the potential asymmetric relationship between spot and futures prices through causality analysis and inconclusive findings (e.g., Arouri et al. 2013; Chang et al. 2015; Dash et al. 2010; Hammoudeh et al. 2004; Jena et al.2019; Joseph et al. 2014; Mayer et al. 2017).

The literature discussed above is inconclusive considering the results and the nature of the commodity. Our study revisits the literature on the spot–futures relationship for the commodity market to explore its specific characteristics compared to the conventional market, with the aim to complete it at four levels. First, we assessed the role of spot/futures prices in price discovery by examining their dynamics of interaction. Second, this relationship is assessed in both long and short terms to find some insights into the theoretical background discussed above. Third, we deliver new insights on the lead–lag relationship by considering various types of commodities and delving into precious metals. Four, we investigated the spot-future relationship based on an empirical framework with several advantages compared to those used in previous studies.

In this study, we assess the spot and futures relationship for three types of commodities: metal markets (aluminum, gold and copper), energy markets (Brent and natural gas) and agriculture markets (wheat). Considering the stylized fact of the commodity markets (seasonal dynamics of consumption, thin trading, lags in information transmission and capital market microstructure effects) and the potential complexity of their co-dynamics, we propose a nonlinear autoregressive distributed lag (NARDL) framework. This approach has several advantages over methods used in the previous literature (GARCH family models, cointegration, Granger Causality, Wavelet, etc.). First, it allows us to assess of the dynamics of the relationship between spot and futures prices for the long and short run and to test the theoretical background discussed above, contrary to other methods (GARCH family models, Granger Causality, etc.). Second, it considers the potential asymmetry and nonlinearity in the spot–futures relationship. Third, it avoids loss of information by allowing a mix between stationary and nonstationary series, contrary to the cointegration approach. Fourth, the nonlinear ARDL approach avoids spurious regression treatments (unit root tests, cointegration testing, etc.) that may be capricious based on some specific decisions such as the choice of deterministic part, autoregressive lags and so on (Dimitriadis et al. 2020).

Our study has some noteworthy findings. We found a bidirectional relationship between both markets over the short and long run. However, leadership is more pronounced in the futures market, supporting the conclusion of price discovery in commodity markets. This study provides insights on the transmission mechanisms in commodity markets, as we confirm that changes in commodity prices appear first in the futures market, explained by the preference of investors and speculators to trade in this market behind the low costs and the high-leverage effect. Thus, the information is transmitted from the futures to the spot market through arbitrage activity, which explains the nonlinear relationship.

The remainder of our paper is organized as follows. Section2 presents the econometric methodology. Section3 discusses the data and the empirical results and Sect.4 presents the conclusion.

Econometric methodology

In this study, we use the NARDL approach introduced by Shin et al. (2014) to examine the relationship between the futures and spot markets for several commodity markets, especially the metal markets (aluminum, gold and copper), energy markets (Brent and natural gas) and agriculture markets (wheat). The use of the NARDL approach allows us to consider the complexity of the interaction between spot and futures returns, especially the nonlinearity and asymmetry over the short and long run.

Pesaran et al. (1999) and Pesaran et al. (2001) are the first to propose a linear ARDL framework presented in the following form:

$Δ J_{t}^{Sp} = α_{0} + \sum_{i = 1}^{P} α_{1} Δ J_{t - i}^{Sp} + \sum_{i = 1}^{q} α_{2} Δ J_{t - i}^{Ft} + θ_{1} J_{t - 1}^{Sp} + θ_{2} J_{t - 1}^{Ft} + ε_{t}$

Case 1

H₀ is rejected for short-run symmetry and cannot be rejected for long-run symmetry. In this case, the cointegrating NARDL model with short-run asymmetry can be expressed as follows:

$Δ J_{t}^{Sp} = α_{0} + \sum_{i = 1}^{p} α_{1} Δ J_{t - i}^{Sp} + \sum_{i = 1}^{q} (β_{i}^{+} Δ J_{t - i}^{F t, +} + β_{i}^{-} Δ J_{t - i}^{F t, -}) + θ_{1} J_{t - 1}^{Sp} + θ_{2} J_{t - 1}^{Ft} + + ε_{t}$

