Difference between revisions of "Firm Market Power and the Earnings Distribution"
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{{DES | des = [[Market Power|Market power]], a form of [[Market Failure|market failure]], produces a positive relationship between a firm's labor supply elasticity and the earnings of its workers. This paper provides empirical evidence measuring market power and showing that employers with more power pay lower wages. Especially at lowest incomes. | show=}} | {{DES | des = [[Market Power|Market power]], a form of [[Market Failure|market failure]], produces a positive relationship between a firm's labor supply elasticity and the earnings of its workers. This paper provides empirical evidence measuring market power and showing that employers with more power pay lower wages. Especially at lowest incomes. | show=}} | ||
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− | + | Firm Market Power and the Earnings Distribution | |
− | Douglas A. Webber ∗† | + | Douglas A. Webber ∗† 11-22-11 |
Abstract | Abstract | ||
− | Using the Longitudinal Employer Household Dynamics (LEHD) data from the United States Census Bureau, I compute rm-level measures of labor market (monop- sony) power. To generate these measures, I extend the | + | Using the Longitudinal Employer Household Dynamics (LEHD) data from the United States Census Bureau, I compute rm-level measures of labor market (monop- sony) power. To generate these measures, I extend the dynamic model proposed by Manning (2003) and estimate the labor supply elasticity facing each private non-farm rm in the US. While a link between monopsony power and earnings has traditionally been assumed, I provide the rst direct evidence of the positive relationship between a rm's labor supply elasticity and the earnings of its workers. I also contrast the semistructural method with the more traditional use of concentration ratios to measure a rm's labor market power. In addition, I provide several alternative measures of labor market power which account for potential threats to identication such as endogenous mobility. Finally, I construct a counterfactual earnings distribution which allows the eects of rm market power to vary across the earnings distribution. |
− | + | I estimate the average rm's labor supply elasticity to be 1.08, however my ndings suggest there to be signicant variability in the distribution of rm market power across US rms, and that dynamic monopsony models are superior to the use of concentration ratios in evaluating a rm's labor market power. I nd that a one-unit increase in the labor supply elasticity to the rm is associated with wage gains of between 5 and 18 percent. While nontrivial, these estimates imply that rms do not fully exercise their labor market power over their workers. Furthermore, I nd that the negative earnings impact of a rm's market power is strongest in the lower half of the earnings distribution, and that a one standard deviation increase in rms' labor supply elasticities reduces the variance of the earnings distribution by 9 percent. | |
∗This research uses data from the Census Bureau's Longitudinal Employer Household Dynamics Program, which was partially supported by the National Science Foundation Grants SES-9978093, SES-0339191 and ITR-0427889; National Institute on Aging Grant AG018854; and grants from the Alfred P. Sloan Foundation. Any opinions and conclusions expressed herein are those of the author and do not necessarily represent the views of the U.S. Census Bureau, its program sponsors or data providers, or of Cornell University. All results have been reviewed to ensure that no condential information is disclosed. | ∗This research uses data from the Census Bureau's Longitudinal Employer Household Dynamics Program, which was partially supported by the National Science Foundation Grants SES-9978093, SES-0339191 and ITR-0427889; National Institute on Aging Grant AG018854; and grants from the Alfred P. Sloan Foundation. Any opinions and conclusions expressed herein are those of the author and do not necessarily represent the views of the U.S. Census Bureau, its program sponsors or data providers, or of Cornell University. All results have been reviewed to ensure that no condential information is disclosed. | ||
− | †I have greatly beneted from the advice of John Abowd, Francine Blau, Ron Ehrenberg, Kevin Hallock, George Jakubson, and Alan Manning. I would also like to sincerely thank Henry Hyatt, J. Catherine Maclean, Matt Masten, Erika Mcentarfer, Ben Ost, and Michael Strain for their many helpful comments | + | †I have greatly beneted from the advice of John Abowd, Francine Blau, Ron Ehrenberg, Kevin Hallock, George Jakubson, and Alan Manning. I would also like to sincerely thank Henry Hyatt, J. Catherine Maclean, Matt Masten, Erika Mcentarfer, Ben Ost, and Michael Strain for their many helpful comments. |
1 Introduction | 1 Introduction | ||
− | There is good reason to believe that some rms have non-trivial power in the labor market, that not all rms act as price takers and pay their employees the prevailing market wage. Intuitively, most would not switch jobs following a wage cut of one cent, and we would not expect a rm which raises wages by a small amount to suddenly have an innite stream of workers. | + | There is good reason to believe that some rms have non-trivial power in the labor market, that not all rms act as price takers and pay their employees the prevailing market wage. Intuitively, most would not switch jobs following a wage cut of one cent, and we would not expect a rm which raises wages by a small amount to suddenly have an innite stream of workers. So it becomes an empirical question of whether the departure from perfect competition is meaningful; whether perfect competition is a good approximation for our economy, or whether a model with substantial frictions ts better. |
The existence of signicant rm eects in wage regressions, even after controlling for detailed person and industry characteristics, is cited as strong suggestive evidence of rm market power (Abowd et al., 1999; Goux and Maurin, 1999). For instance, Goux and Maurin (1999) conclude that on average rm eects alter an individual's wage by more than 20 percent. Furthermore, they nd these rm eects are related more to rm characteristics such as size rather than productivity, implying that the rm eects are not simply absorbing workers' unmeasured marginal product of labor. | The existence of signicant rm eects in wage regressions, even after controlling for detailed person and industry characteristics, is cited as strong suggestive evidence of rm market power (Abowd et al., 1999; Goux and Maurin, 1999). For instance, Goux and Maurin (1999) conclude that on average rm eects alter an individual's wage by more than 20 percent. Furthermore, they nd these rm eects are related more to rm characteristics such as size rather than productivity, implying that the rm eects are not simply absorbing workers' unmeasured marginal product of labor. | ||
Estimating the degree of wage competition in the labor market is important for both theoretical research and policy analysis. Since perfect competition is a standard feature in many models of the labor market, evidence of signicant distortions in the labor market would suggest labor economists should reevaluate the perfect competition assumption and its implications in their models. From a policy perspective, the degree of imperfect competition can drastically change the eects of institutions such as the minimum wage (Card and Krueger, 1995) or unions (Feldman and Scheer, 1982). | Estimating the degree of wage competition in the labor market is important for both theoretical research and policy analysis. Since perfect competition is a standard feature in many models of the labor market, evidence of signicant distortions in the labor market would suggest labor economists should reevaluate the perfect competition assumption and its implications in their models. From a policy perspective, the degree of imperfect competition can drastically change the eects of institutions such as the minimum wage (Card and Krueger, 1995) or unions (Feldman and Scheer, 1982). | ||
− | While the industrial organization literature has theoretically and empirically modeled similar frictions in the product market, there has been comparatively less work done to ac- count for distortions of the labor market. This is primarily due to the comparative lack of rich labor market data (such as linked employer-employee data) versus product market data. Most of the theoretical work done on this topic resides in the search theory literature, with major contributions coming from Burdett and Mortensen (1998) and Shimer (2005) to | + | While the industrial organization literature has theoretically and empirically modeled similar frictions in the product market, there has been comparatively less work done to ac- count for distortions of the labor market. This is primarily due to the comparative lack of rich labor market data (such as linked employer-employee data) versus product market data. Most of the theoretical work done on this topic resides in the search theory literature, |
− | name a few1. This line of research has given rise to a "new monopsony" literature, popular- ized by Alan Manning's (Manning, 2003) careful analysis of labor-related topics absent the assumption of perfect competition. The new monopsony model of the labor market views a rm's market power as derived from search frictions rather than solely geographic power as in a classic monopsony model. These search frictions originate from imperfections in the labor market such as imperfect information about available jobs, worker immobility, or heterogeneous preferences. | + | with major contributions coming from Burdett and Mortensen (1998) and Shimer (2005) to name a few1. This line of research has given rise to a "new monopsony" literature, popular- ized by Alan Manning's (Manning, 2003) careful analysis of labor-related topics absent the assumption of perfect competition. The new monopsony model of the labor market views a rm's market power as derived from search frictions rather than solely geographic power as in a classic monopsony model. These search frictions originate from imperfections in the labor market such as imperfect information about available jobs, worker immobility, or heterogeneous preferences. |
Even if the existence of monopsony power is accepted, estimating the degree of market power possessed by a rm is not a simple task. Economists since Bunting (1962) have searched for empirical evidence of monopsony, with the predominant method being the use of concentration ratios, the share of a labor market which a given rm employs. The most commonly examined market in the empirical monopsony literature has been that of nurses in hospitals (Hurd, 1973; Feldman and Scheer, 1982; Hirsch and Schumacher, 1995; Link and Landon, 1975; Adamache and Sloan, 1982; Link and Settle, 1979). This market lends itself to monopsony because nurses have a highly specic form of human capital and there are many rural labor markets where hospitals are the dominant employer. Despite the relatively large literature on this narrow labor market, the concentration ratio approach has yielded mixed results and no clear consensus. | Even if the existence of monopsony power is accepted, estimating the degree of market power possessed by a rm is not a simple task. Economists since Bunting (1962) have searched for empirical evidence of monopsony, with the predominant method being the use of concentration ratios, the share of a labor market which a given rm employs. The most commonly examined market in the empirical monopsony literature has been that of nurses in hospitals (Hurd, 1973; Feldman and Scheer, 1982; Hirsch and Schumacher, 1995; Link and Landon, 1975; Adamache and Sloan, 1982; Link and Settle, 1979). This market lends itself to monopsony because nurses have a highly specic form of human capital and there are many rural labor markets where hospitals are the dominant employer. Despite the relatively large literature on this narrow labor market, the concentration ratio approach has yielded mixed results and no clear consensus. | ||
− | More recently, studies have attempted to directly estimate the average slope of the labor supply curve faced by the rm, which is a distinct concept from the market labor supply elasticity2. Studying the market for nurses, Sullivan (1989) nds evidence of monopsony using a structural approach to measure the dierence between nurses' marginal product of labor and their wages. Examining another market commonly thought to be monopsonistic, the market for schoolteachers, Ransom and Sims (2010) instrument wages with collectively | + | More recently, studies have attempted to directly estimate the average slope of the labor supply curve faced by the rm, which is a distinct concept from the market labor supply elasticity2. Studying the market for nurses, Sullivan (1989) nds evidence of monopsony using a structural approach to measure the dierence between nurses' marginal product of labor and their wages. Examining another market commonly thought to be monopsonistic, the market for schoolteachers, Ransom and Sims (2010) instrument wages with collectively |
1See Mortensen (2003) or Rogerson et al. (2005) for a review of this literature | 1See Mortensen (2003) or Rogerson et al. (2005) for a review of this literature | ||