$Δ J_{t}^{Ft} = α_{0} + \sum_{i = 1}^{p} α_{1} Δ J_{t - i}^{Ft} + \sum_{i = 1}^{q} (β_{i}^{+} Δ J_{t - i}^{S p, +} + β_{i}^{-} Δ J_{t - i}^{S p, -}) + θ_{1} J_{t - 1}^{Ft} + θ_{2} J_{t - 1}^{Sp} + ε_{t}$

Case 2

H₀ is rejected for the long-run symmetry and cannot be rejected for short-run symmetry. The cointegrating NARDL model with long-run asymmetry can be expressed as follows:

$Δ J_{t}^{Sp} = α_{0} + \sum_{i = 1}^{p} α_{1} Δ J_{t - i}^{Sp} + \sum_{i = 1}^{q} α_{2} Δ J_{t - i}^{Ft} + θ_{1} J_{t - 1}^{Sp} + γ^{+} J_{t - 1}^{F t, +} + γ^{-} J_{t - 1}^{F t, -} + ε_{t}$

$Δ J_{t}^{Ft} = α_{0} + \sum_{i = 1}^{p} α_{1} Δ J_{t - i}^{Ft} + \sum_{i = 1}^{q} α_{2} Δ J_{t - i}^{Sp} + θ_{1} J_{t - 1}^{Ft} + γ^{+} J_{t - 1}^{S p, +} + γ^{-} J_{t - 1}^{S p, -} + ε_{t}$

Case 3

H₀ is rejected for both long- and short-run symmetry. The cointegrating NARDL model with long- and short-run asymmetry is defined in Eqs.(3) and (4).

Case 4

H₀ cannot be rejected for both long- and short-run symmetry. The suitable model is the cointegrating linear ARDL model defined in Eqs.(1) and (2).

Finally, the existence of cointegration estimated by the previous models does not necessarily mean that the estimated coefficients are stable. To test the stability of the estimated coefficients, we use the cumulative sum (CUSUM) and cumulative sum of squares (CUSUMQ) tests proposed by Brown et al. (1975). The CUSUM and CUSUMQ statistics are updated recursively and plotted against the breakpoints. The test simply identifies parameter instability if the CUSUM and CUSUMQ exceed the area between the two critical bounds of 5% significance.

Data and empirical results

Data and preliminary results

In this study, we investigate the interaction between the spot and futures markets for the metal, energy and agriculture markets. We obtained the daily price time series data from the Bloomberg database and for the period from January 2002 to November 2020. The use of daily frequency constitutes a contribution to the literature, as existing studies typically use the monthly frequency. This frequency might provide more information on the dynamics of the relationship between spot and futures markets, especially in the evolution of storage. The descriptive statistics for all variables are presented in Table Table11.

Table 1

Descriptive statistics for the return series

	Gold		Aluminum		Brent		Copper		Gas		Wheat
	Futures	Spot	Futures	Spot	Futures	Spot	Futures	Spot	Futures	Spot	Futures	Spot
Mean	0.00045	0.00044	0.00018	0.00017	0.00044	-0.00009	0.00048	0.00048	0.00052	0.00110	0.00034	0.00034
Med	0.00018	0.00058	0.00000	0.00000	0.00042	0.00000	0.00000	0.00000	0.00000	0.00000	0.00000	0.00000
Max	0.09008	0.10788	0.09753	0.06604	0.21019	0.32528	0.12349	0.12441	0.38314	1.01565	0.09193	0.14315
Min	−0.09354	−0.09074	−0.10775	−0.07924	−0.24404	−1.99086	−0.11050	−0.09840	−0.18045	−0.44530	−0.09492	−0.09982
Std	0.01110	0.01091	0.01383	0.01343	0.02265	0.04641	0.01711	0.01654	0.03292	0.04877	0.01978	0.01950
Skew	−0.22800	−0.25477	−0.15076	−0.10197	−0.10970	−25.44100	−0.11003	0.01601	1.09149	4.15016	0.27711	0.29296
Kurt	8.48803	8.99977	7.03263	5.54349	13.36809	1035.43100	7.71873	7.55832	12.22166	78.81827	4.88025	5.90809
J-B Prob,	0.00000	0.00000	0.00000	0.00000	0.00000	0.00000	0.00000	0.00000	0.00000	0.00000	0.00000	0.00000