2The market labor supply elasticity corresponds to the decision of a worker to enter the labor force, while the labor supply elasticity to the rm corresponds to the decision of whether to supply labor to a particular rm. This paper focuses on the rm-level decision. | 2The market labor supply elasticity corresponds to the decision of a worker to enter the labor force, while the labor supply elasticity to the rm corresponds to the decision of whether to supply labor to a particular rm. This paper focuses on the rm-level decision. | ||
2 | 2 | ||
− | approach using German administrative data, Schmieder (2010) nds evidence of a positive sloping labor supply curve through an analysis of new establishments. | + | bargained pay scales and estimate a labor supply elasticity between 3 and 4. In a novel approach using German administrative data, Schmieder (2010) nds evidence of a positive sloping labor supply curve through an analysis of new establishments. |
− | Using a | + | Using a dynamic approach similar to this study, Ransom and Oaxaca (2010) and Hirsch et al. (2010) both separately estimate the labor supply elasticities to the rm of men and women, each nding strong evidence of monopsonistic competition. Ransom and Oaxaca (2010) use data from a chain of grocery stores, and nd labor supply elasticities of about 2.5 for men and 1.6 for women. Hirsch et al. (2010) uses administrative data from Germany to estimate elasticities ranging from 2.5-3.6 and 1.9-2.5 for men and women respectively. Applying this approach to survey data, Manning (2003) nds labor supply elasticities ranging from 0.68 in the NLSY to 1.38 in the PSID. In a developing country context, Brummund (2011) nds strong evidence of monopsony in Indonesian labor markets, estimating labor supply elasticities between .6 and 1. |
− | Utilizing data from the US Census Bureau's Longitudinal Employer Household Dynamics (LEHD) program, I estimate the market-level average labor supply elasticity faced by rms in the US economy, similar to the Hirsch et al. (2010) study using German data. I then extend the approach to estimate rm-level labor supply elasticities. This is accomplished through | + | Utilizing data from the US Census Bureau's Longitudinal Employer Household Dynamics (LEHD) program, I estimate the market-level average labor supply elasticity faced by rms in the US economy, similar to the Hirsch et al. (2010) study using German data. I then extend the approach to estimate rm-level labor supply elasticities. This is accomplished through an extension to the dynamic model of labor supply proposed by Manning (2003). This method allows me to examine the eects of monopsonistic competition on the earnings distribution in great detail, and contributes to the existing literature in a number of ways. First, it is the rst examination of monopsony power using comprehensive administrative data from the US. Second, my particular empirical strategy allows me to examine the distribution of monopsony power which exists in the US, and to provide the rst direct evidence on the negative impact of a rm's market power on earnings. I compare the performance of the market power measures derived in this study to that of the more traditional concentration ratio to illustrate the signicant contribution of the new monopsony models. Finally, I construct a counterfactual earnings distribution in which rms' market power is reduced |
3 | 3 | ||
− | I estimate the average labor supply elasticity to the rm to be approximately | + | in order to demonstrate the impact of imperfect competition on the shape of the earnings distribution. |
+ | I estimate the average labor supply elasticity to the rm to be approximately 1.08. Esti- mates in this range are robust to various modeling assumptions and corrections for endoge- nous mobility. Furthermore, I nd evidence of substantial heterogeneity in the market power possessed by rms, ranging from negligible to highly monopsonistic. While a link between monopsony power and wages has traditionally been assumed (Pigou, 1924), I provide the rst direct evidence of a positive relationship between a rm's labor supply elasticity and the earnings of its workers, estimating that a one-unit increase is associated with a decrease of between .05 and .18 log earnings. I demonstrate that the eect of monopsony power is not constant across workers: unconditional quantile regressions imply that impacts are largest among low paid and negligible among high paid workers. Finally, implications in the inequality literature are addressed through the construction of a counterfactual earnings distribution, which implies that a one standard deviation increase of each rm's labor supply elasticity would decrease the variance of earnings distribution by 9 percent. | ||
The paper is organized as follows, Section 2 describes the denition of market power utilized in this study. Section 3 lays out the theoretical foundation for this study. The data and methods are described in Section 4. Section 5 presents the results and sensitivity analyses, and Section 6 concludes. | The paper is organized as follows, Section 2 describes the denition of market power utilized in this study. Section 3 lays out the theoretical foundation for this study. The data and methods are described in Section 4. Section 5 presents the results and sensitivity analyses, and Section 6 concludes. | ||
2 Discussion of Monopsony Power | 2 Discussion of Monopsony Power | ||
− | The concept of monopsony was rst dened and explored as a model by Robinson ( | + | The concept of monopsony was rst dened and explored as a model by Robinson (1933). In her seminal work, Robinson formulated the analysis which is still taught in undergraduate labor economics courses. Monopsony literally means one buyer, and although the term is most often used in a labor market context, it can also refer to a rm which is the only buyer of an input. |
− | + | ||
4 | 4 | ||
− | nite labor supply elasticity, or upward sloping labor supply curve to the rm. While the classic monopsony model is based on the idea of a single rm as the only outlet for which workers can supply labor, the new framework denes monopsony as any departure from the assumptions of perfect competition. Additionally, the degree of monopsonistic competition may vary signicantly across labor markets, and even across rms within a given labor market | + | It should be pointed out that in the new monopsony framework, the word monopsony is synonymous with the following phrases: monopsonistic competition, imperfect competition, nite labor supply elasticity, or upward sloping labor supply curve to the rm. While the classic monopsony model is based on the idea of a single rm as the only outlet for which workers can supply labor, the new framework denes monopsony as any departure from the assumptions of perfect competition. Additionally, the degree of monopsonistic competition may vary signicantly across labor markets, and even across rms within a given labor market. |
In order to think about what determines a rm's monopsony power, we must consider why we do not observe the predicted behavior from a perfectly competitive model. What gives a rm exibility in oering a wage rather than being forced to oer the market wage? Put another way, why do we not observe workers jumping from job to job whenever they observe a higher paying opportunity for which they are qualied? | In order to think about what determines a rm's monopsony power, we must consider why we do not observe the predicted behavior from a perfectly competitive model. What gives a rm exibility in oering a wage rather than being forced to oer the market wage? Put another way, why do we not observe workers jumping from job to job whenever they observe a higher paying opportunity for which they are qualied? | ||
− | One of the most prominent reasons is that the typical worker does not have a continuous stream of job oers (this point will be discussed further in the theoretical model section). This source of monopsony power has roots in the classic monopsony framework in that, all else held constant, workers in labor markets with more rms are likely to have a greater number of oers. However, this idea takes an overly simplistic view of the boundaries of a given labor market. Most employers are likely operating in many labor markets at any given time. A prestigious university may be competing in a national or international labor market for professors, a regional labor market for its high-level administrators and technical sta, and a local labor market for the low-level service workers. Even if the arrival rate of job oers were the only source of monopsony power, it seems that geographic modeling alone would do a poor job of measuring that power. Another source of monopsony power is imperfect information about job openings (McCall, 1970; Stigler, 1962), which is not completely distinct from the arrival rate of job oers since a decrease in information can | + | One of the most prominent reasons is that the typical worker does not have a continuous stream of job oers (this point will be discussed further in the theoretical model section). This source of monopsony power has roots in the classic monopsony framework in that, all else held constant, workers in labor markets with more rms are likely to have a greater number of oers. However, this idea takes an overly simplistic view of the boundaries of a given labor market. Most employers are likely operating in many labor markets at any given time. A prestigious university may be competing in a national or international labor market for professors, a regional labor market for its high-level administrators and technical sta, and a local labor market for the low-level service workers. Even if the arrival rate of job oers were the only source of monopsony power, it seems that geographic modeling alone would do a poor job of measuring that power. Another source of monopsony power is imperfect information about job openings (McCall, 1970; Stigler, 1962), which is not completely distinct from the arrival rate of job oers since a decrease in information can cause a reduction in job oers. This is a particularly compelling example since studies |
5 | 5 | ||
− | + | such as Hoer and Murphy (1992) and Polachek and Robst (1998) estimate that imperfect information about job prospects depresses wages by approximately ten percent. | |
The costs (both monetary and psychic) associated with changing jobs can also be thought of as giving market power to the rm. Moving costs are typically thought of as a short run cost, particularly when a worker is young. However these costs can grow signicantly when a worker has a family and roots in a community. Consider the scenario of a dual-career family. Two job oers will be needed to induce either of the partners to move, a fact which gives signicant bargaining power to the employers of each partner, particularly the one who is paid less. Additionally, changing jobs means that workers must adjust to a new system which will require at least a small degree of learning on the job. | The costs (both monetary and psychic) associated with changing jobs can also be thought of as giving market power to the rm. Moving costs are typically thought of as a short run cost, particularly when a worker is young. However these costs can grow signicantly when a worker has a family and roots in a community. Consider the scenario of a dual-career family. Two job oers will be needed to induce either of the partners to move, a fact which gives signicant bargaining power to the employers of each partner, particularly the one who is paid less. Additionally, changing jobs means that workers must adjust to a new system which will require at least a small degree of learning on the job. | ||
− | Firm specic human capital also can be thought of as giving market power to the rm, since there is in eect a barrier to leaving a rm when an individual's rm specic capital is large relative to their general human capital. | + | Firm specic human capital also can be thought of as giving market power to the rm, since there is in eect a barrier to leaving a rm when an individual's rm specic capital is large relative to their general human capital. In fact, Wasmer (2006) concludes that markets with substantial search frictions induce workers to overinvest in rm specic human capital. |
− | + | Reputation costs likely also play a large role in the mobility of workers. Potential employ- ers would be very suspicious of hiring a worker who changes jobs the moment he is oered any wage increase. For all of these reasons, and likely many more, workers must be selective with the wage oers they choose to accept, thus leading to a labor market with substantial frictions. | |
As discussed in Manning (2010), another way to think about imperfect competition in the labor market is in terms of the rents received by the employee and the employer. On the worker's side, the rents to a given job match would be the dierence between the current wage (utility) and the worker's opportunity cost, either a wage (utility) from a dierent rm or unemployment benets. Studies such as Jacobson et al. (1993) implicitly estimate these rents by exploring the impacts of exogenous job destruction. This literature estimates wage losses of 20-30 percent, implying signicant rents to employees from a given job match. From the employer's perspective, the rents from the ith job match are the dierence between | As discussed in Manning (2010), another way to think about imperfect competition in the labor market is in terms of the rents received by the employee and the employer. On the worker's side, the rents to a given job match would be the dierence between the current wage (utility) and the worker's opportunity cost, either a wage (utility) from a dierent rm or unemployment benets. Studies such as Jacobson et al. (1993) implicitly estimate these rents by exploring the impacts of exogenous job destruction. This literature estimates wage losses of 20-30 percent, implying signicant rents to employees from a given job match. From the employer's perspective, the rents from the ith job match are the dierence between | ||
6 | 6 | ||
(MPi − wi) and (MPj − wj), where j is the next worker who would be hired if worker i leaves the rm. This is a harder quantity to measure empirically, but can be approximated (assuming that the marginal product is the same for workers i and j) by hiring and training costs. The estimates of hiring and training costs as a fraction of total wages paid tend to be in the range of 3-7 percent (Oi, 1962; Abowd and Kramarz, 2003). The ratio of worker rents to employer rents can be thought of as a measure of the rm's market power. If the worker's opportunity cost is high relative to her employer's opportunity cost, then the employer will be able to extract a large amount of the surplus from the job match. However, if the converse is true, the worker will be in the position of power. | (MPi − wi) and (MPj − wj), where j is the next worker who would be hired if worker i leaves the rm. This is a harder quantity to measure empirically, but can be approximated (assuming that the marginal product is the same for workers i and j) by hiring and training costs. The estimates of hiring and training costs as a fraction of total wages paid tend to be in the range of 3-7 percent (Oi, 1962; Abowd and Kramarz, 2003). The ratio of worker rents to employer rents can be thought of as a measure of the rm's market power. If the worker's opportunity cost is high relative to her employer's opportunity cost, then the employer will be able to extract a large amount of the surplus from the job match. However, if the converse is true, the worker will be in the position of power. | ||
A relatively new branch of labor economics which focuses on the initial labor market conditions when a worker enters the labor market may also provide insight into the mobility of workers. A number of studies (Oyer, 2006, 2008; Genda and Kondo, 2010; Kahn, 2010) nd persistent and negative wage eects from entering the labor market in a bad economy, lasting for at least 20 years. These persistent eects provide further evidence that there are signicant long-run frictions in the economy. | A relatively new branch of labor economics which focuses on the initial labor market conditions when a worker enters the labor market may also provide insight into the mobility of workers. A number of studies (Oyer, 2006, 2008; Genda and Kondo, 2010; Kahn, 2010) nd persistent and negative wage eects from entering the labor market in a bad economy, lasting for at least 20 years. These persistent eects provide further evidence that there are signicant long-run frictions in the economy. | ||
− | Finally, while a worker's earnings represent an important market outcome, it is important to remember that wages make up only a part of the total compensation to the worker. The true quality of a job match has many dimensions, such as benets, working conditions, and countless other | + | Finally, while a worker's earnings represent an important market outcome, it is important to remember that wages make up only a part of the total compensation to the worker. The true quality of a job match has many dimensions, such as benets, working conditions, and countless other compensating dierentials. The interaction of monopsony with these non-wage goods should be explored in future research. |
3 Theoretical Model | 3 Theoretical Model | ||
A central feature of perfect competition is the law of one wage, that all workers of equal ability should be paid the same market clearing wage. In an attempt to explain how wage dispersion can indeed be an equilibrium outcome, Burdett and Mortensen (1998) develop a model of the economy in which employers post wages based on the wage-posting behavior | A central feature of perfect competition is the law of one wage, that all workers of equal ability should be paid the same market clearing wage. In an attempt to explain how wage dispersion can indeed be an equilibrium outcome, Burdett and Mortensen (1998) develop a model of the economy in which employers post wages based on the wage-posting behavior | ||
7 | 7 | ||
− | of competing employers. Even assuming equal ability for all workers, wage dispersion is an equilibrium outcome as long as one assumes that the arrival rate of job oers is positive but nite (perfect competition characterizes the limiting case, as the arrival rate tends to innity). | + | of competing employers. Even assuming equal ability for all workers, wage dispersion is an equilibrium outcome as long as one assumes that the arrival rate of job oers is positive but nite (perfect competition characterizes the limiting case, as the arrival rate tends to innity). While I do not explicity estimate the Burdett and Mortensen model in this paper, the intuition of monopsony power derived from search frictions is central to this study. See Kuhn (2004) for a critique of the use of equilibrium search models in a monopsony context. |
The Burdett and Mortensen model of equilibrium wage dispersion | The Burdett and Mortensen model of equilibrium wage dispersion | ||
− | Assume there are Mt equally productive workers (where productivity is given by p), each gaining utility b from leisure. Further assume there are Me constant returns to scale rms which are innitesimally small when compared to the entire economy. A rm sets wage w to maximize steady-state prots π = (p-w)N(w | + | Assume there are Mt equally productive workers (where productivity is given by p), each gaining utility b from leisure. Further assume there are Me constant returns to scale rms which are innitesimally small when compared to the entire economy. A rm sets wage w to maximize steady-state prots π = (p-w)N(w) where N(w) represents the supply of labor to the rm. Also dene F(w) as the cdf of wage oers observed in the economy, and f(w) is the corresponding pdf. All workers within a rm must be paid the same wage. Employed workers will accept a wage oer w' if it is greater than their current wage w, and non- employed workers will accept w' if w'b where b is their reservation wage. Wage oers are drawn randomly from the distribution F(w), and arrive to all workers at rate λ. Assume an exogenous job destruction rate δ, and that all workers leave the job market at rate δ to be replaced in nonemployment by an equivalent number of workers. RN denotes The recruitment ow and separation rate functions are given by: |
− | Burdett and Mortensen (1998), or alternatively Manning (2003), show that in this econ- omy, as long as λ is positive and nite, there will be a nondegenerate distribution of wages even when all workers are equally productive. As λ tends to zero, the wage distribution will | + | R(w) = RN + λ |
− | + | w 0 | |
+ | f(x)N(x)dx (1) | ||
+ | s(w) = δ + λ(1 − F (w)) (2) | ||
+ | Burdett and Mortensen (1998), or alternatively Manning (2003), show that in this econ- omy, as long as λ is positive and nite, there will be a nondegenerate distribution of wages even when all workers are equally productive. As λ tends to zero, the wage distribution will | ||
8 | 8 | ||
− | where R(w | + | collapse to the monopsony wage, which in this particular economy would be the reservation wage b. As λ tends to innity the wage distribution will collapse to the perfectly competitive wage, the marginal product of labor p. |
− | + | Note that the following primarily relies on the model presented in Manning (2003), and incorporates a key insight from the recent working paper by Depew and Sorensen (2011) to derive the least restrictive formula for the labor supply elasticity facing the rm currently in the literature. We can recursively formulate the supply of labor to a rm with the following equation, where R(w) is the ow of recruits to a rm and s(w) is the separation rate. | |
− | ε = | + | Nt(w) = Nt−1(w)[1 − st−1(w)] + Rt−1(w) (3) |
− | way | + | Equation (3) formalizes the denitionally true statement that a rm's employment this period is equal to the fraction of workers from last period who stay with the rm plus the number of new recruits. Noting that Nt = γNt−1 where γ is the rate of employment growth between period t-1 and t, we can rewrite Equation (3) as |
− | ε= | + | Nt(w) = Rt(w) (4) 1 − (1 − st(w)) 1 |
− | + | γt Taking the natural log of each side, multiplying by w, and dierentiating we can write the | |
− | + | elasticity of labor supply, ε, at time t as a function of the long-run elasticities of recruitment and separations, as well as the contemporary separation and growth rates. | |
+ | ε =ε −ε st(w) (5) t R S γt + st(w) − 1 | ||
+ | We can further decompose the recruitment and separation elasticities in the following way | ||
+ | ε =θRεE +(1−θR)εN −θSεE sEt (w) −(1−θS)εN sNt (w) (6) t R R S γ t + s Et ( w ) − 1 S γ t + s Nt ( w ) − 1 | ||
9 | 9 | ||
− | + | Where the elasticity of recruitment has been broken down into the elasticity of recruit- ment of workers from employment (εER) and the elasticity of recruitment of workers from nonemployment (εNR ). Similarly the elasticity of separation has been decomposed into the elasticity of separation to employment (εES ) and the elasticity of separation to nonemploy- ment (εNS ). θRand θS represent the share of recruits from employment and the share of separations to employment respectively. | |
− | εNR = εER − wθ‘R(w)/θR(w)(1 − θR(w)) ( | + | While there are established methods for estimating separation elasticities with standard job-ow data, recruitment elasticities are not identied without detailed information about every job oer a worker receives. Therefore, it would be helpful to express the elasticities of recruitment from employment and noemployment as functions of estimable quantities. |
− | + | Looking rst at the elasticity of recruitment from employment, we can write the recruit- ment from employment function and its derivative as | |
+ | RE(w) ∂w | ||
+ | RE(w) = λ | ||
+ | w 0 | ||
+ | f(x)N(x)dx (7) | ||
+ | ∂RE(w) = λf(w)N(w) (8) ∂w | ||
+ | Combining Equations (4), (7), and (8), along with the denition of an elasticity (εER = w ∂RE(w)), we get: | ||
+ | εE = wλf(w) (9) R 1 + s Et ( w ) − 1 | ||
+ | γt γt In dealing with the numerator, note that the the derivative of the separation to employ- | ||
+ | ment function, sE (w) = λ(1 − F (w)), is ∂sE(w) = −λf(w) (10) | ||
+ | ∂w | ||
+ | Combining equations (9), (10), and the denition of an elasticity (εE = w ∂sE(w)), we s sE(w) ∂w | ||
+ | 10 | ||
+ | can write the elasticity of recruitment from employment as a function of estimable quantities: | ||
+ | εE = −εERsEt (w) (11) R 1 + s Et ( w ) − 1 | ||
+ | γt γt Next, Manning (2003, p. 100) notes that the elasticity of recruitment from nonemploy- | ||
+ | ment can be written as | ||
+ | εNR = εER − wθ‘R(w)/θR(w)(1 − θR(w)) (12) | ||
+ | This is derived from the simple denition of θR, the share of total recruits which come from employment, which implies RN = RE(1 − θR)/θR, where RN and RE are the recruits from nonemployment and employment respectively. Taking the natural log of each side of this relation and dierentiating yields the relation depicted in Equation (12). The second term on the right-hand side of Equation (12) can be thought of as the bargaining premium that an employee receives from searching while currently employed. Thus, the labor supply elasticity to the rm can be written as a function of both separation elasticities, the premium to searching while employed, and the calculated separation and growth rates. To my knowledge, no other study has estimated this model before. | ||
In an economy where the arrival rate of job oers is nite (and thus the labor supply elasticity is nite) rms are not bound by market forces to pay workers their marginal product of labor. The model presented above implies that, even in a world where all rms and individuals are identical, a decrease in the arrival rate of job oers will both lower the average wage and increase inequality. To see how a rm's labor supply elasticity aects the wage it pays, consider a prot-maximizing rm which faces the following objective function: | In an economy where the arrival rate of job oers is nite (and thus the labor supply elasticity is nite) rms are not bound by market forces to pay workers their marginal product of labor. The model presented above implies that, even in a world where all rms and individuals are identical, a decrease in the arrival rate of job oers will both lower the average wage and increase inequality. To see how a rm's labor supply elasticity aects the wage it pays, consider a prot-maximizing rm which faces the following objective function: | ||
− | + | M ax Π = pQ(L) − wL(w) (13) w | |
P is the price of the output produced according to the production function Q. The | P is the price of the output produced according to the production function Q. The | ||
− | choice of wage w determines the labor supplied to the rm L. Taking rst order conditions, | + | 11 |
− | substituting ε = w ∂L(w) , and solving for w yields: L(w) ∂w | + | choice of wage w determines the labor supplied to the rm L. Taking rst order conditions, substituting ε = w ∂L(w) , and solving for w yields: |
− | + | L(w) ∂w | |
− | w = pQ′(L) ( | + | w = pQ′(L) (14) 1+1 |
ε | ε | ||