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This table reports the descriptive statistics of spot and futures returns for the commodity markets of our sample. For each series, we report the mean (Mean), median (Med), maximum (Max), minimum (Min), standard deviation (Std), skewness (Skew), Kurtosis (Kurt) and Jarque–Bera (J-B)

Descriptive statistics are calculated based on the log-returns series. The mean returns are positive for all the indexes excepting the spot Brent index. The mean of the futures indexes is higher than the mean of the spot indexes for the gold, aluminum and Brent markets. The volatility of the futures indexes is higher than the volatility of the spot indexes for the gold, aluminum, copper and wheat markets. The skewness was often negative and statistically significant during this period for gold, aluminum, Brent futures and spot indexes and positive for the natural gas and wheat markets. For the copper market, the skewness was negative for the spot index and negative for the futures index. Kurtosis of all indexes suggests that distribution tails are higher than those of a normal distribution are. Normality was statistically rejected for all series.

Table Table22 presents the results of the unit root tests. We used two different tests for the unit root to assess the integration order of the series. The null hypothesis for the augmented Dickey-Fuller (ADF) test is that the data are nonstationary, where the null hypothesis for the KPSS test is that the data are stationary. The two tests show that at log levels, both futures and spot log price series are nonstationary in all cases, indicating the presence of unit root. For the log difference, the null hypothesis for the ADF test was rejected for all the series. The results are confirmed by the KPSS test, which is in favor of stationarity for all log difference series. Finally, we note that for the ARDL specification, it does not matter whether the regressors are stationary processes I (0) or nonstationary processes I (1).

Table 2

Results of unit root tests

	Gold		Aluminum		Brent		Copper		Gas		Wheat
	Futures	Spot	Futures	Spot	Futures	Spot	Futures	Spot	Futures	Spot	Futures	Spot
ADF
Log levels	2.271	2.319	0.396	0.364	0.299	0.284	1.262	1.413	−0.715	−0.890	0.396	0.039
Log difference	−70,823^***	−71,324^***	−75,120^***	−72,977^***	−72,600^***	−38,756^***	−75,041^***	−75,130^***	−73,203^***	−21,529^***	−70,928^***	−71,3365^***
KPSS
Log levels	7.176	7.175	0.832	2.171	2.171	1.693	3.723	3.725	5.338	5.225	2.386	1.607
Log difference	0,2763	0,2805	0,0989	0,0894	0,2142	0,3779^*	0,3371	0,3540^*	0,1084	0,0774	0,0770	0,0853

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The ADF test critical values: 1% level (−3.4314), 5% level (−2.8619) and 10% level (−2.5670). The KPSS Asymptotic critical values: 1% level (0.7390), 5% level (0.4630) and 10% level (0.3470).* denotes significance at the 10% level, ** denotes significance at the 5% level and *** denotes significance at the 1% level

Table Table33 presents the results of the corresponding best suitable model that estimates the relationship between the spot and futures markets for the metal, energy and agriculture markets. We note that the nature of the relationship between spot and futures markets is specific for each asset. Short-run asymmetry characterizes the relationship between the spot and futures markets since this hypothesis is confirmed for all estimations except for the model specifications of the aluminum and wheat futures prices and copper spot prices. Additionally, for natural gas, the interaction between the spot and futures returns is characterized by a short-run asymmetry in both directions. Finally, the nonlinearity in either the long or short run is present for all the estimations except for the model specifications of the copper spot prices and the wheat futures prices. All these findings support the choice of the NARDL framework, as they show that the use of a linear symmetric model leads to misspecification of the relationship between spot and futures returns.