− | The numerator in Equation ( | + | The numerator in Equation (14) is simply the marginal product of labor, and ε is the labor supply elasticity faced by the rm. It is easy to see that in the case of perfect competition (ε = ∞) that the wage is equal to the marginal product of labor, but the wage is less than then marginal product for all 0 < ε < ∞. |
Every empirical study in the new monopsony literature attempts to estimate the labor supply elasticity to the rm at the market level. In other words, they measure the (rm-size weighted) average slope of each rm's supply curve in the market. In a highly competitive market we would expect these elasticities to be very large numbers. Among the contributions of this paper is to separately estimate each rm's labor supply elasticity rather than a market average. | Every empirical study in the new monopsony literature attempts to estimate the labor supply elasticity to the rm at the market level. In other words, they measure the (rm-size weighted) average slope of each rm's supply curve in the market. In a highly competitive market we would expect these elasticities to be very large numbers. Among the contributions of this paper is to separately estimate each rm's labor supply elasticity rather than a market average. | ||
4 Data and Methodology | 4 Data and Methodology | ||
Data | Data | ||
− | The Longitudinal Employer Household Dynamics (LEHD) data are built primarily from Un- employment Insurance (UI) wage records, which cover approximately 98 percent of wage and salary payments in private sector non-farm jobs. Information about the rms is constructed from the Quarterly Census of Employment and Wages (QCEW). The LEHD infrastructure allows users to follow both workers and rms over time, as well as to identify workers who share a common employer. | + | The Longitudinal Employer Household Dynamics (LEHD) data are built primarily from Un- employment Insurance (UI) wage records, which cover approximately 98 percent of wage and salary payments in private sector non-farm jobs. Information about the rms is constructed from the Quarterly Census of Employment and Wages (QCEW). The LEHD infrastructure allows users to follow both workers and rms over time, as well as to identify workers who share a common employer. Firms in these data are dened at the state level, which means that a Walmart in Florida and a Walmart in Georgia would be considered to be dierent rms. However, all Walmarts in Florida are considered to be part of the same rm. These |
− | + | ||
− | + | ||
− | + | ||
− | + | ||
− | + | ||
− | + | ||
12 | 12 | ||
+ | data also include demographic characteristics of the worker and basic rm characteristics, obtained through administrative record and statistical links. For a complete description of these data, see Abowd et al. (2009). | ||
+ | My sample consists of quarterly observations on earnings and employment for 47 states between 1985 and 20083. I make several sample restrictions in an attempt to obtain the most economically meaningful results, analyses without these restrictions are presented as a robustness check later in the paper. These restrictions are necessary in large part because the earnings data are derived from tax records, and thus any payment made to an individual, no matter how small, will appear in the sample. As a consequence, there are many job spells which appear to last only one quarter, but are in fact one-time payments which do not conform with the general view of a job match between a rm and worker. | ||
+ | First, I only include an employment spell in the sample if at some point it could be considered the dominant job, dened as paying the highest wage of an individual's jobs in a given quarter4. I also remove all spells which span fewer than three quarters.5 This sample restriction is related to the construction of the earnings variable. Since the data do not contain information on when in the quarter an individual was hired/separated, the entries for the rst and last quarters of any employment spell will almost certainly underestimate the quarterly earnings rate (unless the individual was hired on the rst day or left employment on the last day of a quarter). Thus, in order to get an accurate measurement of the earnings rate I must observe an individual in at least one quarter other than the rst or last of an employment spell. I remove job spells which have average earnings greater than $1 million per quarter and less than $100 per quarter, which corresponds approximately to the top and | ||
+ | 3The states not in the sample are Connecticut, Massachusetts, and New Hampshire. Not all states are in the LEHD infrastructure for the entire time-frame, but once a state enters it is in the sample for all subsequent periods. Figure 1 presents the coverage level of the US economy reproduced from Abowd and Vilhuber (2011). | ||
+ | 4This formulation allows an individual to have more than one dominant job in a given quarter. The rationale behind this denition is that I wish to include all job spells where the wage is important to the worker. The vast majority of job spells in my sample, 89.9 percent, have 0 or 1 quarters of overlap with other job spells. Restricting the dominant job denition to only allow one dominant job at a given time does not alter the reported results. | ||
+ | 5The relaxation of this assumption does not appreciably alter any of the reported results. 13 | ||
+ | bottom 1 percent of observations Additionally, I limit the analysis to rms with 100 total employment spells of any length | ||
+ | over the lifespan of the rm. For the full-economy monopsony model, these sample re- strictions yield a nal sample of approximately 149,710,000 unique individuals who had 325,630,000 total employment spells at 670,000 dierent rms. Additionally, for analyses using the rm-level measure of the labor supply elasticity, only rms which have greater than 25 separations to employment, 25 separations to unemployment, and 25 recruits from employment over the lifespan of the rm are considered. This reduces the analysis sample to approximately 121,190,000 unique individuals having 267,310,000 employment spells at 340,000 unique rms. | ||
Empirical Strategy | Empirical Strategy | ||
The primary reason for the small empirical literature on monopsony is a lack of high quality data. In order to identify a rm's market power, the researcher must have a credible rm- level instrument for each rm studied or detailed employer-employee linked data to identify worker ows. I employ the latter approach in this study since nding a credible instrument for nearly every rm in the US is unlikely. The construction of the market power measures most closely represents an augmented rm-level implementation of the methodology proposed in Manning (2003). | The primary reason for the small empirical literature on monopsony is a lack of high quality data. In order to identify a rm's market power, the researcher must have a credible rm- level instrument for each rm studied or detailed employer-employee linked data to identify worker ows. I employ the latter approach in this study since nding a credible instrument for nearly every rm in the US is unlikely. The construction of the market power measures most closely represents an augmented rm-level implementation of the methodology proposed in Manning (2003). | ||
I rst describe in detail how the market power measures are calculated, followed by a description of how they are used to examine the US earnings distribution. | I rst describe in detail how the market power measures are calculated, followed by a description of how they are used to examine the US earnings distribution. | ||
Location-Based Measures | Location-Based Measures | ||
− | I construct an overall measure of the percent of the industry-specic labor market that each rm employs (Number of workers at rm i/number of workers in rm i's county and in rm i's industry) using North American Industry Classication System (NAICS) industry denitions. While this variable is far from a perfect measure of an employer's power to | + | I construct an overall measure of the percent of the industry-specic labor market that each rm employs (Number of workers at rm i/number of workers in rm i's county and in rm i's industry) using North American Industry Classication System (NAICS) industry denitions. While this variable is far from a perfect measure of an employer's power to |
− | + | ||
− | + | ||
− | + | ||
− | + | ||
− | + | ||
− | + | ||
− | + | ||
14 | 14 | ||
− | + | set wages, it has several advantages over the dynamic measures to be used later in the paper. Both the construction of these measures and the regression estimates using them are transparent. Endogeneity, misspecied equations, etc. are of less concern in the construction of these labor concentration measures, and the interpretation of the regression coecients on these variables is straightforward. This analysis corresponds to the traditional concentration ratio approach of analyzing labor market power. | |
− | + | Dynamic Measure | |
− | + | The simplest way to estimate the labor supply elasticity to the rm would be to regress the natural log of rm size on the natural log of rm wages. However, even when controlling for various demographic characteristics, this is deemed to produce a potentially biased estimate6. I therefore rely on estimating parameters presented in the theoretical section which are plausibly identied, and then combine them using results from Manning (2003) and equation (6) to produce an estimate of the labor supply elasticity to the rm. | |
− | + | To my knowledge, only Hirsch et al. (2010) has used a similar, but considerably more restrictive, method with administrative data which yielded an economy-wide estimate of the average labor supply curve facing the rm. Manning (2003) also estimates an economy-wide measure of the degree of monopsony using surveys such as the National Longitudinal Survey of Youth (NLSY) 1979. One of the major contributions of this paper is that I estimate the labor supply elasticities for each rm, rather than the average over the whole economy. Additionally, these prior studies imposed a steady-state assumption on their model, which the model in this paper does not impose. Estimating the labor supply elasticities at the rm level does have several advantages. First, the estimation of each of the elasticity components is much more exible than even the least constrained specications of Hirsch et al. (2010). Second, I will be able to use the measures as an explanatory variable, and can test a number | |
− | + | 6The rm size-wage premium is a well known result in the labor economics literature, and is often attributed to non-monopsony related factors such as economies of scale increasing the productivity, and thus the marginal product, of workers at large rms | |
− | + | ||
15 | 15 | ||
− | + | of dierent models. Finally, I will be able to examine the eect of market power on earnings at each point in the market power distribution, rather than examining only the average eect. This is particularly important because theory predicts signicant nonlinear eects relating to the labor supply elasticity and a rm's ability to mark down wages (Pigou, 1924). However, this strategy has the drawback that I am unable to estimate the relevant parameters, and thus the labor supply elasticity, for the smallest rms (sample restrictions are discussed in the data section). | |
− | + | According to the results presented in the theoretical model section, three quantities must be estimated in order to construct the labor supply elasticity measure, (εES , εNS and wθR′ (w)/θR(w)(1 − θR(w))), as well as the calculated separation and growth rates for each rm. Each of the following models will be run separately for every rm in the sample (as well as on the whole sample for comparison purposes), where the unit of observation is an employment spell, thus one individual can appear in multiple rm's models. Looking rst at the separation elasticities, I model separations to nonemployment as a Cox proportional hazard model given by | |
− | + | λN (t|βN,seplog(earnings)i + XiγN,sep) = λ0(t) exp(βN,seplog(earnings)i + XiγN,sep) (15) | |
+ | where λ() is the hazard function, λ0 is the baseline hazard, t is the length of employment, log(earnings) is the natural log of individual i's average quarterly earnings, and X is a vector of explanatory variables including gender, race, age, education, and year control variables (industry controls are also included in the full-economy model). While the entire sample will be used, workers who transition to a new employer or who are with the same employer at the end of the data series are considered to have a censored employment spell. In this model, the parameter β represents an estimate of the separation elasticity to nonemployment. In an analogous setting, I model separations to employment as | ||
16 | 16 | ||
− | model cross-sectional variation in the level of earnings is used to identify the labor supply elasticity. In a rm-specic model, however, the labor supply elasticity of rm A does not mechanically depend on the level of earnings at rm B. This eciency wage hypothesis will be directly tested. | + | λE(t|βE,seplog(earnings)i +XiγE,sep)=λ0(t)exp(βE,seplog(earnings)i +XiγE,sep) (16) |
+ | with the only dierence being that the sample is restricted to those workers who do not have a job transition to nonemployment. As before, β represents an estimate of the sep- aration elasticity to employment. To estimate the third quantity needed for equation (6), wθ‘R(w)/θR(w)(1 − θR(w)), Manning (2003) shows that this is equivalent to the coecient on log earnings when estimating the following logistic regression | ||
+ | Prec = exp(βE,reclog(earnings)i + XiγE,rec) (17) 1 + exp(βE,reclog(earnings)i + XiγE,rec) | ||
+ | where the dependent variable takes a value of 1 if a worker was recruited from employment and 0 if they were recruited from nonemployment. To enable this coecient to vary over time, log earnings is interacted with time dummies. The same explanatory variables used in the separation equations are used in this logistic regression. At this point the results listed in the theoretical section can be used (along with calculating the share of recruits and separations to employment, separation rates, and growth rates for each rm) in conjunction with equation (6) to produce an estimate of the labor supply elasticity facing each rm. 7 | ||
+ | To provide some intuition on the models being estimated, consider the analysis of sepa- rations to employment. A large (in absolute value) coecient on the log earnings variable implies that a small decrease in an individual's earnings will greatly increase the probability of separating in any given period. In a perfectly competitive economy, we would expect this coecient to be innitely high. Similarly, a very small coecient implies that the em- ployer can lower the wage rate without seeing a substantial decline in employment. One concern with this procedure is that this measure of monopsony power is actually proxying | ||
+ | 7Each equation was also estimated with an indicator variable for whether the employment spell was in progress at the beginning of the data window to correct for potential bias of truncated records. Additionally, all models were reestimated using only job spells for which the entire job spell was observed, with no substantial dierences observed betweeen these models. | ||
+ | 17 | ||
+ | for high-wage rms, reecting an eciency wage view of the economy where rms pay a wage considerably above the market wage in exchange for lower turnover. This is much more of a concern in the full economy estimate of the labor supply elasticity to the rm found elsewhere in the literature than in my rm-level estimation since the models in this paper are run separately by rm. The logic behind this dierence is that in the full economy model cross-sectional variation in the level of earnings is used to identify the labor supply elasticity. In a rm-specic model, however, the labor supply elasticity of rm A does not mechanically depend on the level of earnings at rm B. This eciency wage hypothesis will be directly tested. | ||
Analysis | Analysis | ||
In addition to the full-economy models of monopsony, I include the concentration ratio and rm-level labor supply elasticity measures in earnings regressions. This provides direct evidence of the eect of rm market power on earnings, a feature not possible in the full- economy models. Additionally, it serves as a test of the eciency wage hypothesis, which predicts that rms with low estimated labor supply elasticities will pay the highest wages. The main focus of this paper is on this model, explicitly written as: | In addition to the full-economy models of monopsony, I include the concentration ratio and rm-level labor supply elasticity measures in earnings regressions. This provides direct evidence of the eect of rm market power on earnings, a feature not possible in the full- economy models. Additionally, it serves as a test of the eciency wage hypothesis, which predicts that rms with low estimated labor supply elasticities will pay the highest wages. The main focus of this paper is on this model, explicitly written as: | ||
− | log(quarterly earningsij) = βmarketpowerj + γXij + δYj + θZi + εij ( | + | log(quarterly earningsij) = βmarketpowerj + γXij + δYj + θZi + εij (18) |
− | The dependent variable is the natural log of individual i's quarterly earnings in employ- ment spell j. The market power variable represents rm j's estimated labor supply elasticity or the share of the local working population employed at the rm. X is a vector of person characteristics, which may vary by the employment spell, including age, age-squared, tenure (quarters employed at rm), tenure-squared, | + | The dependent variable is the natural log of individual i's quarterly earnings in employ- ment spell j. The market power variable represents rm j's estimated labor supply elasticity or the share of the local working population employed at the rm. X is a vector of person and rm characteristics, which may vary by the employment spell, including age, age-squared, tenure (quarters employed at rm), tenure-squared, education8, gender, race, ethnicity, year |
− | + | 8Reported educational attainment is only available for about 10 percent of the sample, although sophis- ticated imputations of education are available for the entire sample. The results presented in this paper correspond the the full sample of workers (reported education and imputed education). All models were also run on the sample with no imputed data, and no substantive dierences were observed. In particular, since the preferred specication includes person xed-eects, and thus educational attainment drops out of the | |
− | + | 18 | |
+ | eects, indicator variables for the two-digit NAICS sector, and the size (employment) of the rm. Y is a vector of rm xed-eects, Z is a vector of person xed-eects, and ε is the error term. Time-invariant characteristics in X are excluded in models with person or rm xed-eects. | ||
Finally, to examine whether there is a disproportionate impact of imperfect competition on workers near the bottom of the earnings distribution, I construct a counterfactual earnings distributions in which each rm's labor supply elasticity is increased. The counterfactual distribution is constructed according to the unconditional quantile approach decomposition suggested in Firpo et al. (2010). Unconditional quantile regression, rst introduced in Firpo et al. (2009), estimates the parameters of a regression model as they relate to the quantiles of the dependent variable. This contrasts with traditional quantile regression, which estimates parameters corresponding to the conditional (on the included regressors) quantiles of the dependent variable. The unconditional quantile approach is most advantageous in models with relatively low R-squared (i.e. all wage regressions) since the quantiles of y are most likely to diverge from the quantiles of y-hat (predicted dependent variable) in this scenario. | Finally, to examine whether there is a disproportionate impact of imperfect competition on workers near the bottom of the earnings distribution, I construct a counterfactual earnings distributions in which each rm's labor supply elasticity is increased. The counterfactual distribution is constructed according to the unconditional quantile approach decomposition suggested in Firpo et al. (2010). Unconditional quantile regression, rst introduced in Firpo et al. (2009), estimates the parameters of a regression model as they relate to the quantiles of the dependent variable. This contrasts with traditional quantile regression, which estimates parameters corresponding to the conditional (on the included regressors) quantiles of the dependent variable. The unconditional quantile approach is most advantageous in models with relatively low R-squared (i.e. all wage regressions) since the quantiles of y are most likely to diverge from the quantiles of y-hat (predicted dependent variable) in this scenario. | ||
− | Under this approach, unconditional quantile regressions are performed on every 5th quan- tile of the earnings distribution using the same model as Equation ( | + | Under this approach, unconditional quantile regressions are performed on every 5th quan- tile of the earnings distribution using the same model as Equation (18). The estimated coecients on the labor supply elasticity variable from each regression will then be used to simulate the impact of a one unit increase in the labor supply elasticity to the rm on earnings in the associated quantile. |
5 Results | 5 Results | ||
Summary Statistics | Summary Statistics | ||
− | Table 1 reports summary statistics from my analysis sample. Since the unit of observation is the employment spell, and only dominant jobs are included, some statistics deviate slightly from typical observational studies of the labor market (such as a nearly even split of job spells between men and women). The average employment spell lasts about two and a half years, with | + | Table 1 reports summary statistics from my analysis sample. Since the unit of observation is |
− | + | the employment spell, and only dominant jobs are included, some statistics deviate slightly | |
− | + | model, this is of little concern. | |
− | an individual separated to employment or nonemployment, and therefore the proportion of separations to employment is slightly higher than comparable statistics reported in Manning (2003). | + | 19 |
− | Also of note are the employment concentration ratios, with the average rm employing roughly 9 percent of their county's industry specic labor force. | + | from typical observational studies of the labor market (such as a nearly even split of job spells between men and women). The average employment spell lasts about two and a half years, with more than sixty percent of spells resulting from a move from another job. The quarterly nature of the LEHD data make it dicult to precisely identify9 whether an individual separated to employment or nonemployment, and therefore the proportion of separations to employment is slightly higher than comparable statistics reported in Manning (2003). |
+ | The average rm in my sample employs nearly 3000 workers and hires almost 500 in a given quarter. Several qualications must be made for these statistics. First, the distribu- tions are highly skewed, with the median rm employing only 400 and hiring 75 in a given quarter. Second is that statistics are not point in time estimates, but rather totals through- out an entire quarter. Finally, remember that these are at the rm (state-level) rather than at the establishement (individual unit) level. Also of note are the employment concentration ratios, with the average rm employing roughly 9 percent of their county's industry specic labor force. | ||
Location-Based Measure | Location-Based Measure | ||
As previously noted, many studies have attempted to search for evidence of monopsony in the labor market through the use of concentration ratios. While this approach was the best available given prior data constraints, it assumes that monopsony power is derived only from geographical constraints. | As previously noted, many studies have attempted to search for evidence of monopsony in the labor market through the use of concentration ratios. While this approach was the best available given prior data constraints, it assumes that monopsony power is derived only from geographical constraints. | ||
− | Table 2 presents the estimated impact of a ten percentage point increase in the concentra- tion ratio in various specications of Equation ( | + | Table 2 presents the estimated impact of a ten percentage point increase in the concentra- tion ratio in various specications of Equation (18). These results suggest that, in general, a rm's geographic dominance does not appear to signicantly alter the wage bill it pays. Note |
+ | 9The denition used in this paper requires an individual to have no reported earnings for an entire quarter following an employment spell to be dened as a separation to nonemployment, with all other separations coded as a separation to employment. This denition was chosen because it lead to the most conservative (least monopsonistic) results, although the dierences were small. The other methods tried involved imputing the time during the quarter at which employment stopped/started based on a comparison of the earnings reported in the last/rst quarter to a quarter in which I know the individual worked the entire quarter. | ||
+ | 20 | ||
+ | that when the models are run separately by North American Industry Classication System (NAICS) sector, as depicted in Table 3, there is evidence that rms with high concentration ratios in certain industries (such as the utilities sector) pay slightly lower wage bills. How- ever, the eect sizes are small relative to the observed distribution of concentration ratios. Given the small results, and the fact that the industry-specic eects seem to be centered around zero, it seems plausible to conclude that geographic constraints in the labor market play at most a small role in wage determination for the average worker. | ||
Full-Economy Model | Full-Economy Model | ||
− | I rst compute the average labor supply elasticity to the rm prevailing in the economy by estimating Equations ( | + | I rst compute the average labor supply elasticity to the rm prevailing in the economy by estimating Equations (15)-(17) on a pooled sample of all (dominant) employment spells, and combining the results according to Equation (6). Table 4 presents the output of a several specications of the full-economy monopsony model. The estimated elasticities range from 0.76 to 0.82 depending on the specication (inclusion of xed eects, etc.). These elasticities are certainly on the small side, implying that at the average rm a wage cut of one percent would only reduce employment by .8 percent. However, this magnitude is still within the range observed by Manning (2003) in the NLSY79. Additionally, even the inclusion of xed- eects still puts many more restrictions on the parameter estimates than separate estimations for each rm. Based on a comparison of the full-economy model and the rm-level model presented in the next section, the failure to fully saturate the full economy model likely produces downward biased estimates. A detailed discussion of factors which may attenuate these estimates, as well as structural reasons we should expect these results from US data, is given in the Discussion and Extensions section. |