Table 3

Wald test results for long- and short-run symmetries

Dependent variable	Long run	Short run	Corresponding best-fit model
Aluminum spot	5.385**	12.461***	NARDL, long- and short-run asymmetries
Aluminum spot	(0.020)	(0.000)	NARDL, long- and short-run asymmetries
Aluminum futures	7.963***	0.850	NARDL, long-run asymmetry
Aluminum futures	(0.005)	(0.493)	NARDL, long-run asymmetry
Gold spot	7.650***	7.681***	NARDL, long- and short-run asymmetries
Gold spot	(0.006)	(0.000)	NARDL, long- and short-run asymmetries
Gold futures	1.866	4.386***	NARDL, short-run asymmetry
Gold futures	(0.172)	(0.000)	NARDL, short-run asymmetry
Brent spot	4.453**	5.890***	NARDL, long- and short-run asymmetries
Brent spot	(0.035)	(0.000)	NARDL, long- and short-run asymmetries
Brent futures	0.498	55.529***	NARDL, short-run asymmetry
Brent futures	(0.481)	(0.000)	NARDL, short-run asymmetry
Copper spot	3.419	1.782	ARDL
Copper spot	(0.065)	(0.076)	ARDL
Copper futures	4.929**	2.789***	NARDL, long- and short-run asymmetries
Copper futures	(0.027)	(0.007)	NARDL, long- and short-run asymmetries
Gas spot	0.006	3.847***	NARDL, short-run asymmetry
Gas spot	(0.938)	(0.000)	NARDL, short-run asymmetry
Gas futures	1.222	3.229***	NARDL, short-run asymmetry
Gas futures	(0.269)	(0.001)	NARDL, short-run asymmetry
Wheat spot	0.230	11.401***	NARDL, short-run asymmetry
Wheat spot	(0.631)	(0.000)	NARDL, short-run asymmetry
Wheat futures	0.289	0.291	ARDL
Wheat futures	(0.591)	(0.747)	ARDL

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The corresponding best-fit model is determined based on the estimation of Eqs.(1), (2), (3) and (4). For long-run symmetry, the null hypothesis H0 defined as $γ^{+} = γ^{-}$ , is tested against the alternative hypothesis H1: long-run asymmetry. For the short run, the null hypothesis H0 defined as $β_{i}^{+} = β_{i}^{-}$ , is tested against the alternative hypothesis H1: short-run asymmetry.

P-values are in brackets. ***, ** and * indicate the significance at 1%, 5% and 10% levels, respectively

Lead–lag relationship between the spot and futures commodity markets

Table Table44 presents the estimation results for the specification of the best regression models, as defined in Table Table3.3. In these models, spot returns of our sample of commodity indexes (aluminum, gold, copper, Brent, natural gas and wheat) are a function of spot market returns and past information from the futures market, which allow us to test the predictive power of futures prices in explaining the spot returns. If the coefficient of the past information from the futures market is significant, the futures market contributes to the spot market price discovery and speculation in futures markets plays an important role in price formation. From Table Table4,4, we can see that the Breusch–Godfrey test for serial correlation and the autoregressive conditional heteroscedasticity (ARCH) test with a lag of eight indicate that the selected models are correctly specified at a level of 5%. Furthermore, Table Table44 indicates that all the models exhibit short-run asymmetry except for the model explaining the copper spot returns. The asymmetric long-run coefficients $L^{+}$ and $L^{-}$ are positive and significant at the 1% level, for aluminum, gold and Brent spot markets indicating that both positive and negative variation in the futures markets allows a variation in the same direction in the long run. Similarly, asymmetric short-run coefficients $β_{i}^{+}$ and $β_{i}^{-}$ for aluminum, gold and Brent spot markets are positive and significant indicating that last variations are induced in the same direction. For the copper, spot returns estimated using the symmetric ARDL model, the coefficients $θ_{2}$ and $α_{2, i}$ associated with the long and short run, are positive and significant indicating that a change in the futures market is induced in the same direction for the copper spot market. For the natural gas and wheat spot markets, the asymmetry is relevant only for the short run. Overall, our results show that the futures market contributes to price discovery in the spot market. This implies that the process of price discovery is based on the transmission of new information from the futures prices to the spot prices through the transactions initiated by arbitrageurs who trade in different markets. This arbitrage activity and transaction costs characterizing the functions of commodity markets can be an explanation for the nonlinear relationship between the spot and futures returns.