− | + | ||
− | + | ||
− | combining the results according to Equation ( | + | |
Firm-Level Measure | Firm-Level Measure | ||
− | Table 5 | + | Table 5 presents the elasticities estimated through Equations (15)-(17). The rst four columns report the average rm-level elasticities of recruitment from employment and nonem- |
− | + | ||
− | + | ||
− | + | ||
− | + | ||
− | + | ||
− | + | ||
− | + | ||
21 | 21 | ||
+ | ployment, and the separation elasticities to employment and nonemployment respectively. The nal column combines these elasticities, along with the calculated shares of separa- tions/recruits to/from employment to obtain the labor supply elasticity. Of note is that the labor supply elasticity does not appear to depend substantially on the regressors included in the model. The rst three rows report only the long-run elasticities, while the nal row describes the elasticities when each quantitiy is allowed to vary over time. Not accounting for the time-varying nature of the labor supply elasticity, as has been common in the prior literature, appears to underestimate its magnitude by 20%. | ||
+ | Table 6 displays information about the distribution of rms' labor supply elasticities, and Figure 2 presents a kernel density plot of the market power measure10. This distribution is constructed by separately estimating Equations (15)-(17) for each rm. While the median supply elasticity (0.75) is close to the estimate from the full-economy model, there appears to be signicant variation in the market power possessed by rms. I estimate a mean labor supply elasticity of 1.08, however, there are many rms (about 3 percent of the sample) with labor supply elasticities greater than 5. It appears that while there is a nontrivial fraction of rms whose behavior approximates a highly competitive labor market, the majority of the distribution is characterized by signicant frictions.While not surprising, to my knowledge this is the rst documentation of the large discrepancy in rms' ability to set the wage. | ||
+ | Table 7 reports average labor supply elasticities broken down by NAICS sector. I nd signicant variation in these estimates across industries. The manufacturing sector appears to enjoy the least wage-setting power, with a labor supply elasticity of 1.82. As manufacturing is likely the most heavily unionized of all sectors, this result is not surprising. By contrast, rms in the health care (0.78) and administrative support (0.72) sectors seem to wield the greatest wage-setting power. This is consistent with the focus on the healthcare market among economists investigating monopsony power. | ||
+ | The central focus of this paper is presented in Table 8, which estimates various speci- | ||
+ | 10For condentiality reasons, the long right tail of the kernel density plot has been suppressed | ||
+ | 22 | ||
+ | cations of Equation (18) in order to measure the impact of market power on the earnings distribution. Unconditionally, a one unit increase in the labor supply elasticity increases earnings by .13 log points. Even the specications with the most detailed controls estimate a strong positive relationship between a rm's labor supply elasticity and the earnings of its workers. These estimates range from an impact of 0.05 log points in the model with person xed-eects to an impact of 0.18 log points with a full compliment of person and rm ef- fects11. This is an important result for the new monopsony literature, because it rules out the possibility that the dynamic model identication strategy is actually identifying high-wage rms whose employees do not often switch jobs due to the high wages. | ||
+ | There is good reason to believe that the estimates in Table 8 are lower bounds of the true impact of rm market power on earnings. Each labor supply elasticity is a weighted average of many more precisely dened elasticities which would more accurately measure a rm's market power over a particular individual. For example, rms likely face dierent supply elasticities for every occupation, and potentially dierent elasticities across race and gender groups. From a measurement error perspective, regressing the log of earnings on the average labor supply elasticity to the rm would attenuate the estimates relative to the ideal scenario where I could separately identify every occupation specic elasticity. | ||
+ | While these results are clear evidence that rms exercise their market power, there is reason to believe that rms are not using the majority of labor market power available to them. Bronfenbrenner (1956) rst made this point, arguing that most rms in our economy likely faced upward sloping labor supply curves but that these rms would not pay substan- tially less than the competitive wage. This could be because rm's choose to maximize some function of prots and other quantities such as public perception and worker happiness. | ||
+ | To test this assertion, we can calculate what the coecient on labor supply elasticity should be in an economy where rms only maximize prots and the mean labor supply | ||
+ | 11All models were also run using the time-invariant long run labor supply elasticity rather than the time varying measure. The results of each model which could be run using this measure (rm eects could not be included) were nearly identical. | ||
+ | 23 | ||
+ | elasticity is 1.08. This is done by taking the derivative of the coecient on the marginal | ||
+ | product of labor in Equation (14) and dividing this by the coecient itself, a formula which | ||
+ | simplies to 1 . Evaluating this at a labor supply elasticity of 1.08 implies that if rms ε2 +ε | ||
+ | were exploiting all of their market power then the coecient on labor supply elasticity in Table 8 should be about 0.45, roughly 2.5 times greater than the estimated 0.18. Even assuming a high degree of measurement error in the assignment of the average labor supply elasticity to all workers in a rm would likely not account for this disparity. One possibility is that rms reduce labor costs through other avenues than wages which are more easily manipulated such as benets. Alternatively, this may be evidence that rms do not solely maximize prots, but instead maximize some combination of prots and other quantities (i.e. public perception). | ||
Counterfactual Distribution | Counterfactual Distribution | ||
− | Table | + | Table 9 details the disproportionate eect which rms' market power has on workers at the low end of the earnings distribution. Assuming a one unit increase in the labor supply elas- ticity for each rm (approximately 1 standard deviation), the 10th percentile of the earnings distribution increases by 0.09 log points under the counterfactual assumption, while the me- dian worker sees an increase of 0.04 log points and the 90th percentile remains unchanged. The nonlinear impacts are also clearly seen in the unconditional quantile regression coe- cients, which are 4-5 times greater than the OLS coecient at lower quantiles and essentially zero at the upper end of the distribution. |
− | Standard measures of inequality are also reported in Table | + | Standard measures of inequality are also reported in Table 9 for both the empirical and counterfactual distributions. A one unit increase in rms' labor supply elasticity is associated with a 9 percent reduction in the variance of the earnings distribution (0.94 to 0.86 log points). Similarly, we see decreases in the 90-10 ratio (1.32 to 1.3), 50-10 ratio (1.18 to 1.16), and 90-50 ratio (1.12 to 1.11). |
− | These results could arise from a number of dierent scenarios, the examination of which is beyond the scope of the current paper. It may reect low-ability workers having few outside options for employment. This could be due to strict mobility constraints, a less eective job referral network (Ioannides and Loury, 2004), lower job search ability (Black, 1981), or simply being qualied for fewer jobs. Another mechanism through which a rm's market power might dierentially aect low wage workers is gender discrimination, as suggested by Hirsch et al. (2010) or racial discrimination. These questions deserve a much deeper treatment, and should be explored in future research. | + | These results could arise from a number of dierent scenarios, the examination of which is 24 |
− | Figure | + | beyond the scope of the current paper. It may reect low-ability workers having few outside options for employment. This could be due to strict mobility constraints, a less eective job referral network (Ioannides and Loury, 2004), lower job search ability (Black, 1981), or simply being qualied for fewer jobs. Another mechanism through which a rm's market power might dierentially aect low wage workers is gender discrimination, as suggested by Hirsch et al. (2010) or racial discrimination. These questions deserve a much deeper treatment, and should be explored in future research. |
− | + | Figure 3 plots both the empirical earnings distribution and the counterfactual distribution under a more drastic assumption which more closely approximates perfect competition, that each rm's labor supply elasticity is increased by a factor of 10 (median elasticity goes from .74 to 7.4). The variance of the counterfactual distribution is considerably lower, with nearly all of the movement occurring in the lower half of the distribution. The striking fact about Figure 3 is that the Burdett and Mortensen model predicts this same behavior as the arrival rate of job oers increases. | |
− | Figure | + | It is important to note that the results in the counterfactual distribution is estimated from a model which includes all person and rm controls, but no person or rm xed eects. This is because identifying o of within person/rm variation in a sense redenes the unconditional quantiles of the distribution, and can introduce substantial bias into the results. Given that the OLS estimates of the impact of rm market power are larger in the specications which include xed eects, the results in Table 9 should be taken as lower bounds. |
Discussion and Extensions | Discussion and Extensions | ||
The labor supply elasticities reported in this paper imply that rms possess a high degree of power in setting the wage. For a variety of reasons, these elasticities are on the lower end of those present in the literature. In this section I address the factors which contribute to these results. | The labor supply elasticities reported in this paper imply that rms possess a high degree of power in setting the wage. For a variety of reasons, these elasticities are on the lower end of those present in the literature. In this section I address the factors which contribute to these results. | ||
− | First, it should be noted that the only other studies to estimate the labor supply elasticity to the rm with comprehensive administrative data used European data. Given the | + | First, it should be noted that the only other studies to estimate the labor supply elasticity 25 |
− | One potential criticism of the labor supply elasticities derived in this paper is that the data do not contain detailed occupation characteristics. This problem is mitigated by the fact that the measures are constructed at the rm level in that I am only comparing workers in the same rm in the construction of a rm's monopsony power. Additionally, previous studies such as Hirsch et al. (2010) and Manning (2003) nd that the addition of individual- level variables had little impact on the estimated labor supply elasticities and that it was the addition of rm characteristics which altered the results. As a further check of this problem, I compute the aggregate monopsony measures in the NLSY, as done in Manning (2003), both with and without detailed occupation characteristics. As shown in Table | + | to the rm with comprehensive administrative data used European data. Given the veryis a determinant of earnings inequality restrictive (from the point of view of the employer) employment laws in place in many European countries, this result is not surprising. Assuming that job security accrues over time within rm but drops following a transition to a new rm, any law which makes it more dicult to re a worker eectively lowers the cost to the employee of switching jobs because job security is less of a factor. |
− | + | One potential criticism of the labor supply elasticities derived in this paper is that the data do not contain detailed occupation characteristics. This problem is mitigated by the fact that the measures are constructed at the rm level in that I am only comparing workers in the same rm in the construction of a rm's monopsony power. Additionally, previous studies such as Hirsch et al. (2010) and Manning (2003) nd that the addition of individual- level variables had little impact on the estimated labor supply elasticities and that it was the addition of rm characteristics which altered the results. As a further check of this problem, I compute the aggregate monopsony measures in the NLSY, as done in Manning (2003), both with and without detailed occupation characteristics. As shown in Table 10, I nd that the dierence between these labor supply elasticities is about 0.2 and is not statistically signicant. Keep in mind that even if this dierence were statistically signicant, the estimates in this paper are still a long way from implying perfect competition. Thus, I conclude that the absence of occupation controls in the LEHD data will not seriously bias the results of this study. | |