Table 4

Results for the NARDL estimation for the spot returns

Variable	Aluminum spot		Gold spot		Brent spot		Copper spot		Gas spot		Wheat spot
	NARDL-LR& SR		NARDL-LR&SR		NARDL-LR& SR		ARDL		NARDL-SR		NARDL-SR
	Coef	Prob.*	Coef	Prob.*	Coef	Prob.*	Coef	Prob.*	Coef	Prob.*	Coef	Prob.*
$α_{1, t - 1}$	−0.362***	0.000	−0.256***	0.000	−0.091***	0.000	−0.395***	0.000	−0.135***	0.000	−0.178***	0.000
$α_{1, t - 2}$	−0.130***	0.000	−0.192***	0.000	−0.011	0.432	−0.244***	0.000	−0.237***	0.000	−0.024*	0.084
$α_{1, t - 3}$	−0.037***	0.007	−0.166***	0.000	−0.081***	0.000	−0.142***	0.000	−0.147***	0.000	−0.022**	0.024
$α_{1, t - 4}$			−0.122***	0.000	0.041***	0.002	−0.096***	0.000	−0.138***	0.000
$α_{1, t - 5}$			−0.069***	0.000	−0.018	0.153	−0.059***	0.000	−0.046***	0.001
$α_{1, t - 6}$			−0.027***	0.002	−0.011	0.376	−0.041***	0.003	−0.100***	0.000
$α_{1, t - 7}$					−0.026**	0.013			−0.095***	0.000
$α_{1, t - 8}$									−0.043***	0.000
$α_{2, t}$							0.868***	0.000
$α_{2, t - 1}$							0.379***	0.000
$α_{2, t - 2}$							0.237***	0.000
$α_{2, t - 3}$							0.130***	0.000
$α_{2, t - 4}$							0.080***	0.000
$α_{2, t - 5}$							0.059^***	0.000
$α_{2, t - 6}$							0.036***	0.008
$α_{2, t - 7}$							0.014**	0.011
$α_{2, t - 8}$							0.015***	0.009
$β_{t}^{+}$	0.951***	0.000	0.962***	0.000	1.013***	0.000			0.469***	0.000	0.764***	0.000
$β_{t - 1}^{+}$	0.334***	0.000	0.205***	0.000	0.228***	0.000			0.567***	0.000	0.273***	0.000
$β_{t - 2}^{+}$	0.165^***	0.000	0.206***	0.000	−0.130^***	0.0020			0.185^***	0.000	0.003	0.985
$β_{t - 3}^{+}$	0.047***	0.001	0.147***	0.000	0.244***	0.0000			0.222***	0.000	0.037**	0.016
$β_{t - 4}^{+}$			0.097***	0.000	−0.118*	0.086			0.285***	0.000
$β_{t - 5}^{+}$			0.080***	0.000	0.008	0.826			−0.005	0.903
$β_{t - 6}^{+}$					0.036	0.285			0.145***	0.000
$β_{t - 7}^{+}$					0.063***	0.009			0.105**	0.010
$β_{t - 8}^{+}$									0.070**	0.023
$β_{t}^{-}$	0.936***	0.000	0.997***	0.000	1.106***	0.000			0.405***	0.000	0.862***	0.000
$β_{t - 1}^{-}$	0.400***	0.000	0.223***	0.000	−0.014	0.735			0.739***	0.000	0.129***	0.000
$β_{t - 2}^{-}$	0.123***	0.000	0.135***	0.000	0.087**	0.034			0.152***	0.000	0.083***	0.000
$β_{t - 3}^{-}$	0.039***	0.005	0.164***	0.000	0.031	0.442			0.153***	0.000
$β_{t - 4}^{-}$			0.112***	0.000	0.125***	0.000			0.131***	0.001
$β_{t - 5}^{-}$			0.030*	0.061					0.233***	0.000
$β_{t - 6}^{-}$			0.032**	0.021					0.022	0.588
$β_{t - 7}^{-}$			−0.015	0.083					0.117***	0.004
$β_{t - 8}^{-}$			0.020	0.001					0.090	0.000
$θ_{1}$	−0.263***	0.000	−0.681***	0.000	−0.007	0.169	−0.093***	0.000	−0.130***	0.000	−0.008***	0.000
$θ_{2}$							0.093***	0.000	0.131***	0.000	0.009***	0.000
$γ^{+}$	0.265***	0.000	0.682***	0.000	0.003***	0.000
$γ^{-}$	0.263***	0.000	0.678***	0.000	0.014***	0.000
$α_{0}$	1.895***	0.000	3.850***	0.000	−0.002*	0.089	0.287***	0.000	−0.113***	0.000	−0.045***	0.000
$L^{+}$	1,006***	0.000	1,001***	0.000	0,049***	0.000
$L^{-}$	0,999***	0.000	0,996***	0.000	1,942***	0.000
AIC	−8.374		−8.186		−4.341		−7.102		−3.583		−6.206
SIC	−8.355		−8.153		−4.310		−7.079		−3.545		−6.189
B-G (8)	0.000***		0.000***		0.001***		0.000***		0.000***		0.018**
ARCH(8)	0.000***		0.000***		0.000***		0.000***		0.000***		0.000***

Open in a separate window

The estimation results of the best-suited NARDL specifications are presented in this table. The superscript “ + ” and “-” denote positive and negative cumulative sums, respectively. $L^{+}$ and $L^{-}$ are the estimated long-run coefficients associated with positive and negative changes, respectively. B-G refers to the Breusch–Godfrey serial correlation LM test, ARCH refers to the ARCHEngle'sTestfor ResidualHeteroscedasticity, AIC and SIC refer to the Akaike and Schwarz criteria for selecting model order and LR and SR indicate the long and short run, respectively

Table Table55 presents the estimation results of the best specifications (see Table Table3)3) for the futures returns of the commodity markets of our sample (aluminum, gold, copper, Brent, natural gas and wheat). These regressions aim to test the predictive power of past information from the spot market and past futures returns in explaining futures returns. If the coefficient of the past information from the spot market is significant, we conclude that there is a bidirectional relationship between the spot and futures commodity markets and market fundamentals play an important role in price discovery. From Table Table5,5, we note that the Breusch–Godfrey test for serial correlation and the ARCH test for conditional heteroscedasticity with a lag of eight indicate that the selected models are correctly specified at a level of 5%. The results reported in Table Table55 justify the use of the NARDL model, which considers the complexity of the relationship between both markets characterized by nonlinearity and asymmetry in the short and long run. Interestingly, all the selected models exhibit short-run asymmetry except for the model explaining aluminum and wheat futures returns. By comparing the parameter values of regressions estimating the spot returns (Table (Table4)4) and regressions estimating futures returns (Table (Table5)5) for gold, Brent and gas, we note that, in the short run, the parameter values are greater when the spot return is the dependent variable. This conclusion indicates that there is bidirectional feedback between both markets but the futures markets have a greater impact on the spot markets than the contrary. Similarly, for the wheat market, by comparing the relationship based on the symmetric long run, the relationship is also stronger when considering the impact of the futures index on the spot index.