− | conclude that the absence of occupation controls in the LEHD data will not seriously bias the results of this study. | + | A potentially more serious problem in the estimation of the labor supply elasticity to the rm is endogenous mobility. Consider the standard search theory model with on the job search: A worker will leave their current job if they receive a higher wage oer from another rm. Their wage at the new rm is then endogenously determined since in eect it was drawn from a distribution truncated at the wage of the their previous job. In this sense, the earnings data for those individuals who were hired away from another job is biased upward, which will bias estimates of the labor supply elasticity to the rm downward. I deal with |
− | A potentially more serious problem in the estimation of the labor supply elasticity to the rm is endogenous mobility. Consider the standard search theory model with on the job search: A worker will leave their current job if they receive a higher wage oer from another rm. Their wage at the new rm is then endogenously determined since in eect it was drawn from a distribution truncated at the wage of the their previous job. In this sense, the earnings data for those individuals who were hired away from another job is biased upward, which will bias estimates of the labor supply elasticity to the rm downward. I deal with the endogenous mobility bias in several dierent ways. First, I estimate the average earnings premium an individual gets from moving to their nth job (where n is the job number in a string of consecutive employment spells). For instance, workers' earnings increase on average .19 log points when they move from their rst to their second jobs. I then reduce the earnings of all job movers by the average premium associated with a move from job n-1 to n. For example, all workers in their second jobs of a string of employment spells would have their earnings reduced by .19 log points. | + | 26 |
− | Second, I recalculate the labor supply elasticities with a Heckman selection correction. In this model I dene the selected group as those who separate from one job to another, and use the number of new jobs in an individual's state and industry as the excluded variable. The logic behind this restriction is that the state-industry specic labor market should be highly correlated with the likelihood that an individual moves to a new job, but should | + | the endogenous mobility bias in several dierent ways. First, I estimate the average earnings premium an individual gets from moving to their nth job (where n is the job number in a string of consecutive employment spells). For instance, workers' earnings increase on average .19 log points when they move from their rst to their second jobs. I then reduce the earnings of all job movers by the average premium associated with a move from job n-1 to n. For example, all workers in their second jobs of a string of employment spells would have their earnings reduced by .19 log points.12 The rationale behind this adjustment is that I only observe workers moving from one job to another if they receive a higher wage oer (This is a typical assumption of on-the-job search models, and is overwhelmingly true in the data). Thus, the earnings I observe in the second job are endogenously determined, since they were in a sense drawn from a strictly positive oer distribution. |
− | + | Second, I recalculate the labor supply elasticities with a Heckman selection correction. In this model I dene the selected group as those who separate from one job to another, and use the number of new jobs in an individual's state and industry as the excluded variable. The logic behind this restriction is that the state-industry specic labor market should be highly correlated with the likelihood that an individual moves to a new job, but should be uncorrelated with that individual's unobserved ability to move. The inverse Mills ratio from the Heckman selection model is included as a regressor in each of the Equations (15)- (17). As noted in Table 10, each of these corrections leads to a trivial change in the labor supply elasticity distribution. | |
− | + | One nal concern regarding endogenous mobility is that we do not observe the complete history of workers, only that within the time-frame of the LEHD infrastructure. Thus, any employment spells in progress at the beginning of our window which are the result of a hire from another rm may introduce bias into the results. To assess the degree to which this is a problem, I again employ the NLSY79. I use a Monte Carlo approach to compare | |
− | be uncorrelated with that individual's unobserved ability to move. The inverse Mills ratio from the Heckman selection model is included as a regressor in each of the Equations ( | + | 12Dene a string of employment spells as consecutive jobs an individual holds with no time spent outside the labor force. In other words, each job transition in a string of employment spells is dened as being a separation to, or recruitment from, employment. An observation takes a default value of 1, 2 if the employment spell is the second in a string of spells, etc. |
− | One nal concern regarding endogenous mobility is that we do not observe the complete history of workers, only that within the time-frame of the LEHD infrastructure. Thus, any employment spells in progress at the beginning of our window which are the result of a hire from another rm may introduce bias into the results. To assess the degree to which this is a problem, I again employ the NLSY79. I use a Monte Carlo approach to compare the estimated labor supply elasticities using the complete worker histories and using only employment spells which occurred in the nal third of the sample window. This is the ideal comparison, where the rst calculation takes into account the entire work histories of each individual and the second calculation uses only those spells observed after an arbitrary date. The Monte Carlo analysis nds that using the complete worker histories leads to a statistically insignicant decrease of the estimated labor supply elasticity. This implies that the use of some partial histories in this study is not likely a problem, and at worst yields an underestimate of monopsony power. | + | 27 |
− | For the reasons mentioned in this section and probably many others, critics may claim that this paper does not accurately estimate the labor supply elasticity to the rm, and they could be right. As with any identication strategy, this study relies on assumptions, not all of which are testable. But while the average rm's labor supply elasticity may not be exactly . | + | the estimated labor supply elasticities using the complete worker histories and using only employment spells which occurred in the nal third of the sample window. This is the ideal comparison, where the rst calculation takes into account the entire work histories of each individual and the second calculation uses only those spells observed after an arbitrary date. The Monte Carlo analysis nds that using the complete worker histories leads to a statistically insignicant decrease of the estimated labor supply elasticity. This implies that the use of some partial histories in this study is not likely a problem, and at worst yields an underestimate of monopsony power. |
− | + | For the reasons mentioned in this section and probably many others, critics may claim that this paper does not accurately estimate the labor supply elasticity to the rm, and they could be right. As with any identication strategy, this study relies on assumptions, not all of which are testable. But while the average rm's labor supply elasticity may not be exactly 1.08, the variable which I call a supply elasticity is certainly some kind of weighted average highly correlated with mobility and individuals' responsiveness to changes in earnings. The fact that this measure is highly correlated with earnings, especially for those at the bottom of the distribution, tells us that our economy is less competitive than we commonly assume. | |
6 Conclusion | 6 Conclusion | ||
− | This study nds evidence of signicant frictions in the US labor market, although the severity of these frictions varies greatly between labor markets. I estimate the average rm's labor supply elasticity to be quite monopsonistic at | + | This study nds evidence of signicant frictions in the US labor market, although the severity of these frictions varies greatly between labor markets. I estimate the average rm's labor supply elasticity to be quite monopsonistic at 1.08, however there is a nontrivial fraction of rms who do appear to be operating in an approximately competitive labor market. While identifying the precise frictions which contribute to rms' labor market power is beyond the scope of this study, I can conclude that a rm's geographical dominance alone does not account for all or even most of their ability to aect the wage oer distribution. |
− | I extend the | + | I extend the dynamic model-based empirical strategy proposed by Manning (2003) to |
+ | 28 | ||
+ | identify rm level labor supply elasticities. The use of these measures of rm market power in earnings regressions provides the rst direct test of the validity of the new monopsony model. I nd that a one unit increase in a rm's labor supply elasticity is associated with a 5-18 percent increase in earnings on average. Further exploring the earnings distribution, I nd highly nonlinear eects implying that the negative eects of monopsony power are concentrated at the lower end of the distribution. While these eects are certainly not trivial, it is important to note that there is evidence that rms only utilize a fraction of their market power. | ||
The development of the rm-level measures of labor market power described in this paper could have a signicant impact on how we view the interaction of imperfect competition with traditional models of the labor market. Future research will examine topics such as gender/race wage gaps, minimum wage laws, unionization, labor demand over the business cycle, agglomeration, and many others. | The development of the rm-level measures of labor market power described in this paper could have a signicant impact on how we view the interaction of imperfect competition with traditional models of the labor market. Future research will examine topics such as gender/race wage gaps, minimum wage laws, unionization, labor demand over the business cycle, agglomeration, and many others. | ||
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− | Figure 1 | + | 33 |
− | + | Figure 1: Proportion of Employment Covered by the LEHD Infrastructure | |
− | Figure 2 | + | Reproduced with permission from Abowd and Vilhuber (2011) |
− | + | 34 | |
+ | Figure 2: Distribution of Labor Supply Elasticities | ||
+ | 35 | ||
+ | Figure 3: Empirical and Counterfactual Distributions | ||
+ | 36 | ||
Table 1: Summary Statistics | Table 1: Summary Statistics | ||
Variable | Variable | ||
− | Age Female White Hispanic High School Some College College Degree+ Tenure (Quarters) Log(Quarterly Earnings) Firm Concentration Firm Industry-Concentration Recruited from Employment | + | Age Female White Hispanic < High School High School Diploma Some College College Degree+ Tenure (Quarters) Log(Quarterly Earnings) Firm Concentration Firm Industry-Concentration Firm Hires per Quarter Firm Employment Separation Rate Employment Growth Rate Recruited from Employment |
Mean Std Dev | Mean Std Dev | ||
38 15.2 0.5 0.5 | 38 15.2 0.5 0.5 | ||
− | 0. | + | 0.77 0.42 0.14 0.34 0.14 0.34 0.29 0.45 0.32 0.47 0.25 0.43 10.1 10.7 |
− | 8.5 1 0.01 0.02 0.09 0.16 0. | + | 8.5 1 0.01 0.02 0.09 0.16 |
− | + | 493 1592 2962 10772 0.15 0.15 1.01 0.15 | |
− | Impact of a ten percentage point increase in concentration ratio on log(earnings) Demographic and human capital controls Employer controls Tenure Controls State xed-eects R-Squared | + | 0.64 0.48 |
− | 0.0213 | + | 37 |
− | No | + | Impact of a ten percentage point increase in concentration ratio on log(earnings) Demographic and human capital controls Employer controls Tenure Controls State xed-eects R-Squared Observations |
− | + | 0.0213 | |
− | 0.0109 0.0066 | + | No |
+ | 0.0053 0.0109 0.0066 | ||
0.0114 | 0.0114 | ||
Table 2: Impact of Firm Concentration on Earnings | Table 2: Impact of Firm Concentration on Earnings | ||
− | *A pooled national sample of all dominant employment spells is used in this set of regressions. The dependent variable is the natural log of quarterly earnings. Demographic and human capital controls include: age, age-squared, and indicator variables for gender, ethnicity, racial status, and education level. Employer controls include indicator variables for each of the 20 NAICS sectors and number of employees working at the rm. Tenure controls include the length (in quarters) of the employment spell, as well as its squared term. Year eects are included in all models. The results are not reported for the models with rm and person xed eects because the coecient was deemed to be biased due to severe multicollinearity. Standard errors are not reported because all t-statistics are greater than 50. | + | No No No 0.0013 |