Table 5

Results for the NARDL estimation for the futures returns

Variable	Aluminum futures		Gold futures		Brent futures		Copper futures		Gas futures		Wheat futures
	NARDL-LR		NARDL-SR		NARDL-SR		NARDL-LR&SR		NARDL-SR		ARDL
	Coef	Prob.*	Coef	Prob.*	Coef	Prob.*	Coef	Prob.*	Coef	Prob.*	Coef	Prob.*
$α_{1, t - 1}$	−0.373***	0.000	−0.224***	0.000	−0.159***	0.000	−0.388***	0.000	−0.201^***	0.000	−0.170^***	0.000
$α_{1, t - 2}$	−0.159***	0.000	−0.172***	0.000	−0.016	0.251	−0.242***	0.000	−0.046^***	0.007	−0.019^**	0.016
$α_{1, t - 3}$	−0.054***	0.000	−0.150***	0.000	0.022	0.112	−0.127***	0.000	−0.040^**	0.018
$α_{1, t - 4}$			−0.108***	0.000	−0.017	0.230	−0.089^***	0.000	−0.042^**	0.013
$α_{1, t - 5}$			−0.069***	0.000	−0.005	0.707	−0.066***	0.000	−0.082^***	0.000
$α_{1, t - 6}$			−0.039***	0.005	0.033	0.017	−0.043***	0.002	−0.034^**	0.038
$α_{1, t - 7}$					−0.026*	0.056	−0.015**	0.012	−0.002	0.879
$α_{1, t - 8}$					0.023**	0.044	−0.010	0.096	−0.050^***	0.001
$α_{2, t}$	0.980***	0.000									0.844^***	0.000
$α_{2, t - 1}$	0.364***	0.000									0.150^***	0.000
$α_{2, t - 2}$	0.144***	0.000
$α_{2, t - 3}$	0.045***	0.001
$α_{2, t - 4}$
$α_{2, t - 5}$
$α_{2, t - 6}$
$α_{2, t - 7}$
$α_{2, t - 8}$
$β_{t}^{+}$			0.884***	0.000	0.639***	0.000	0.931***	0.000	0.258^***	0.000
$β_{t - 1}^{+}$			0.284***	0.000	−0.079***	0.000	0.397***	0.000	0.030	0.160
$β_{t - 2}^{+}$			0.163***	0.000	0.069***	0.000	0.264^***	0.000	0.079^***	0.000
$β_{t - 3}^{+}$			0.160^***	0.000	0.023*	0.070	0.139^***	0.000	0.027	0.202
$β_{t - 4}^{+}$			0.134***	0.000	−0.024*	0.059	0.081***	0.000	0.082^***	0.000
$β_{t - 5}^{+}$			0.071***	0.001	0.060***	0.000	0.095***	0.000	0.016	0.442
$β_{t - 6}^{+}$			0.053***	0.002	−0.030***	0.009	0.034**	0.038	0.005	0.790
$β_{t - 7}^{+}$					−0.023***	0.004			0.072^***	0.000
$β_{t - 8}^{+}$									0.024	0.121
$β_{t}^{-}$			0.877***	0.000	0.290***	0.000	0.956***	0.000	0.256^***	0.000
$β_{t - 1}^{-}$			0.239***	0.000	0.356***	0.000	0.391***	0.000	0.116^***	0.000
$β_{t - 2}^{-}$			0.227***	0.000	0.028	0.094	0.230***	0.000	−0.000	0.982
$β_{t - 3}^{-}$			0.169***	0.000	−0.078***	0.000	0.134***	0.000	0.046^**	0.035
$β_{t - 4}^{-}$			0.113***	0.000	0.072***	0.000	0.136***	0.000	0.025	0.249
$β_{t - 5}^{-}$			0.096***	0.000	−0.023	0.136	0.035*	0.080	0.034	0.111
$β_{t - 6}^{-}$			0.035**	0.034	−0.009	0.563	0.064***	0.000	0.063^***	0.003
$β_{t - 7}^{-}$			0.015*	0.098	0.063***	0.000			0.010	0.602
$β_{t - 8}^{-}$			−0.021***	0.001	−0.065***	0.000			0.046^***	0.000
$θ_{1}$	−0,286***	0.000	−0.700***	0.000	−0.010***	0.000	−0.092***	0.000	−0.021^**	0.018	−0.005^***	0.001
$θ_{2}$			0.700***	0.000	0.011***	0.000			0.015^*	0.078	0.004^***	0.004
$γ^{+}$	0,275***	0.000					0.094***	0.000
$γ^{-}$	0,285***	0.000					0.089***	0.000
$α_{0}$	1.998***	0.000	0.002	0.109	−0.024***	0.000	0.374***	0.000	0.018^***	0.000	0.024^***	0.001
$L^{+}$	0,961***	0.000					1,021***	0.000
$L^{-}$	0,996***	0.000					0,967***	0.000
AIC	−8.327		−8.289		−5.450		−7.019		−4.122		−6.158
SIC	−8.312		−8.256		−5.413		−6.985		−4.084		−6.149
B-G (8)	0.000***		0.000***		0.000***		0.004***		0.018^**		0.039^**
ARCH(8)	0.000***		0.000***		0.000***		0.000***		0.000^***		0.000^***

Open in a separate window

The estimation results of the best-suited NARDL specifications are presented in this table. The superscript “ + ” and “− ” denote positive and negative cumulative sums, respectively. $L^{+}$ and $L^{-}$ are the estimated long-run coefficients associated with positive and negative changes, respectively. B-G refers to the Breusch–Godfrey serial correlation LM test, ARCH refers to the ARCHEngle'sTestfor ResidualHeteroscedasticity, AIC and SIC refer to the Akaike and Schwarz criteria for selecting model order and LR and SR indicate long and short run, respectively

Overall, our results show that futures returns lead to spot returns, which confirms the dominant contribution of the futures market toward price discovery in commodity markets. Our results are in line with the strand of literature supporting bidirectional causality (such as Bhatia et al. 2018; Dash et al. 2010) and contradicts the strand supporting unidirectional causality from the futures market to the spot market and otherwise (e.g., Jena et al. 2018; Joseph et al. 2014; Srinivasan, 2012). However, our findings complete this literature from at least two aspects. First, we propose an investigation of a large set of commodity markets. Second, our empirical framework offers insights to explain the previous mixed results; although our results support a bidirectional relationship, we show that the relationship is more pronounced from the futures markets to spot markets.