− | + | Yes Yes Yes Yes | |
− | + | No Yes Yes Yes No No Yes Yes No No No Yes | |
− | + | 0.2369 0.3300 0.3438 325,630,000 325,630,000 325,630,000 325,630,000 325,630,000 | |
− | + | *A pooled national sample of all dominant employment spells is used in this set of regressions. The dependent variable is the natural log of quarterly earnings. Demographic and human capital controls include: age, age-squared, and indicator variables for gender, ethnicity, racial status, and education level. Employer controls include indicator variables for each of the 20 NAICS sectors and number of employees working at the rm. Tenure controls include the length (in quarters) of the employment spell, as well as its squared term. Year eects are included in all models. The results are not reported for the models with rm and person xed eects because the coecient was deemed to be biased due to severe multicollinearity. Standard errors are not reported because all t-statistics are greater than 50. Observation counts are rounded to the nearest 10,000 for condentiallity reasons. | |
+ | 38 | ||
0.3502 | 0.3502 | ||
Table 3: Concentration Ratio Regressions by Industry | Table 3: Concentration Ratio Regressions by Industry | ||
Line 259: | Line 309: | ||
0.056 -0.01 -0.005 0.016 0.046 0.021 -0.129 -0.013 | 0.056 -0.01 -0.005 0.016 0.046 0.021 -0.129 -0.013 | ||
*A pooled national sample of all dominant employment spells is used in this set of regressions. The dependent variable is the natural log of quarterly earnings. Demographic and human capital controls include: age, age-squared, and indicator variables for gender, ethnicity, racial status, and education level. Employer controls include the number of employees working at the rm. Tenure controls include the length (in quarters) of the employment spell, as well as its squared term. Year eects are included in all models. | *A pooled national sample of all dominant employment spells is used in this set of regressions. The dependent variable is the natural log of quarterly earnings. Demographic and human capital controls include: age, age-squared, and indicator variables for gender, ethnicity, racial status, and education level. Employer controls include the number of employees working at the rm. Tenure controls include the length (in quarters) of the employment spell, as well as its squared term. Year eects are included in all models. | ||
− | + | 39 | |
Table 4: Full-Economy Estimate of the Labor Supply Elasticity to the Firm | Table 4: Full-Economy Estimate of the Labor Supply Elasticity to the Firm | ||
Full sample Full sample with rm FE | Full sample Full sample with rm FE | ||
− | . | + | .76 .82 |
− | Only rms with an individually estimated elasticity . | + | Only rms with an individually estimated elasticity .81 |
− | *These labor supply elasticities were obtained by estimating equations ( | + | *These labor supply elasticities were obtained by estimating equations (15)-(17), on a pooled sample of all (dominant) employment spells. Each model contained age, age-squared, along with indicator variables for female, nonwhite, Hispanic, high school diploma, some college, college degree or greater, year, and each of 20 NAICS sectors. |
− | + | 40 | |
− | Table 5: Distribution of Estimated Firm-Level Labor Supply Elasticities | + | Model |
+ | Earnings Only No Education Controls Full Model Full Model (Time-Varying) | ||
+ | εER εNR εES εNS ε | ||
+ | Table 5: Firm-Level Labor Supply Elasticities | ||
+ | 0.41 0.1 0.43 0.3 0.47 0.46 | ||
+ | 0.6 0.59 | ||
+ | -0.41 -0.43 -0.47 -0.6 | ||
+ | -0.5 0.84 -0.52 0.89 -0.54 0.95 -0.67 1.08 | ||
+ | The rst row represents estimates from equations (15)-(17) where the only regressor in each model is log earnings. The second row estimates the same equations, and includes age, age-squared, along with indicator variables for female, nonwhite, Hispanic, and year eects. The third row adds indicator variables for completing a high school diploma, some college, and college degree or greater. The rst four columns report the average rm-level elasticities of recruitment from employment and nonemployment, and the separation elasticities to employment and nonemployment respectively. The nal column combines these elasticities, along with the calculated shares of separations/recruits to/from employment, separation rates, and growth rates to obtain the labor supply elasticity. The rst three rows report only the long-run elasticities, while the fourth row describes the elasticities when a steady-state is not assumed, and they are allowed to vary over time. | ||
+ | 41 | ||
+ | Table 6: Distribution of Estimated Firm-Level Labor Supply Elasticities | ||
Percentiles Mean 10th 25th 50th 75th 90th | Percentiles Mean 10th 25th 50th 75th 90th | ||
− | + | 1.08 0.22 0.44 0.75 1.13 1.73 | |
− | *Three separate regressions, corresponding to equations ( | + | *Three separate regressions, corresponding to equations (15)-(17), were estimated separately for each rm in the data which met the conditions described in the data section. The coecients on log earnings in each regression were combined, weighted by the share of recruits and separations to employment, separation rates, and growth rates according to equation (6) to obtain the estimate of the labor supply elasticity to the rm. Demographic and human capital controls include: age, age-squared, and indicator variables for gender, ethnicity, racial status, and education level. Employer controls include number of employees working at the rm and industry indicator variables. Year eects are included in all models. |
− | + | 42 | |
− | Table | + | Table 7: Mean Labor Supply Elasticity by Sector |
− | + | NAICS Sector | |
Agriculture Mining/Oil/Natural Gas Utilities Construction Manufacturing Wholesale Trade Resale Trade Transportation Information Finance and Insurance Real Estate and Rental Profession/Scientic/Technical Services Management of Companies Administrative Support Educational Services Health Care and Social Assistance Arts and Entertainment Accommodation and Food Services Other Services Public Administration | Agriculture Mining/Oil/Natural Gas Utilities Construction Manufacturing Wholesale Trade Resale Trade Transportation Information Finance and Insurance Real Estate and Rental Profession/Scientic/Technical Services Management of Companies Administrative Support Educational Services Health Care and Social Assistance Arts and Entertainment Accommodation and Food Services Other Services Public Administration | ||
Mean Labor | Mean Labor | ||
Supply Elasticity | Supply Elasticity | ||
− | 1. | + | 1.43 1.52 1.18 1.42 1.82 1.48 1.03 1.47 1.17 1.27 1.01 1.17 |
− | 0.72 0. | + | 1.17 0.72 0.91 0.78 0.94 0.85 1.04 1.19 |
− | *The numbers in this table represent averages by NAICS sector of the estimated labor supply elasticity to the rm. Three separate regressions, corresponding to equations ( | + | *The numbers in this table represent averages by NAICS sector of the estimated labor supply elasticity to the rm. Three separate regressions, corresponding to equations (15)-(17), were estimated separately for each rm in the data which met the conditions described in the data section. The coecients on log earnings in each regression were combined, weighted by the share of recruits and separations to employment, separation rates, and growth rates according to equation (6) to obtain the estimate of the labor supply elasticity to the rm. Demographic and human capital controls include: age, age-squared, and indicator variables for gender, ethnicity, racial status, and education level. Employer controls include number of employees working at the rm. Year eects are included in all models. |
− | + | 43 | |
− | Coecient on labor supply elasticity Demographic | + | Coecient on labor supply elasticity Demographic controls Employer controls Tenure controls State xed-eects Person xed-eects Firm xed-eects R-Squared |
− | 0. | + | 0.05 0.09 0.18 |
− | No No Yes Yes Yes | + | Yes Yes Yes |
− | + | Table 8: Impact of Firm Market Power on Earnings | |
− | 0. | + | 0.13 0.11 0.05 0.03 0.03 |
− | 0. | + | No Yes Yes Yes Yes |
− | *A pooled national sample of all dominant employment spells subject to the sample restriction described in the data section is used in this set of regressions. The dependent variable is the natural log of quarterly earnings. Demographic | + | No No Yes Yes Yes NoNoNoYesYes NoNoNoNoYes NoNoNoNoNoYesNoYes |
− | + | NoNoNoNoNoNoYesYes | |
− | Table | + | 0.005 0.238 0.312 0.331 0.338 0.784 0.90 0.99 |
+ | *A pooled national sample of all dominant employment spells subject to the sample restriction described in the data section is used in this set of regressions. The dependent variable is the natural log of quarterly earnings. Demographic controls include: age, age-squared, and indicator variables for gender, ethnicity, racial status, and education level. Employer controls include the number of employees working at the rm and industry indicator variables. Tenure controls include the length (in quarters) of the employment spell, as well as its squared term. Year eects are included in all models. These results are unweighted, however all models were also estimated with demographic weights constructed by the author. There were no signicant dierences between the weighted and unweighted models. Standard errors are not reported because the t-statistics range from 500-1000, but are available upon request along with all other estimated coecients. There are 267,310,000 observations in each specication. | ||
+ | 44 | ||
+ | Yes Yes Yes Yes Yes Yes Yes Yes Yes | ||
+ | Table 9: Counterfactual Distribution Analysis | ||
Change (log points) in Quantiles of the Earnings Distribution | Change (log points) in Quantiles of the Earnings Distribution | ||
Quantile 10th 25th | Quantile 10th 25th | ||
− | Change in 0. | + | Change in 0.09 0.05 log(earnings) |
Inequality Variance 90-10 measure | Inequality Variance 90-10 measure | ||
− | Earnings . | + | Earnings .94 1.32 distribution |
− | Counterfactual . | + | Counterfactual .86 1.30 distribution |
50th 75th 90th | 50th 75th 90th | ||
− | 0. | + | 0.04 0.01 0.00 |
50-10 90-50 | 50-10 90-50 | ||
1.18 1.12 1.16 1.11 | 1.18 1.12 1.16 1.11 | ||
− | *The counterfactual distribution was constructed by estimating unconditional quantile regressions at every fth quantile of the earnings distribution, and using the supply elasticity coecient from each regression to simulate the eect at each quantile of a | + | *The counterfactual distribution was constructed by estimating unconditional quantile regressions at every fth quantile of the earnings distribution, and using the supply elasticity coecient from each regression to simulate the eect at each quantile of a one-unit increase of the labor supply elasticity. Demographic and human capital controls include: age, age-squared, and indicator variables for gender, ethnicity, racial status, and education level. Employer controls include the number of employees working at the rm and industry indicator variables. Tenure controls include the length (in quarters) of the employment spell, as well as its squared term. Year eects are included in all models. |
− | + | 45 | |
*Panel A: NLSY comparisons | *Panel A: NLSY comparisons | ||
Bootstrapped dierence in labor supply elasticity Std Error | Bootstrapped dierence in labor supply elasticity Std Error | ||
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0.20 0.14 | 0.20 0.14 | ||
Uncorrected labor supply elasticity | Uncorrected labor supply elasticity | ||
− | . | + | .75 |
Full history versus partial history | Full history versus partial history | ||
-.46 .76 | -.46 .76 | ||
Earnings of job changers adjusted downward | Earnings of job changers adjusted downward | ||
− | . | + | .74 |
Control for Heckman selection correction | Control for Heckman selection correction | ||
− | . | + | .76 |
− | Table | + | Table 10: Robustness Checks |
− | *Panel A: Equations ( | + | *Panel A: Equations (15)-(17) were estimated on a sample of employment spells from the NLSY79 from 1979-1996 (the last year for which detailed information on recruitment and separation dates are available). The specications include the same variables available through the LEHD data: age, age-squared, year eects, along with gender, ethnicity, race, industry, and education indicators. The rst column compares the labor supply elasticities with and without the inclusion of occupational xed eects. The second column compares the labor supply elasticities with and without the assumption that only the last third of every individual's work history is known. |
− | **Panel B: The second column represents a recalculation of the labor supply elasticity in which workers who are recruited away from another job have their earnings adjusted downward by the average premium of moving from job n to job n+1. The third column represents a recalculation of the labor supply elasticity in which the inverse | + | **Panel B: The second column represents a recalculation of the labor supply elasticity in which workers who are recruited away from another job have their earnings adjusted downward by the average premium of moving from job n to job n+1. The third column represents a recalculation of the labor supply elasticity in which the inverse Mills ratio of a Heckman selection model for mobility is controlled for in each of Equations (15)-(17). The omitted category in the Heckman model is the number of new local jobs in each workers current industry. |
− | + | 46 | |
}} | }} |