It seems that informed investors and speculators prefer trading in the futures market characterized by low costs and a high-leverage effect, which explains the lead of this market in price discovery. Subsequently, the information is transmitted to the spot market and in equilibrium, both markets are rich through arbitrage activity. These results show that speculation is an important determinant of commodity prices rather than market fundamentals.

Figure1 reports the results of the CUSUM test for the stability of the relations between the different spot and futures commodity markets over the long and short run. According to Fig.1, the estimated specifications are moderately stable for all regressions except the model specification for the copper spot returns. For the latter, the CUSUM exceeds the area between the two critical bounds of 5% significance. Similarly, the CUSUMQ test reported in Fig.2 considers the variance, allows for the detection of random movements rather than systematic changes and is a perfect complement to the CUSUM test (Brown et al. 1975). The CUSUMQ test is in favor of the stability parameters of the model specifications of the wheat futures, spot returns and gas futures returns. The above results can be explained by the fact that our sample period includes several turmoil periods characterized by high volatility, such as the subprime crisis (2007–2009), the debt crisis (2010–2012) and the ongoing COVID-19 crisis. These turbulent periods that caused abrupt changes can explain the instability of the parameters revealed by the CUSUMQ test.

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Fig. 1

The CUSUM test. Cusum denotes the CUSUMtestresults and 5% significance denotes the upper and lower range of significance based on 5%. The figures on the left and right show the CUSUMtestresults for the time series futures as explanatory variables and the CUSUMtest results for the spot time series as explanatory variables, respectively

Open in a separate window

Fig. 2

The CUSUMQ test. The cusum of squares denotes the CUSUMQtestresults and 5% significance denotes the upper and lower range of significance based on 5%. The figures on the left and right show the CUSUMQtestresults for the time series futures as explanatory variables and the CUSUMQtestresults for the spot time series as explanatory variables, respectively

Conclusion

This study aims to investigate the relationship between spot and futures markets for a sample of commodity markets, especially the metal markets (aluminum, gold and copper), energy markets (Brent and natural gas) and agriculture markets (wheat). Considering the complexity of the interaction between both markets characterized by nonlinearity and asymmetry in the short and long run, we model this relationship on a NARDL framework. Our results highlight bidirectional feedback between both markets, but the lead of the futures market on the spot returns is greater than the contrary. This confirms the leadership of the futures commodity market in the process of price discovery. Changes in commodity prices appear first in futures markets and then the information is transmitted to spot markets through arbitrageurs’ trades. This result shows that speculation is an important determinant of commodity prices rather than market fundamentals. The arbitrageurs’ activity and transaction costs characterizing the functions of the commodity market explain the nonlinear relationship.

The results of our study are useful for several reasons. First, it informs regulators if the futures market plays an initial role in risk management or if it is dominated by speculative activity. Second, determining the leader market in which commodity prices change helps investors determine their investment and arbitrage strategy. Third, our results are helpful to scholars in the information efficiency field, as it helps them understand the process of price formation and transmission of information from one market to another.

We should note that in this study, we investigated the spot–futures relationship between various assets. It would be interesting for future research to draw some portfolio investment strategies that account for our findings using assets exhibiting only a short-run relationship and those exhibiting both short- and long-run relationships.

Funding

None

Availability of data and material

upon authors request

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upon authors request

Declarations

None

Conflict of interest

None

Footnotes

Publisher's Note

Springer Nature remains neutral with regard to jurisdictional claims in published maps and institutional affiliations.

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Revisiting the relationship between spot and futures markets: evidence from commodity markets and NARDL framework (2024)

Associated Data

Abstract

Introduction

Econometric methodology

Case 1

Case 2

Case 3

Case 4

Data and empirical results

Data and preliminary results

Table 1

Table 2

Table 3

Lead–lag relationship between the spot and futures commodity markets

Table 4

Table 5

Conclusion

Funding

Availability of data and material

Code availability

Declarations

Conflict of interest

Footnotes

References

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